Solid State Chemistry
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Solid State Chemistry
by R.C. Ropp Warren New Jersey USA
2OO3
ELSEVIER AMSTERDAM - BOSTON- HEIDELBERG- LONDON- NEW YORK- OXFORD PA R IS - S A N D I E G O - S A N F R A N C I S C O - S I N G A P O R E - S Y D N E Y - T O K Y O
ELSEVIER SCIENCE B.V. Sara Burgerhartstraat 25 P.O. Box 211, 1000 AE Amsterdam, The Netherlands
9 2003 Elsevier Science B.V. All rights reserved.
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Preface
Most of the
books
concerning
"Solid
State
Chemistry"
that
I have
e xamin ed have been w r i t t e n for the specialist or for the advanced s t u d e n t . I have c o m p o s e d this book with the novice in mind. That is, those w h o have little b a c k g r o u n d but w i s h to begin to learn about the solid state and w h a t it entails can start at the be gi nn i ng and build u p o n their knowledge
and
experience.
This
includes
biotechnology, p h a r m a c e u t i c a l a n d p r o t e o m i c s
those
working
own
in
the
fields. At this point in
time, they have s e q u e n c e d the h u m a n g e n o m e and are trying to define t h e s t r u c t u r e of proteins. It is m y opinion t h a t the material in this book will be helpful to t h e m as well. With this in mind, I have p r e s e n t e d the information in this book in a f o r m t h at can be easily u n d e r s t o o d . I t h i n k that it is quite i m p o r t a n t t hat any s t u d e n t of the body of knowledge
t h a t we call "science"
needs to be
cognizant of the history a nd effort t hat has been m a d e by those w h o p r e c e d e d us. It was Newton who said: "If I have seen further, it is because I have stood on the s h o u l d e r s of giants". Thus, I have tried to give a s h o r t history of each particular s e g m e n t of solid state theory and technology. I have enjoyed c o m p o s i n g the material in this book and t r u s t t h a t t h e reader can use it as a self-study to build u p o n his (her)
store of usable
knowledge. I t h a n k m y wife, Francisca Margarita, profusely for her s u p p o r t during t h e time t h a t it has t a k e n to finish this c o m p o s i t i o n . R.C. R o p p March 2 0 0 3
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vii
Table off contents Preface Table of Contents CHAPTER 1 - The Phase Chemistry of Solids 1 . 1 . - Phase Changes of Solids, Liquids and Gases 1.2.- Differences Between the Three States of Matter a. The Gaseous State b. The Liquid State c. The Solid State 1.3.- The Close-Packed Solid 1.4. Phase Relations Between Individual Solids References Cited Problems for Chapter 1
PaBe i iii
2 9 12 15 17 23 27 28
CHAPTER 2- Determining the Structure of Solids 2.1.- Scientific Basis for Determining the Structure of Solids 2.2.- Solid State Structure Conventions and Protocols 2.3.- How to Determine the Structure of Compounds 2.4.- Symmetry Distribution of Crystals 2.5.- Phase Relationships Among Two or More Solids SUGGESTED READING Problems for Chapter 2
31 31 45 55 61 64 69 69
CHAPTER 3- Defects in Solids 3.1.- The Defect Solid a. The Point Defect in Homogeneous Solids b. The Point Defect in Heterogeneous Solids c. The Line Defect d. The Volume Defect 3.2.- Mathematics and Equations of the Point Defect a. The Plane Net 3.3.- Non-Stoichiometric Solids 3.4.- Defect Equation Symbolism
71 73 74 72 82 85 88 88 95 98
viii
3.5.- S o m e Applications For Defect C h e m i s t r y a. P h o s p h o r s
99 100
3.6.- Defect Equilibria a n d Their E n e r g y 3.7. Defect Equilibria in Various Types of C o m p o u n d s a. S t o i c h i o m e t r i c Binary C o m p o u n d s of MXs b. Defect C o n c e n t r a t i o n s in MXs C o m p o u n d s
101 103 104 107
3.8.- The Effects of Purity (And I m p u r i t i e s )
110
Suggested Reading
112
P r o b l e m s for C h a p t e r 3
113
A p p e n d i x 1.
C o n c e n t r a t i o n s of Defects in Non-Ionized a n d
Non-Stoichiometric Compounds A. Defects in N o n - S t o i c h i o m e t r i c MXs + d C o m p o u n d s A p p e n d i x I I. Analysis of a Real Crystal Using the Thermodynamic Method A. The AgBr Crystal with a Divalent Impurity, Cd 2+ B. Defect Disorder in AgBr- A T h e r m o d y n a m i c A p p r o a c h AoDendix III. Statistical M e c h a n i c s a n d the Point Defect CHAIrI'ER 4- M e c h a n i s m s a n d Reactions in the Solid S t a t e
115 115 118 118 120 124 129
4. I.- P h a s e C h a n g e s 4.2.- The Role of P h a s e B o u n d a r i e s in Solid State R e a c t i o n s
130 132
4.3.- Reaction Rate P r o c e s s e s in Solids 4.4.- Defining H e t e r o g e n e o u s Nucleation P r o c e s s e s
138 140
4.5.- The T a r n i s h i n g R e a c t i o n
146
4.6.- Fick's Laws of Diffusion 4.7.- Diffusion M e c h a n i s m s 4.8. - Analysis of Diffusion R e a c t i o n s
148 151 156
4.9. - Diffusion in Silicates 4. I0.- Diffusion M e c h a n i s m s W h e n the Cation C h a n g e s V a l e n c e
161 171
P r o b l e m s for C h a p t e r 4 A p p e n d i x I- Math Associated with Nucleation Models of 4 . 4 . 1 . A p p e n d i x II- Math Associated w i t h Incipient Nuclei G r o w t h A p p e n d i x III- H o m o g e n o u s Nucleation P r o c e s s e s A p p e n d i x IV- Diffusion E q u a t i o n s Relating to F u n d a m e n t a l Vibrations of the Lattice
175 177 182 184 188
CHAPTER 5- Particles and Particle Technology 5.1.- Sequences in Particle Growth 5.2.- Sintering, Sintering Processes and Grain Growth 5.3.- Particle Size 5.4.5.5.5.6.5.7.-
Particle Distributions Particle Distributions and the Binomial T h e o r e m Measuring Particle Distributions Analysis of Particle Distribution P a r a m e t e r s A. The Histogram B. Frequency Plots C. Cumulative F r e q u e n c y D. Log Normal Probability M e t h o d 5.8.- Types of Log Normal Particle Distributions A. Unlimited Particle Distributions B. Limited Particle Distributions C. Particle Distributions with Discontinuous Limits D. Multiple Particle Distributions Case I: Fluorescent Lamp Phosphor Particles Case II: T u n g s t e n Metal Povcder 5.9.- A Typical PSD Calculation 5.10.- Methods of Measuring Particle Distributions A. The Microscope- Visual Counting of Particles
B. Sedimentation Methods C. Electrical Resistivity-The Coulter Counter D. Other Methods of Measuring Particle Size Permeability Gas adsorption Particle size by laser r e f r a c t o m e t r y Suggested Reading Problems for Chapter 5 Chapter 6. - Growth of Crystals 6. I.- Methods of Growth of Crystals 6.2.- Furnace Construction 6.3.- Steps in Growing a Single Crystal
191 192 193 203 207 209 213 217 218 218 219 220 222 223 223 224 225 226 228 229 232 233 237 241 245 245 245 247 248 249 251 252 253 258
260 270 274 275 278 282
Czochralski Growth of Single Crystals 6.5.- The Bridgeman-Stockbarger Method for Crystal Growth 6.6.- Zone Melting as a Means for Forming Single Crystals 6.7.- Zone Refining 6.8.- The Impurity Leveling Factor 6.9.- The Verneufl Method of Crystal Growth 6. I0.- Molten Flux Growth of Crystals 6.11.- Hydrothermal Growth 6.12.- Vapor Methods Used for Single Crystal Growth 6.13.- Edge Defined Crystal Growth 6.14.- Melting and S t o i c h i o m e t r y
285 288 292 294 296
6.15.- Actual Imperfections in Crystals 6.16.- Electronic Properties of Crystals A. Conductivity in Ionic Compounds 6.17.- Silicon Single Crystals and Integrated Circuits A. Silicon
299 302 303 308 308
.4.
-
B. Silicon as a S e m i - C o n d u c t o r C. Semiconductor Devices D. Integrated Circuits E. Manufacture of Integrated Circuits F. Steps in the Manufacture of Integrated Circuits G. Film Deposition H. Impurity Doping
310 311 313 315 318 328 328
I. Lithographic P a t t e r n i n g J. E t c h i n g K. A Final Look at the IC Manufacturing Process L. Crystal Growth and Crystal Defects Affecting IC's 6.18.- Future Methods for Manufacture of Integrated Circuits 6.19.- Pushing the Limits of Semi-Conductor Technology 6.20.- The Solar Cell A. Crystalline, PolycrystaUine and Amorphous Solar Cells B. Thin Film Solar Cells 6.21.- Piezo-electric materials and Their Uses A. Applications Sonar
329 330 330 334 337 338 343 345 350 351 352
xi
Medical U l t r a s o u n d Micro-positioning and M i c r o - m o t o r s
353
Piezoelectric T r a n s f o r m e r s
353 353
Active Noise a n d Vibration D a m p i n g
353
SUGGESTED READING
353
References on Silicon Devices
354
Problems for C h a p t e r 6
354
Chapter 7- M e a s u r e m e n t of Solid State P h e n o m e n a
357
7.1.- Methods of M e a s u r e m e n t of Solid State Reactions A. Differential T h e r m a l Analysis (DTA)
357 358
B. Differential S c a n n i n g Calorimetry 7.2.- Utilization of DTA and DSC
374 376
A. Applications of DTA
376
B. Uses of DSC 7.3.- T h e r m o g r a v i m e t r y
380 381
7.4.- D e t e r m i n a t i o n of Rate Processes in Solid State Reactions
389
A. Types of Solid State R eact i ons B. The Freeman-Carroll Method applied to DTA Data
389 392
C. The Freeman-Carroll Method Applied to TGA Data 7.5.- Dilatometry 7.6.- T h e r m o m e t r y
393 394 401
7.7.- Application of Dilatometry to Plastic Materials
403
7.8.- Optical M e a s u r e m e n t s of Solids A. Defining Light
405 405
B. M e a s u r e m e n t of Color
409
C. The Nature of Light
410
D.- Absorbance, Reflectivity and T r a n s m i t t a n c e
411
E. M e a s u r e m e n t of Color I. The S t a n d a r d Observer II. The Nature of C h r o m a
415 417 417
III. Intensity and S c a t t e r i n g IV. Color Processes and Color Matching S y s t e m s
418 420
F. The S t a n d a r d Observer and The First Color-Comparator 4 2 1 I. T r i s t i m u l u s Coefficients
426
xii
II. Chromaticity Coordinate Diagrams 7.9.- Color Spaces A. The Munsell Color T r e e B. Color Matching and MacAdam Space R e c o m m e n d e d Reading Problems for Chapter 7
42 43 43 43 43 44
Chapter 1
ii
....
The P h a s e C h e m i s t r y of Solids To u n d e r s t a n d the solid state, we m u s t first u n d e r s t a n d how m a t t e r exists. T h a t is, m a t t e r w a s originally defined as "anything t h a t occupies s p a c e a n d h a s weight". This definition w a s m a d e in the e i g h t e e n t h c e n t u r y w h e n little w a s k n o w n a b o u t "matter" . T h u s ,
it w a s defined in t e r m s of its general
s h a p e a n d physical c h a r a c t e r i s t i c s . We will delve into the "ouflding-blocks" of m a t t e r a n d how solids originate. It is a s s u m e d t h a t you have some initial knowledge c o n c e r n i n g p h y s i c s a n d c h e m i s t r y as well as s o m e ability in m a t h e m a t i c s . The m o r e difficult m a t h e m a t i c a l t r e a t m e n t s are reserved to the a p p e n d i c e s of certain c h a p t e r s . Originally, in the 18th century, w h e n the "Scientific Revolution" w a s j u s t getting started, science w a s referred to as "Natural Philosophy". R e s e a r c h e r s were i n t e r e s t e d in n a t u r a l science, including w h a t we call today: Physics, Chemistry, Biology a n d Biochemistry. All of t h e s e scientific disciplines deal with
molecules
having various
physical
aspects
and
properties
(even
proteins). The earliest w o r k dealt with air, w a t e r a n d solids since t h e s e were the easiest to m a n i p u l a t e in t h o s e times. Note t h a t we r e g a r d all of their scientific a p p a r a t u s to be c r u d e by o u r s t a n d a r d s .
Yet, even the m o s t
s o p h i s t i c a t e d i n s t r u m e n t s (by their criteria) h a d to be built b y h a n d . Even so, early w o r k e r s k n e w t h a t m a t t e r existed in three forms, i.e.- solids, liquids a n d gases. W a t e r w a s s t u d i e d extensively b e c a u s e it w a s e a s y to freeze a n d boil. As we will show, m a n y of o u r basic m e a s u r e m e n t s
a n d scientific
s t a n d a r d s r e s u l t e d from s u c h studies. Reversible t r a n s f o r m a t i o n s b e t w e e n the t h r e e forms (phases) of m a t t e r , are called "Changes of State". The science related to t h e s e p h a s e c h a n g e s lies in the r e a l m of "Physical Chemistry" while their a c t u a l "chemistry", or "reactiveproperties", lies either in the r e a l m of "Inorganic" or "Organic" chemistry. Inorganic
materials
include
both
m a t e r i a l s have a c a r b o n b a c k b o n e .
elements
and
compounds.
Organic
Nearly all inorganics are solids at
a m b i e n t t e m p e r a t u r e . At elevated t e m p e r a t u r e s , t h e y t r a n s f o r m or melt to form a liquid a n d t h e n a gas. Most of t h e s e p h a s e c h a n g e s are reversible. A
[]
few are g a s e s at r o o m t e m p e r a t u r e , b u t liquids are rare. In contrast, organic compounds
can
be
either
solid,
liquid,
or gaseous.
Although
organic
c o m p o u n d s do u n d e r g o some C h a n g e s - o f - S t a t e easily a n d reversibly, their t h e r m a l stability is a problem. If one tries to i n d u c e a c h a n g e of s t a t e in an organic c o m p o u n d , one u s u a l l y finds t h a t liquid organic c o m p o u n d s will freeze a n d / o r sublime. Notwithstanding, m o s t organic solids d e c o m p o s e if the g a s e o u s state is sought. This is due to their relatively low t h e r m a l stability, i.e.- "they burn". Organic h y d r o c a r b o n c o m p o u n d s u s u a l l y r e a c t with
oxygen
and
convert to c a r b o n
t e m p e r a t u r e s of 200 ~
to 600 ~
stable at r a n g e s of 1500 ~ interested
in
inorganics
and water
at r a t h e r
low
while m a n y inorganic c o m p o u n d s are
to 2 0 0 0 ~ because
dioxide
of
a n d even higher. We will be m o r e their
greater
thermal
stability.
Additionally, inorganic c o m p o u n d s have physical properties t h a t c a n n o t be d u p l i c a t e d in the organic d o m a i n of chemistry, a n d vice-versa. 1.1.- PHASE CHANGES OF SOLIDS, LIQUIDS AND GASES The b e s t w a y to u n d e r s t a n d p h a s e c h a n g e s is to e x a m i n e those observed with water, i.e.- t h o s e involving the molecule, H20. We are, of course, familiar with the three s t a t e s of water, n a m e l y ice, w a t e r a n d s t e a m , since these forms are e n c o u n t e r e d daily. The a c t u a l difference b e t w e e n t h e m is a m a t t e r of energy. To illustrate this fact, let u s calculate how m a n y calories are required to c h a n g e ice into w a t e r into s t e a m . This p r o b l e m is typical of those c o n c e r n i n g Changes-of-State. In solving s u c h a problem, we will also define certain c o n c e p t s a n d c o n s t a n t s relating to its solution. For example, we k n o w t h a t w a t e r (a liquid) will c h a n g e to ice (a solid) ff its internal temperature
falls below a certain t e m p e r a t u r e .
Likewise, ff its
i n t e r n a l t e m p e r a t u r e rises above a certain point, w a t e r c h a n g e s to s t e a m (a gas). B e c a u s e w a t e r is so a b u n d a n t on the Earth, it w a s u s e d in the p a s t to define C h a n g e s of S t a t e a n d even to define T e m l ~ r a t u r e
Scales. However,
the concept of "heat" is also involved, a n d we need to also define the perception of h e a t as it is u s e d in this context. Note t h a t defining h e a t implies t h a t we have a reproducible w a y to m e a s u r e t e m p e r a t u r e . A great deal of w o r k w a s r e q u i r e d in the p a s t to r e a c h t h a t stage. First, you have to e s t a b l i s h t h a t certain liquids e x p a n d w h e n heated. T h e n you m u s t e s t a b l i s h
how m u c h t h e y expand. You c a n do this b y malting a glass capillary {a glass t u b e with a u n i f o r m small-bore hole in it} a n d t h e n m e a s u r i n g how far the liquid m o v e s from a given t e m p e r a t u r e point to a n o t h e r . The easiest w a y to do this is to establish the freezing point of w a t e r a n d its boiling point on y o u r "thermo" meter. Lastly, you t h e n d e t e r m i n e if y o u r c h o s e n liquid e x p a n d s in a linear m a n n e r b e t w e e n t h e s e two t h e r m a l points (For a history, see p. 401}. There are two h e a t factors involved in a n y p h a s e change. T h e y are: "heat capacity", i.e.- Cp or C v , a n d "heat of transformation", u s u a l l y d e n o t e d as H. The former factor is c o n c e r n e d with i n t e r n a l t e m p e r a t u r e
c h a n g e within
a n y given m a t e r i a l (solid, liquid or gas) w h e r e a s t h e latter is involved in c h a n g e s of s t a t e of t h a t material. The a c t u a l n a m e s we u s e to describe H d e p e n d u p o n the direction in w h i c h the p h a s e c h a n g e occurs, vis: 1.1.1.-
C h a n g e s of S t a t e in W a t e r TEMPERATURE CHANGE OF STA.TE ice to w a t e r
HLHEAT OF: Fusion
~ 0
OF 32
w a t e r to ice
Solidification
0
w a t e r to s t e a m
Vaporization
100
212
32
s t e a m to w a t e r
Condensation
100
212
The terms, heat, h e a t c a p a c i t y a n d h e a t of t r a n s f o r m a t i o n were originally defined in t e r m s of water. The earliest concept w a s t h a t of "heat", b u t it w a s soon f o u n d t h a t every m a t e r i a l h a d its own "heat capacity". T h a t is, the u n i t of "heat" (or i n t e r n a l energy) itself w a s originally defined as the a m o u n t of energy r e q u i r e d to raise the t e m p e r a t u r e of 1.00 g r a m of w a t e r b y 1.00 degree Celsius, the u n i t of h e a t energy being set equal to one {1.0) calorie. Heat c a p a c i t y itself w a s originally defined as the a m o u n t of h e a t r e q u i r e d to raise the t e m p e r a t u r e
of one {1) cubic c e n t i m e t e r (cc.) of w a t e r (whose
density w a s later defined as 0.9999 @ 3.98 ~ by one (1.00) degree. However, after tbJs concept h a d b e e n defined, it w a s f o u n d t h a t the s a m e a m o u n t of h e a t d i d n o t raise the i n t e r n a l t e m p e r a t u r e of other m a t e r i a l s to the
same
degree.
This led to the
concept
of h e a t
capacity.
Heat
of
t r a n s f o r m a t i o n w a s discovered s o m e w h a t later. How t h e s e c o n c e p t s arose c a n be illustrated as follows.
S u p p o s e you decide to solve the p r o b l e m of defining the c o n c e p t s of h e a t c a p a c i t y a n d h e a t of t r a n s f o r m a t i o n . The former is hhe a m o u n t of energy required to c h a n g e the t e m p e r a t u r e of a m a t e r i a l while the latter relates to how m u c h energy is n e e d e d to c h a n g e from one p h a s e to another. Defining t h e s e c o n c e p t s is a n intellectual r e s e a r c h exercise in itself. In doing this work, it is clear t h a t you m u s t be able to define s o m e sort of m e a s u r e of energy, or heat, itself (even t h o u g h you have not yet defined a u s a b l e scale of heat). Since w a t e r is plentiful (it covers a b o u t 75% of the E a r t h ' s surface), you decide to u s e w a t e r as a s t a n d a r d . You begin by distilling w a t e r to obtain a p u r e p h a s e . You will find t h a t this is difficult since even the a p p a r a t u s you u s e will c o n t a m i n a t e the distilled w a t e r ff you are not careful. After observing its behavior
as
its t e m p e r a t u r e
is changed,
you
decide
to
set u p
a
t e m p e r a t u r e scale in t e r m s of water. In this work, you define the meltW_g point of ice as 0 . 0 0 0 ~
a n d the boiling point of w a t e r as 100.000 ~
(C is
"Celcius", n a m e d after the r e s e a r c h e r who did the original w o r k in 1734). You do this b e c a u s e t h e s e are easily observable points in a n a r b i t r a r y scale of t e m p e r a t u r e as related to h e a t (and more i m p o r t a n t l y are reproducible a n d reversible points). As we said, the m o s t i m p o r t a n t p a r t of this w o r k is to obtain a s a m p l e of p u r e water. M u c h effort w a s e x p e n d e d in the p a s t in a c c o m p l i s h i n g this goal. T a k i n g y o u r p u r e p h a s e of water, you t h e n m e a s u r e its d e n s i t y as a function of t e m p e r a t u r e . Note t h a t you have already defmed a "specific volume" for u s e in y o u r work, ie- cubic c e n t i m e t e r = cc. You d e t e r m i n e t h a t the point of m a x i m u m density of w a t e r o c c u r s at 3 . 9 8 0 ~ d e c r e a s e s b o t h as you a p p r o a c h 0 . 0 0 ~
a n d t h a t the d e n s i t y of w a t e r
a n d its boiling point of 100.00 ~
You t h e n assign the a r b i t r a r y value of 1.000 g r a m / 1 . 0 0 0 ml. of w a t e r (or 0 . 9 9 9 8 g r a m / c c , as later more precise m e a s u r e m e n t s have revealed) as the d e n s i t y of w a t e r at its t e m p e r a t u r e of m a x i m u m density. By t h e n m e a s u r i n g the a m o u n t
of h e a t r e q u i r e d to raise the t e m p e r a t u r e
of 1.000 cubic
c e n t i m e t e r of w a t e r b y 100th of y o u r a r b i t r a r y t e m p e r a t u r e range, i.e. 1.000 ~
by
you have also defined y o u r s t a n d a r d u n i t of h e a t (and called it
1.000 calorie). You have now defined "heat" itself as the a m o u n t of energy r e q u i r e d to raise 1 cc. of w a t e r by one degree as one calorie. However, the t e m p e r a t u r e at
w h i c h you m e a s u r e d y o u r s t a n d a r d calorie w a s not specified. For this reason, you choose the t e m p e r a t u r e r a n g e of 14.5 ~ to 15.5 ~ b e c a u s e you have d e t e r m i n e d t h a t this r a n g e is one w h e r e the d e n s i t y of w a t e r r e m a i n s relatively uniform. T h u s , the s t a n d a r d calorie w a s originally defined as the a m o u n t of h e a t r e q u i r e d to raise the t e m p e r a t u r e of o n e g r a m of w a t e r from 14.5 ~ to 15.5 ~
at a c o n s t a n t p r e s s u r e of one (1) a t m o s p h e r e . Note t h a t in
y o u r r e s e a r c h to define heat, h e a t c a p a c i t y a n d h e a t of t r a n s f o r m a t i o n , you have discovered several a n o m a l i e s of w a t e r t h a t h a d not b e e n k n o w n before y o u r w o r k w a s accomplished. Next, you now m e a s u r e o t h e r m a t e r i a l s to deterrrdne how m u c h energy is required to raise their t e m p e r a t u r e by one degree a n d find t h a t the a m o u n t of energy ,caries from m a t e r i a l to material. In this way, you e s t a b l i s h the notion of h e a t capacity. However, you also note t h a t e a c h m a t e r i a l h a s its own i n t e r n a l energy (heat capacity) at a given t e m p e r a t u r e in relation to t h a t of water. The next step t h a t you t a k e is to s h o w t h a t the t e m p e r a t u r e of ice does n o t c h a n g e as it m e l t s (or t h a t the t e m p e r a t u r e of w a t e r does not c h a n g e as it freezes). This t a k e s several very careful m e a s u r e m e n t s to e s t a b l i s h this fact. It is this concept t h a t e s t a b l i s h e d t h a t there are two k i n d s of "heat" involved in Changes-of-State, n a m e l y t h a t of h e a t of t r a n f o r m a t i o n a n d h e a t capacity. T h u s , the i n t e r n a l t e m p e r a t u r e of a m a t e r i a l c h a n g e s in a linear m a n n e r as energy is a d d e d until the point of t r a n s f o r m a t i o n (phase change) occurs. Then, the i n t e r n a l t e m p e r a t u r e does n o t c h a n g e u n t i l the p h a s e c h a n g e is complete. Reiterating, h e a t of t r a n s f o r m a t i o n , or H, is involved in c h a n g e of form of the m a t e r i a l while h e a t c a p a c i t y relates to its i n t e r n a l c h a n g e in t e m p e r a t u r e as it a p p r o a c h e s a n o t h e r point of change. Both of t h e s e c o n s t a n t s are b a s e d u p o n the s t a n d a r d of energy, or heat, of one (1.00) calorie. Heat c a p a c i t y is also k n o w n as t h e r m a l capacity. We t h u s label h e a t c a p a c i t y as Cp, m e a n i n g the t h e r m a l c a p a c i t y at c o n s t a n t pressure.
Sometimes, it is also called specific heat, m e a n i n g the ratio of
t h e r m a l c a p a c i t y of a n y given m a t e r i a l to t h a t of water, defined as 1.000.
This is the a m o u n t of h e a t in calories t h a t it t a k e s to raise a n y given material 1.00 ~ Originally, C v , the t h e r m a l capacity at c o n s t a n t v o l u m e w a s also used, b u t its u s e is rare n o w a d a y s . The r e a s o n for this is t h a t m o s t m a t e r i a l s e x p a n d over a given t e m p e r a t u r e range, a n d this complicates a n y a c c u r a t e m e a s u r e m e n t (since you have to c o m p e n s a t e for this c h a n g e in volume). We have now d e m o n s t r a t e d t h a t there are two types of "heat" involved in the physical c h a n g e s of a n y given material, one involved in c h a n g e of internal t e m p e r a t u r e of the material a n d the other d u r i n g its t r a n f o r m a t i o n . We specify its internal energy as the "heat" of a material, u s i n g HS,L,G. where S, L, or G refer to either solid, liquid or gas. Note t h a t this internal energy differs from the h e a t of t r a n s f o r m a t i o n , It. (This concept is p e r h a p s one of the m o r e difficult o n e s for one to grasp. However, the internal energy is t h a t energy the s u b s t a n c e h a s b e t w e e n HS,L,G a n d Cp is: I.I.2.-
at a given temperature).
{ H = Cp. T}S,L,G, or
Thus,
the relation
ikI-Is,L,G = Cp(S,L,G) ATs,L,G
where the a c t u a l state of m a t t e r is either S, L, or G. (Note t h a t Cp will differ d e p e n d i n g u p o n the state of m a t t e r involved). In contrast, t h e i n t e r n a l t e m p e r a t u r e the material undergoes
of a material does not change
as
a c h a n g e o f s t a t e . (Thus, its internal energy does
not c h a n g e at t h a t point). Therefore, for a c h a n g e of state between solid a n d liquid, we w o u l d have: 1.1.3-
{ I ~ - HI.} = Cp (T(s) - T(L) ) or tdtI = Cp AT
Note t h a t AIt here is a h e a t of t r a n s f o r m a t i o n involved in a c h a n g e o f s t a t e w h e r e a s zkHs,L,G refers to c h a n g e in ~ t e r ~ d h e a t for a given state of matter. In the case of water, w e have defined its heat capacity, whereas its
heats of transformation were measured. These c o n s t a n t s r e p r e s e n t the relative a m o u n t s of energy n e e d e d to c a u s e c h a n g e s in form of the molecule, H20, from one p h a s e to a n o t h e r state. Their values are given in the following values as s h o w n in 1.1.4. on the next page:
1.1.4.Ice:
0.5 c a l / g m / ~ 80 c a l . / g m . (S ~ L)
Water:
1.00 c a l / g m / ~ 5 4 0 c a l . / g i n . {L ~ G)
Steam:
0.5 c a l . / g i n / ~
We c a n n o w c a l c u l a t e the a m o u n t of energy r e q u i r e d to raise o n e g r a m o f i c e at - 10 ~
to form o n e g r m n o f s t e a m at 110 ~
This is s h o w n in the
following: 1.1.5.- CALORIES REOUIRED TO CHANGE 1 G r a m OF ICE TO STEAM FORM Ice
AT -10 to 0
Ice
0
Water
0 to 100
Water
0
Ca 0.5
C ~ 5.0 cal.
...... 1.0
100 cal.
. . . . . .
to S t e a m
&H_K
ADDED
---
5.0 cal.
80 cal.(fusion)
85.0 cal.
---
100.0 cal.
540 cal.
5 4 0 . 0 cal.
(vaporization) Total =
730.0 cal.
In all cases, AItx is specified in t e r m s of the type of c h a n g e of s t a t e occurring, while Cp AT is the c h m a g e i n i n t e r n a l h e a t w h i c h o c c u r s as the t e m p e r a t u r e rises (or falls). At a given c h a n g e of state, all of t h e energy goes to the c h a n g e of s t a t e a n d t h e t e m p e r a t u r e does not c h a n g e until t h e t r a n s f o r m a t i o n is complete. In t h e n e x t section, we shall see w h e r e the energy goes. The s a m e t r a n s f o r m a t i o n s t a k e place r e g a r d l e s s of the n a t u r e of t h e a t o m s composing
the
compound,
unless,
as
we
said
above,
the
compound
d e c o m p o s e s to s o m e o t h e r form. Let u s now e x a m i n e t h e t h e r m a l c h a n g e s we have d e s c r i b e d above in t e r m s of a g r a p h s h o w i n g t h e c h a n g e in a c t u a l t e m p e r a t u r e . This is i l l u s t r a t e d in the follo,~mg d i a g r a m , given on the n e x t page as 1.1.6. Note t h a t we have plotted the calories a d d e d on a s h o r t e n e d scale so as to
get the total calories a d d e d to the s y s t e m on one page. The s a m e n u m b e r s given in 1.1.5. are u s e d in 1.1.6. b u t it is easier to see t h a t the calories involved in C h a n g e - o f - S t a t e p r e d o m i n a t e over t h o s e w h i c h m e r e l y c h a n g e the i n t e r n a l energy, or t h e t e m p e r a t u r e , of the m a t e r i a l (here, ice or steam). The next c o n c e p t w h i c h we w i s h to e x a m i n e is t h a t of the differences b e t w e e n the three s t a t e s of m a t t e r , gases, liquids a n d solids. In t h i s case, we will fred very significant differences in their e n e r g y content, n a m e l y t h a t t h e g a s e o u s form is t h e m o s t energetic while the solid h a s t h e l e a s t energy.
1,2.- DIFFERENCES B ~ E N
THE THREE STATES OF MATTER
In order to define s u c h differences, we m u s t first s h o w how t h e s e s t a t e s differ physically from one another. We will s t a r t with gases, t h e n liquids a n d finally solids. As we shall see, the m a j o r difference b e t w e e n these s t a t e s is a m a t t e r of energy, the solid having the least energy of all. G a s e o u s molecules are free to roam, w h e r e a s m o l e c u l e s in the liquid s t a t e are b o u n d together a n d molecules in the solid state are b o u n d a n d ordered into a tight-knit structure. a. The G a s e o u s State The g a s e o u s s t a t e h a s b e e n defined as "a state of m a t t e r in w h i c h the s u b s t a n c e e x p a n d s readily to fill a n y c o n t a i n i n g vessel" (1). W h a t this m e a n s is t h a t a n y collection of molecules in the g a s e o u s state is free to move in all directions a n d t h a t the g a s e o u s molecules will fill a n y c o n t a i n e r in w h i c h t h e y are confined. For the H20 molecule in a g a s e o u s state (which h a s 3 a t o m s per molecule), there will be 9 degrees of freedom (since there are 3 d i m e n s i o n s in w h i c h it c a n move). These c a n be divided into 3-translational, 3-vibrational a n d 3-rotational degrees of freedom. These axe s h o w n in the following diagram, given as 1.2.1. on the next page. Note t h a t the drawings are exaggerated from the a c t u a l condition to illustrate the c h a n g e s in vibrational a n d rotational states. T h e s e molecules are free to move in a n y of three directons, a n d c a n rotate a n d vibrate in v a r i o u s m o d e s in a n y of the three directions as shown. Their energy s t a t e s are quantized, b u t well s e p a r a t e d in energy as s h o w n in the following diagram, also given on the next page as 1.2.2. Note t h a t the drawings are exaggerated from the actual condition to illustrate the c h a n g e s in vibrational a n d rotational states. These molecules are free to move in a n y of three directons, a n d c a n rotate a n d vibrate in v a r i o u s m o d e s in a n y of the three directions as shown. In this diagram, we have s h o w n 3 s e p a r a t e vibrational s t a t e s with rotational s t a t e s s u p e r i m p o s e d u p o n them. For o u r g a s e o u s w a t e r molecule w h i c h h a s three a t o m s per molecule, (1 oxygen a n d two h y d r o g e n atoms), the 3 vibrational degrees of freedom will have (2J+ 1 = 7) rotational s t a t e s s u p e r i m p o s e d u p o n
10
t h e m (J is the n u m b e r of a t o m s in the molecule, having q u a n t i z e d vibrational states).
If the
molecule
happened
to be
NH3,
then
the
expected
number
of
vibrational s t a t e s would be nine. If we m e a s u r e the a b s o r p t i o n s p e c t r a of a n y molecule, M X 2 , in the infra-red region of the s p e c t r u m , we will obtain
11
r e s u l t s similar to t h o s e s h o w n in the d i a g r a m given above, the exact region of the s p e c t r u m d e p e n d i n g u p o n the type of molecule p r e s e n t (i.e.- m o l e c u l a r vceight). It t h u s s h o u l d be clear t h a t e a c h g a s e o u s molecule is free to move in a n y of the three d i m e n s i o n s until it collides with either the walls of the container, or with s o m e o t h e r molecule. The average d i s t a n c e t h a t e a c h molecule m o v e s before collision is called the "mean free path". The m e a n free p a t h will be a function of b o t h the t e m p e r a t u r e a n d the p r e s s u r e of the gas. This concept arose from the Kinetic T h e o r y of G a s e s w h i c h in t u r n arose from Avagadro's Hypothesis. In 1811, Avogadro p o s t u l a t e d t h a t equal v o l u m e s of g a s e s c o n t a i n equal n u m b e r s of molecules (at a given t e m p e r a t u r e
a n d pressure). Following this, J o u l e
explained in 1843 t h a t the p r e s s u r e of a gas is c a u s e d b y the i n t e n s e m o t i o n of the molecules w h i c h b o m b a r d the walls of the container. The exact p r e s s u r e w a s p r o p o s e d to be proportional to the speed a n d m o m e n t u m of these molecules. Both Avogadro's a n d J o u l e ' s theories were d i s p u t e d over a n u m b e r of y e a r s on several g r o u n d s until 1906 w h e n J e a n Perrin directly observed, a n d Einstein explained, the Brownian m o v e m e n t in gases. These arguments,
coupled with direct scientific observation, finally served to
e s t a b l i s h t h e s e theories as Laws. However, it w a s Maxwell in
1848 who s h o w e d t h a t molecules have a
distribution of velocities a n d t h a t they do not travel in a direct line. One experimental m e t h o d u s e d to s h o w this w a s t h a t a m m o n i a molecules are not detected in the time expected, as derived from their calculated velocity, b u t arrive m u c h later. This arises t "ore the fact t h a t the a m m o n i a molecules
interdiffuse a m o n g the air moi~.cules b y i n t e r m o l e c u l a r collisions. The m o l e c u l a r velocity calculated for N:i3 molecules from the w o r k done b y J o u l e in 1843 w a s 5.0 x102 m e t e r s / s e c , at r o o m t e m p e r a t u r e . This implied t h a t the odor of a m m o n i a o u g h t to be detected in 4 millisec at a d i s t a n c e of 2.0 m e t e r s from the source. Since Maxwell observed t h a t it took several m i n u t e s , it w a s fully obvious t h a t the m o l e c u l e s did not travel in a direct p a t h . Analysis b y C l a u s i u s in 1849 s h o w e d t h a t the mmmonia molecules travel only s o m e 0.001
cm. b e t w e e n collisions with air molecules at a t m o s p h e r i c
p r e s s u r e , in time intervals of a b o u t 10 -10 sec. between collisions. This m e a n t
12
t h a t t h e y d e s c r i b e a long a n d intricate p a t h in the p r o c e s s of a c q u i r i n g a d i s p l a c e m e n t of several m e t e r s . The m a t h e m a t i c s involved are intricate a n d we will not p r e s e n t t h e m here. However, t h e y a r e available for t h o s e who w i s h to s t u d y t h e m (2). Nevertheless, t h e fact t h a t t h e r e is a n average d i s t a n c e t h a t m o l e c u l e s travel b e t w e e n collisions h a s given u s the c o n c e p t of the Mean Free P a t h (which is the average d i s t a n c e b e t w e e n collisions). A b y - p r o d u c t of the w o r k b y Perrin a n d Einstein w a s the first reliable e v a l u a t i o n of Avogadro's n u m b e r , the n u m b e r of m o l e c u l e s in a mole. The b e s t c u r r e n t value is believed to be: 6.02204531 x 1023 m o l e c u l e s per k i l o g r a m mole. It is well to note, at this point, t h a t all of t h e s e o b s e r v a t i o n s are the r e s u l t of m a n y h o u r s of w o r k by prior investigators from the p a s t . T h u s , we have their experience a n d i n t u i t i o n to d r a w u p o n for a n y w o r k t h a t we m a y c a r r y forward to t h e benefit of m a n k i n d . b. The Liquid S t a t e In the liquid state, the m o l e c u l e s are still free to move in t h r e e d i m e n s i o n s b u t still have to be confined in a c o n t a i n e r in the s a m e m a n n e r as the g a s e o u s s t a t e if we expect to be able to m e a s u r e t h e m . However, there are i m p o r t a n t differences. Since the m o l e c u l e s in the liquid s t a t e have h a d energy
removed
from
them
in
order
to
get
them
to
condense,
the
t r a n s l a t i o n a l degrees of freedom are found to be restricted. This is d u e to the fact t h a t t h e m o l e c u l e s are m u c h closer together a n d c a n i n t e r a c t with one a n o t h e r . It is this i n t e r a c t i o n t h a t gives the liquid s t a t e its u n i q u e properties. T h u s , the m o l e c u l e s of a liquid are not free to flow in a n y of the three directions, b u t are b o u n d by i n t e r m o l e c u l a r forces. T h e s e forces d e p e n d u p o n the electronic s t r u c t u r e of the molecule. In the c a s e of water, w h i c h h a s two electrons on the oxygen a t o m w h i c h do n o t p a r t i c i p a t e in the b o n d i n g s t r u c t u r e , the m o l e c u l e h a s a n electronic m o m e n t , i.e.- is a "dipole". This r e s u l t s in a p r o p e r t y w h i c h we call fluid viscosity since the m o m e n t of e a c h m o l e c u l e i n t e r a c t s with all of its n e a r e s t neighbors. Yet, the s a m e vibrational a n d r o t a t i o n a l s t a t e s are still p r e s e n t b u t in a different form. T h a t is, t h e y are m u t a t e d forms of the s a m e energy levels t h a t we found in the g a s e o u s state. This is i l l u s t r a t e d in t h e following diagram:
13
Note t h a t in the above d i a g r a m there axe still vibrational s t a t e s b u t t h a t the rotational s t a t e s are "smeared" one into the other. There is little t r a n s l a t i o n a l m o t i o n for the w a t e r molecules within the interior of the liquid u n l e s s t h e y escape from the liquid p h a s e . If t h e y do so, we call this "evaporation" (This m a y be c o n t r a s t e d to the escape of molecules from a solid w h i c h we call "sublimation"). :Most liquids do have a def'med v a p o r p r e s s u r e w h i c h m e a n s t h a t molecules c a n a n d do escape from the surface of the liquid to form a gas. This is a n o t h e r r e a s o n t h a t the properties of a liquid vm3r from those of the g a s e o u s state. Hence, we still have the vibrational a n d rotational degrees of freedom left in the liquid, b u t not t h o s e of the t r a n s l a t i o n a l mode. A r e p r e s e n t a t i o n of 'water molecules in the liquid state is p r e s e n t e d in the
following diagram,
s h o w n as 1.2.4. on the next page. (Ignore the o p e n s p a c e s since this is merely a simulation). As s h o w n in this diagram, the w a t e r molecules flu the c o n t a i n e r a n d also have a free surface from w h i c h they c a n escape. T h u s , we conclude t h a t the molecules of a liquid are free to slide p a s t one a n o t h e r b u t the overall a s s e m b l a g e of molecules does n o t have a definitive form, except t h a t of the c o n t a i n e r u s e d to hold it. For this reason, a liquid h a s b e e n defined as "a s u b s t a n c e or state of m a t t e r w h i c h h a s the capacity to flow u n d e r extremely small s h e a r s t e s s e s to conform to the s h a p e of a n y
14
confining vessel, b u t is relatively incompressible and lacks the capacity to expand without limit" (I). 1.2.4.-
Therefore, as we change the state of matter, the translational degrees of freedom in liquids become severely restricted in relation to those of the gaseous state. And, the vibrational a n d rotational degrees of freedom appear to be s o m e w h a t restricted, even t h o u g h m a n y of the liquid vibrational and rotational states have been found to be quite similar to those of the gaseous state.
15
c. The Solid S t a t e If we n o w r e m o v e m o r e
ener~r
from t h e
liquid,
it finally r e a c h e s
a
t e m p e r a t u r e w h e r e it "freezes", t h a t is - it converts to a solid. W h a t h a p p e n s , in a m o l e c u l a r sense, is t h a t the m o l e c u l e s b e c o m e o r d e r e d . A n o t h e r w a y to s a y this is t h a t t h e y form a lattice-like framework. A r e p r e s e n t a t i o n of the solid s t a t e is s h o w n in ~ e foUowing diagram:
In this case, the m o l e c u l e s are f o u n d to have eu-rmnged t h e m s e l v e s in orderly rows. A l t h o u g h we c a n see only t h e top layer, t h e r e are several layers below with the exact s a m e a r r a n g e m e n t (This is not the exact a r r a n g e m e n t f o u n d in "ice" b u t is a stylized r e p r e s e n t a t i o n of the solid s t a t e of water). It s h o u l d
thus
be
clear t h a t
as we c h a n g e
the
state
of m a t t e r ,
the
t r a n s l a t i o n a l degrees of f r e e d o m p r e s e n t in g a s e s b e c o m e r e s t r i c t e d in liquids ~md d i s a p p e a r
in solids.
For g a s e o u s
molecules,
both
~ibrational
and
r o t a t i o n a l degrees of freedorn are p r e s e n t while t h o s e of the liquid s t a t e are modified to the point w h e r e only ~ibrational s t a t e s c a n be said to truly-free s t a t e s . The s a m e c a n n o t be said for m o l e c u l e s in the solid state. In t h e solid,
16
only the vibrational s t a t e s remain, b u t t h e y do not resemble t h o s e of the g a s e o u s a n d liquid states. This is illustrated as follows:
Note t h a t t h e s e vibrational s t a t e s in the solid are not recognizable in t e r m s of those of the g a s e o u s or liquid states. And, the rotational s t a t e s a p p e a r to be completely absent. It h a s b e e n d e t e r m i n e d t h a t solids have quite different vibrational s t a t e s w h i c h are called "phonon modes". These vibrational s t a t e s are
quantized
vibrational m o d e s within the solid s t r u c t u r e w h e r e i n the
a t o m s all vibrate
together
in a specific pattern. T h a t is, the vibrations have
clearly defined energy m o d e s in the solid. The n u m b e r of p h o n o n m o d e s are limited a n d have b e e n described as " p h o n o n b r a n c h e s " w h e r e two types are present, "optical " a n d "acoustical". (These n a m e s arose due to the original m e t h o d s u s e d to s t u d y t h e m in solids). For the solid state, there will be a specific n u m b e r of p h o n o n b r a n c h e s f o u n d in the vibrational s p e c t r u m of a n y given solid, which d e p e n d s u p o n the n u m b e r of a t o m s c o m p o s i n g the solid. The n u m b e r of b r a n c h e s f o u n d in the p h o n o n m o d e s can be f o u n d from the following equations, given in 1.2.7. on the next page. C o n t r a s t this s i t u a t i o n with those of b o t h the liquid state a n d the g a s e o u s state. (What do we m e a n b y "quantized p h o n o n m o d e s in the solid?- the vibrations have specific a m o u n t s of energy a n d these m o d e s a p p e a r only as r e s o n a n t vibrations- i.e.- the molecules or a t o m s vibrate together only- at certain frequencies,
d e p e n d i n g u p o n the m a s s
or the
17
molecules (atoms or ions) a n d the chemical b o n d s holding the s t r u c t u r e together). 1.2.7.- N u m b e r of B r a n c h e s of P h o n o n Dispersi0.n: Equations:
Optical = 3 y -3
Acoustical = y a t o m s / m o l e c u l e
P h o n o n States:
For w a t e r with 3 a t o m s per mole c.ule: Acoustical
=3
Optical
= 6 (i.e.- [3x31 -3)
The m a j o r difference, then, between the 3 p h a s e s we have d i s c u s s e d is t h a t the solid c o n s i s t s of a n a s s e m b l a g e of
close-packed
molecules
w h i c h we have s h o w n to have a r i s e n - w h e n we r e m o v e d e n o u g h energy from the molecules so as to c a u s e t h e m to c o n d e n s e a n d to form the solid state. Let u s n o w examine the properties of a t o m s or molecules w h e n t h e y are crowded together to form a "close-packed" solid. 1.3.- THE CLOSE PACKED SOLID 'We have already said t h a t the solid differs from the o t h e r s t a t e s of m a t t e r in t h a t a long range ordering of a t o m s or molecules h a s appeared. To achieve long r a n g e order in a n y solid, one m u s t s t a c k a t o m s or molecules in a s y m m e t r i c a l w a y t o c o m p l e t e l y fill all of the space available. This is not a trivial m a t t e r since solids require t h a t all of the a t o m s be a r r a n g e d in a synm]etical p a t t e r n hi t h r e e d i m e n s i o n s . T h u s , if we could actually see these a t o m s in a solid, we w o u l d find t h a t t h e y are c o m p o s e d of specific "building blocks", w h i c h we shall call "propagation models" or "Units". (Actually, it is now possible to directly observe the p a c k i n g of a t o m s in solids, b u t t h a t is a n o t h e r story, t h a t of the atomic-force microscope). S u c h m o d e l s m u s t be entirely synm]etrical in t h r e e - d i m e n s i o n a l space so t h a t we c a n a r r a n g e t h e m properly to form a 3 - d i m e n s i o n a l solid. B e c a u s e of this limitation, we find t h a t only certain types of p r o p a g a t i o n m o d e l s will work. And, in doing so, we c a n gain f u r t h e r insight into the properties of a solid. To u n d e r s t a n d tt'ds, consider the following discussion.
18
Of t h e t h r e e - d i m e n s i o n a l m o d e l s available to u s , only c e r t a i n s h a p e s c a n b e u s e d to f o r m a s y m m e t r i c a l solid. T h e s e are e v e n - n u m b e r e d s e t s of a t o m s , a r r a n g e d in e i t h e r of t h e following forms1.3. I.- Atomic F o r m s S u i t a b l e for A s s e m b l i n g Long D i s t a n c e A r r a n g e m e n t s T e t r a g o n a l = 4 a t o m s per Unit H e x a g o n a l = 6 a t o m s p e r Unit Cubic
= 8 a t o m s p e r Unit
T h e s e specific s h a p e s are s h o w n in t h e following d i a g r a m :
Note t h a t t h e r e are 4, 6 or 8 a t o m s p e r Unit, b u t o d d - n u m b e r e d u n i t s of 5, 7, or 9 a t o m s p e r Unit are n o t u s e d . If s u c h U n i t s are tried, o n e finds t h a t t h e y c a n n o t be fit t o g e t h e r in a t h r e e - d i m e n s i o n a l p a t t e r n w h i c h h a s long r a n g e o r d e r a n d s y m m e t r y (If y o u do n o t believe this, t r y it yourself. You will Fund t h a t a five-atom Unit, w h i c h is t h e h e x a g o n a l Unit given above m i n u s one atom,
cannot
be
stacked
together
without
losing
part
of t h e
three-
d i m e n s i o n a l space. In o t h e r w o r d s , t h e r e will b e "holes" in t h e s t r u c t u r e ) . You m i g h t w o n d e r w h y we did n o t specify e i t h e r 1, 2 or 3 a t o m s p e r Unit. T h e r e a s o n lies in t h e fact t h a t 1 a t o m , or 2 a t o m s are n o t t h r e e - d i m e n s i o n a l
19
b u t are t w o - d i m e n s i o n a l (a fact t h a t you c a n a s c e r t a i n b y glueing s o m e pingpong balls together to m a k e individual m o d e l s - t h e s e c o m p o n e n t s c a n be u s e d to form t h e three Units given in
1.3.2.). Note t h a t we have now
e s t a b l i s h e d t h a t only specific s h a p e s c a n be u s e d to a s s e m b l e a solid. The next q u e s t i o n t h a t n e e d s to be a n s w e r e d is how the solid w o u l d a p p e a r if we could see the a t o m s directly. There
are,
in
heterogeneous.
general,
two
kinds
of
solids,
homogeneous
and
The former is c o m p o s e d from a t o m s t h a t are all the s a m e
a n d the latter from a t o m s not the s a m e . If the a t o m s are all of one kind, i.e.one of t h e e l e m e n t s , t h e p r o b l e m is s t r a i g h t forward. S e t s of eight a t o m s , e a c h set a r r a n g e d as a cube, will g e n e r a t e a cubic s t r u c t u r e . Two sets of three a t o m s , e a c h set of t h r e e a r r a n g e d in a triangle, will p r o p a g a t e a hexagonal pattern with three dimensional symmetry. E l e m e n t a l solids h a v i n g a t e t r a g o n a l s t r u c t u r e are very few a n d it is e a s y to a s c e r t a i n t h a t m o s t of the e l e m e n t s form s t r u c t u r e s t h a t are either cubic or hexagonal, b u t rarely tetragonal. The r e a s o n for this is t h a t t e t r a g o n a l u n i t s are m o r e conducive for the c a s e w h e r e not all of t h e a t o m s are the s a m e , i.e.the h e t e r o g e n e o u s case. One e x a m p l e of this is t h e c a s e w h e r e we have 1 p h o s p h o r o u s atom, c o m b i n e d w i t h 4 oxygen a t o m s to form the p h o s p h a t e Unit, i.e.- P04. A n o t h e r case m i g h t be w h e r e we c o m b i n e 1 c a r b o n a t o m w i t h 3 oxygen a t o m s to form a c a r b o n a t e Unit. In t h e first case, we have a t e t r a g o n a l Unit, w i t h the p h o s p h o r o u s a t o m at t h e c e n t e r of the 4 a t o m s c o m p o s i n g a tet_rahedron. In the s e c o n d case, the c a r b o n a t o m aligned w i t h 3 oxygen a t o m s w h i c h lie in t h e form of a t e t r a h e d r o n . In the first case, the t e t r a h e d r o n arises b e c a u s e of s p a t i a l preferences, w h e r e a s in the s e c o n d case, we k n o w t h a t t h e c a r b o n a t o m prefers to form t e t r a h e d r a l b o n d s . T h u s , it s h o u l d be clear t h a t the specific s t r u c t u r e f o u n d in a solid arises either b e c a u s e of s p a t i a l c o n s i d e r a t i o n s , or b e c a u s e of b o n d i n g p r e f e r e n c e s of certain atoms comprising the structure. In forming a solid from a t o m s or molecules, p a r t of t h e p r o b l e m lies in t h e fact t h a t we m u s t h a n d l e a very large n u m b e r of a t o m s or molecules. For example, 6.023 x 1023 (60.23 septiUion) a t o m s c o m p r i s e one mole a n d we m u s t s t a c k e a c h of t h e s e in a s y m m e t r i c a l m a n n e r to form the c l o s e - p a c k e d
20
solid. (As a m a t t e r of c o m p a r i s o n ,
calcium carbonate, whose molecular
weight is a b o u t 100 g r a m s / m o l e , c a n be held in b o t h of y o u r c u p p e d h a n d s . This a m o u n t c o n t a i n s the 6.0 septillion (1028) molecules). There is also a n o t h e r i m p o r t a n t factor. T h a t is, in building a solid s t r u c t u r e one finds t h a t s o l i d s t r u c t u r e s are b a s e d o n t h e l a r g e s t a t o m p r e s e n t , as well as how it s t a c k s together (its valence) in space filling-form. For m o s t inorganic c o m p o u n d s ,
this is the o x y g e n
atom,
e.g.- oxides,
silicates,
p h o s p h a t e s , sulfates, borates, t u n g s t a t e s , v a n a d a t e s , etc. The few exceptions involve chalcogenides, halides, hydrides, etc., b u t even in t h o s e c o m p o u n d s , the s t r u c t u r e is b a s e d u p o n aggregation of the largest atom, e.g..- the sulfur a t o m in ZnS. Zinc sulfide exhibits two s t r u c t u r e s ,
sphalerite-
a cubic
a r r a n g e m e n t of the sulfide atoms, a n d wurtzite- a h e x a g o n a l a r r a n g e m e n t of the
sulfide
atoms.
Divalent
zinc
atoms
have
essentially
the
same
coordination in b o t h s t r u c t u r e s . The following d i a g r a m s h o w s how s u c h a solid w o u l d look on a n atomistic scale:
W h a t we have s h o w n is the surface of several rows of a t o m s c o m p o s i n g the
21
solid s t r u c t u r e . We see the o u t e r m o s t layer of the s t r u c t u r e w h i c h is likely to be the oxygen a t o m s c o m p o s i n g the c o m p o u n d . Let u s n o w consider p r o p a g a t i o n u n i t s in their space-filling aspects. As we defined t h e m above, they are solid state building blocks t h a t we c a n s t a c k in a symmeh--ical form to infinity. Thus, 4 - a t o m s will form a 3 - d i m e n s i o n a l t e t r a h e d r o n (half a c u b e is oniv l - 2-dkmensional) w h i c h is a valid p r o p a g a t i o n unit. This m e a n s t h a t we c a n take tetrahech-ons a n d fit t h e m together 3dimensionally to form a s y m m e t r i c a l s t r u c t u r e w h i c h extends to infini~-. However, the s a m e is not true for 5-atoms, which foiTns a four-sided pyramid. This s h a p e c a n n o t be completely fitted together in a s y m m e t r i c a l a n d space-filling mmnner, b e c a u s e w h e n we s t a c k these p}Tamids containing 5 atoms, we find t h a t their t r a n s l a t i o n a l properties preclude formation of a s}Tnmetrical s t r u c t u r e b e c a u s e there is lost space between the p y r a m i d s which r e s u l t s in holes in hhe long-range s t r u c t u r e . However, if one m o r e a t o m is a d d e d to the pyramid, we t h e n have a n o c t a h e d r o l i w h i c h is space-filling with t r a n s l a t i o n a l properties. This r e s u l t s in a hexagonal s t r u c t u r e . Going further, c o m b i n a t i o n s of seven a t o m s are asymmetrical, b u t eight a t o m s form a cube w h i c h c a n be p r o p a g a t e d to infu-'dty to form a cubic s t r u c t u r e . Note t h a t b y t u r n i n g the top layer of four a t o m s b y 45 ~ (see 1.3.1.), we have a hexagonal u n i t w h i c h is related to the hexagonal u n i t c o m p o s e d of 6 atoms, two triangles atop of each other. By t~g ping-pong balls and" gluing t h e m together to form the p r o p a g a t i o n u n i t s s h o w n above, one c a n get a b e t t e r perspective between cubic a n d hexagonal close-packing. Although we c a n c o n t i n u e with more a t o m s per p r o p a g a t i o n unit, it is easy to s h o w t h a t all of those are related to the four basic p r o p a g a t i o n u n i t s found in the solid state, to wit: 1.3.4.-
Propagation Units Usually F o u n d ~ So!i'ds Tet_rahedron
(4)
Octahedron
(6)
Hexagon
(6 or 8)
Cube
(8)
22
We t h u s conclude t h a t s t r u c t u r e s of solids are based, in general, u p o n t h e s e four (4) b a s i c p r o p a g a t i o n units, w h i c h c a n be s t a c k e d in a syrranetrical a n d space-filling form to n e a r infinity. The synm~etry will be t h a t of the largest a t o m in the s t r u c t u r e , u s u a l l y oxygen in inorganic solids. Variation of s t r u c t u r e d e p e n d s u p o n w h e t h e r the o t h e r a t o m s forming the s t r u c t u r e are larger or smaller t h a n the basic p r o p a g a t i o n u n i t s c o m p o s i n g the s t r u c t u r e . In m a n y c a s e s t h e y are smaller a n d will fit into the i n t e r s t i c e of the p r o p a g a t i o n unit, illustrated b y the PO4 - t e t r a h e d r o n m e n t i o n e d above. In this case, the 1~+ a t o m is small e n o u g h to fit into the center (interstice) of the t e t r a h e d r o n formed b y the four oxygen atoms. If we c o m b i n e it with Er 3+ (which is slightly smaller t h a n PO4), we obtain a tetragonal s t r u c t u r e , a sort of elongated c u b e of high s y m m e t r y . But if we combine it with La 3+ , w h i c h is larger t h a n PO4 3- , a monoclinic s t r u c t u r e with low s y m m e t r y results. There still is one a s p e c t of p h a s e c h e m i s t r y t h a t we have not yet a d d r e s s e d . T h a t is the case w h e r e m o r e t h a n
one solid p h a s e
exists. The basic
properties of a solid include two factors, n a m e l y composition a n d s t r u c t u r e . We will a d d r e s s s t r u c t u r e s of solids in the next chapter. The composition of solids is one w h e r e the individual c o n s t i t u e n t s will vary ff the solid is h e t e r o g e n o u s . T h a t is, the two types of inorganic solids v a r y according to w h e t h e r t h e y are h o m o g e n e o u s or h e t e r o g e n e o u s . This is s h o w n in the following: 1.3.4.- Properties of Solids Variation In H o m o g e n e o u s Solids:
Elemental
S t r u c t u r e only
H e t e r o g e n e o u s Solids:
Compounds
S t r u c t u r e a n d Composition
W h a t this m e a n s is t h a t elements (e.g.- metals) c a n have m o r e t h a n one s t r u c t u r e . For example, Fe exists in 4 s t r u c t u r e s , i.e.- Fe is t e t r a m o r p h o u s . a-Fe is the one stable at r o o m t e m p e r a t u r e . But, it t r a n s f o r m s to ~-Fe, t h e n y-Fe a n d finally ~ -Fe as the t e m p e r a t u r e is raised. These c h a n g e s are all reorganizations
in
packing
d e n s i t y before
the
melting
temperature
is
reached. In c o n s t r a s t , h e t e r o g e n e o u s solids u s u a l l y exist in one s t r u c u r a l
23
modification (a few c h a n g e s t r u c t u r e as t e m p e r a t u r e is increased) b u t t h e y exist in m a n y compositions, d e p e n d i n g u p o n how t h e y were formed. For example, a large n u m b e r of c a l c i u m silicates are known, including: 1.3.5.- Known C a l c i u m Silicates Ca2SiO 3
Ca 3 Si20v
Ca4Si2Ov(OH)2
CaSi205
Ca2SiO4
Ca9Si6021(OH)
CaSiO 3
Ca4(ShO 17)(OH)~.
This is only a partial list (I c o u n t e d 58 k n o w n c o m p o u n d s
of varying
composition). E a c h h a s its own composition a n d sWacture. In order to differentiate a m o n g s u c h complicated s y s t e m s , i.e.- o x y g e n a t e d c o m p o u n d s of c a l c i u m a n d silicon, we r e s o r t to w h a t is called a "phase-diagram". A p h a s e d i a g r a m s h o w s t h o s e c o m p o u n d s w h i c h are formed w h e n varying m o l a r ratios of CaO a n d SiO 2 are r e a c t e d together. 1.-4. P h a s e Relations Between Individual Solids To differentiate a n d to be able to d e t e r m i n e the differences b e t w e e n the p h a s e s t h a t m a y arise w h e n two c o m p o u n d s are p r e s e n t (or are m a d e to r e a c t together), we u s e w h a t are t e r m e d " p h a s e - d i a g r a m s " to illustrate the n a t u r e of the i n t e r a c t i o n s b e t w e e n two solid p h a s e compositions. Consider the following. S u p p o s e we have two solids, "A" a n d "B". It does not m a t t e r w h a t the exact composition of e a c h m a y be. A will have a specifc melting point (ff it is stable a n d does not d e c o m p o s e at the M.P.) a n d likewise for the c o m p o u n d , B. We f u r t h e r s u p p o s e t h a t the M.P. of B is h i g h e r t h a n t h a t of A. F u r t h e r m o r e , we s u p p o s e t h a t A a n d B form a solid solution at all v a r i a t i o n s of composition. W h a t this m e a n s is t h a t from 100% A- 0% B to 50% A-50% B to 0% A-100% B, the two solids dissolve in one a n o t h e r to form a completely h o m o g e n o u s single p h a s e . If we plot the M.P. of the system, we find t h a t t h r e e different c u r v e s could result, as s h o w n in t h e following diagram, given as 1.4.1. on the n e x t page. In this case, the m e l t i n g point of the ideal solid solution s h o u l d i n c r e a s e linearly as the ration of B / A increases. However, it u s u a l l y does not.
24
Either a negative deviation or a positive deviation is regularly observed. In any p h a s e diagram, composition is plotted against temperature. In this way, we can see how the interactions between p h a s e s change as the t e m p e r a t u r e changes a n d the behavior as each solid p h a s e then melts. Either two-phase or three p h a s e sys t em s can be illustrated. This is shown in the following:
Here, the two-phase diagram is simplified to show a hypothetical p h a s e involving "A" and "B" c o m p o u n d s which form a solid solution from 100% A to 100% B. The solid solution is labelled as "r The melting t e m p e r a t u r e of A is higher t h a n t h a t of B. Therefore, the melting t e m p e r a t u r e of a drops as the composition becomes richer in B. At specific t e m p e r a t u r e s on the diagram (see 1. & 2.), a two-phase s y s t e m appears, t h a t of a liquid plus t h a t of a. Finally, as the t e m p e r a t u r e rises, the melt is h o m o g e n o u s a n d the solid, a , h a s melted. In the t h r e e - p h a s e system, only the relationship between A, B
25
a n d C c a n be i l l u s t r a t e d on a t w o - d i m e n s i o n a l drawing. A t h r e e - d i m e n s i o n a l d i a g r a m w o u l d be r e q u i r e d to s h o w the effect of t e m p e r a t u r e as well. The p h a s e d i a g r a m s we have s h o w n are b a s e d u p o n the fact t h a t A a n d B form solid m u t u a l l y soluble solid s t a t e solutions. If t h e y do not, i.e.- t h e y are not m u t u a l l y soluble in the solid state, t h e n the p h a s e d i a g r a m b e c o m e s m o r e complicated. As a n example, consider the foUowing, w h i c h is the c a s e of limited solid solubility b e t w e e n A a n d B. (N.B.- s t u d y the following d i a g r a m s carefully)"
Here, we have the c a s e w h e r e A & B form two slightly different c o m p o n d s , a a n d ~. The composition of a is AxBy while t h a t of ~ is AuBv , w h e r e the s u b s c r i p t s indicate the ratio of A to B (these n u m b e r s m a y be whole n u m b e r s or t h e y m a y be fractional n u m b e r s ) . At low B c o n c e n t r a t i o n s , a exists as a solid (the left side of the diagram). As the t e m p e r a t u r e increases, a m e l t is o b t a i n e d a n d a r e m a i n s a s a solid in the melt (L) {This is indicated by the details given j u s t below the s t r a i g h t line in the diagram}. As the t e m p e r a t u r e is increased, t h e n a m e l t s to form a u n i f o r m liquid. In the middle c o n c e n t r a t i o n s , r a n d g exist as two s e p a r a t e p h a s e s . At 75% A-25% B, ~ m e l t s to form a liquid p l u s solid a w h e r e a s j u s t the opposite o c c u r s at 25% A a n d 75% B. W h e n A e q u a l s B, t h e n b o t h a a n d ~ m e l t together to form the liquid melt, i.e.- the "eutectic point".
26
In two similar c a s e s b u t differing cases, i.e.- a s y s t e m with a melting point m i n i m u m a n d a n o t h e r with a different type of limited solid solubility, the behavior differs as s h o w n in the following diagram:
In the case on the left, a composition exists w h i c h in w h i c h a m i n i m u m melting point exists. Again, A a n d B form a w h i c h partially melts to form a + L. However, two forms of a also exist, a compositional a r e a k n o w n as a "miscibility gap", i.e.- " a l a n d a2". But at higher t e m p e r a t u r e s , b o t h of t h e s e melt into the single p h a s e , a. Finally, we obtain the melt p l u s a. Note t h a t at a b o u t 80% a i - 2 0 % a ~ , a melting point m i n i m u m is seen w h e r e it
melts
directly i n s t e a d of forming the t w o - p h a s e system, a + L. In the case of limited solid solubility, the p h a s e b e h a v i o r b e c o m e s m o r e complicated. Here, b o t h a a n d ~ form (where the a c t u a l composition of a is AxBy while t h a t of ~ is A u B v , as given before. Note t h a t the values of x a n d y change, b u t t h a t we still have the a phase. The s a m e holds for u a n d v of the phase). At low A c o n c e n t r a t i o n s , a exists alone while ~ exists alone at higher B c o n c e n t r a t i o n s . A region exists w h e r e the two p h a s e system,
+
exists. We notew t h a t as the t e m p e r a t u r e is raised, a two p h a s e s y s t e m is also seen consisting of the melt liquid p h u s a solid p h a s e . The p h a s e behavior s h o w n on the right side of the d i a g r a m arises b e c a u s e the two p h a s e s , A a n d B, have limited solubility in each other.
27
Now, let u s consider the case w h e r e three (3) s e p a r a t e p h a s e s a p p e a r in the p h a s e diagram, s h o w n as follows:
In this case, we have three (3) s e p a r a t e p h a s e s t h a t a p p e a r in the p h a s e diagram. T h e s e p h a s e s are a , ~, a n d o , w h o s e c o m p o s i t i o n s are: ct = AxBy, = AuBv a n d ~ - AcBd, respectively (the v a l u e s of x, y, u, v, c, a n d d all differ from e a c h other so t h a t AxBy is a specific c o m p o u n d as are the others). By s t u d y i n g this p h a s e d i a g r a m carefully, you c a n see how t h e individual p h a s e s relate to e a c h other. As you c a n see, a p h a s e d i a g r a m c a n b e c o m e quite complicated. However, in m o s t c a s e s involving real c o m p o u n d s , the p h a s e d i a g r a m s are u s u a l l y simple. Those involving c o m p o u n d s like silicates c a n be complex, b u t those involving alloys of m e t a l s s h o w simple behavior like limited solubility. R E F E R E N C E S CITED I. "Dictionary of Scientific a n d Technical Terms" - D.N. Lapedes- Editor in Chief, McGraw-Hill, New York (1978)
28
(2) "Enclyclopedia of Physics- 2 n d Ed." - Edited b y R.G. Lerner & G.L. Trigg, VCH Publishers, NY (1990). PROBLEMS FOR CHAPTER 1 i. Given I 0 . 0 g r a m s of ice at - 65 ~
calculate the n u m b e r of calories
required to c h a n g e it to s t e a m at 240 ~ 2. Do the s a m e for 24.0 g r a m s of ice at -11 ~ converted to boiling water. 3. Look u p the following h e a t capacities: Br2 CO2 PCI3 CH4 NH3 C2H4 NH3 CO2
- gases - liquids - solids
4. List aU of the metallic e l e m e n t s a n d their crystal s t r u c t u r e s . 5. List the n u m b e r of expected vibrational a n d rotational m o d e s for the following g a s e o u s molecules: Br2
co2 PCI3
cI-14 C2H4 C2H6 6. Draw the following p l a n e s for the cubic lattice (see C h a p t e r 2 for help): {101} {222} {101} {301}.
29
7. Given the foUowing phase diagram, label the individual phases present, assu.~ that three phases are present. Use a , 13, and o as symbols for the three phases:
This Page Intentionally Left Blank
31
Chapter 2 D e t e r m i n i n g t h e S t r u c t u r e of Solids This c h a p t e r will p r e s e n t m o r e a d v a n c e d topics t h a n t h o s e of the first c h a p t e r in t e r m s of d e t e r m i n i n g the s t r u c t u r e of solids. C o n s e q u e n t l y , you will gain s o m e
knowledge
of h o w
one
goes
about
determining
the
s t r u c t u r e of a solid, even if you n e v e r have to do it. 2 . 1 - S C I E N T I F I C DETERMINATION OF THE STRUCTURE OF SOLIDS In this section,
we will p r e s e n t
the
basis developed
to explain
the
s t r u c t u r e of solids. T h a t is, t h e c o n c e p t s t h a t w e r e p e r f e c t e d in o r d e r to a c c u r a t e l y d e s c r i b e h o w a t o m s or ions fit t o g e t h e r to form a solid p h a s e . This w o r k was a c c o m p l i s h e d by m a n y p r i o r w o r k e r s w h o e s t a b l i s h e d t h e r a t i o n a l e u s e d to define the s t r u c t u r e of a s y m m e t r i c a l solid. As you will recall, we said t h a t the basic difference b e t w e e n a gas, liquid a n d t h a t of a solid lay in the o r d e r l i n e s s of the solid, c o m p a r e d to t h e o t h e r p h a s e s of the s a m e m a t e r i a l .
We
have
already
indicated
that
solids
can
have
several
forms
or
s y m m e t r i e s . To e l u c i d a t e the s t r u c t u r e of solids in m o r e detail, at l e a s t t h r e e p o s t u l a t e s apply: First, the f o r m a t i o n of a solid r e s u l t s from a s y m m e t r i c a l "stacking" of a t o m s to n e a r infinity from a t o m s or m o l e c u l e s with s p a c i n g s is m u c h s m a l l e r t h a n t h o s e f o u n d in the liquid or g a s e o u s state. S e c o n d l y , if we w i s h to gain an i n s i g h t into h o w t h e s e a t o m s are a r r a n g e d in the solid, we n e e d to d e t e r m i n e w h a t k i n d of p a t t e r n t h e y form w h i l e in close p r o x i m i t y . T h i r d l y , we c a n t h e n relate o u r p a t t e r n
to o t h e r
structures
and thus
define the s y m m e t r y of solids in g e n e r a l . One w a y to a p p r o a c h a solution of the last two p o s t u l a t e s is to define t h e
32
s t r u c t u r e of any given solid in t e r m s of its l a t t i c e p o i n t s , W h a t this m e a n s is t h a t by s u b s t i t u t i n g a p o i n t for e a c h atom(ion) c o m p o s i n g the s t r u c t u r e , we find t h a t t h e s e p o i n t s c o n s t i t u t e a latticework, i.e.- t h r e e - d i m e n s i o n a l solid, having c e r t a i n s y m m e t r i e s (Examples of the s y m m e t r i e s to w h i c h we refer are given in 1.3.2. of C h a p t e r 1). A lattice is not a s t r u c t u r e per se. A lattice is d e f i n e d as a s e t of t h r e e d i m e n s i o n a l p o i n t s , having a c e r t a i n s y m m e t r y . T h e s e p o i n t s may, or m a y
not, be totally o c c u p i e d by the a t o m s c o m p o s i n g the s t r u c t u r e . C o n s i d e r a cubic s t r u c t u r e s u c h as t h a t given in the following diagram:
Here, we have a set of p o i n t s o c c u p i e d by a t o m s (ions) a r r a n g e d in a simple
three-dimensional
cubic
pattern.
The
lattice
directions
are
defined, b y c o n v e n t i o n , as x , y & z. Note t h a t t h e r e are eight (8) c u b e s in our example. In o r d e r to f u r t h e r define o u r cubic p a t t e r n , we n e e d to analyze b o t h t h e s m a l l e s t Unit a n d h o w it fits into the lattice. We call the s m a l l e s t Unit a "unit-cell" a n d find t h a t t h e u n i t - c e l l is the s m a l l e s t c u b e in the d i a g r a m .
33
We also n e e d to define h o w large t h e u n i t - c e l l is in t e r m s of b o t h t h e l e n g t h of its s i d e s a n d its v o l u m e . We do so b y d e f i n i n g
the
unit-cell
d i r e c t i o n s in t e r m s of its "lattice u n i t - v e c t o r s " . T h a t is, we define it in t e r m s of t h e x, y, & z d i r e c t i o n s
of t h e u n i t cell w i t h specific v e c t o r s
h a v i n g d i r e c t i o n s c o r r e s p o n d i n g to:
X~X
Z-~ ~
w i t h t h e l e n g t h of e a c h u n i t - v e c t o r b e i n g e q u a l to 1.0. (Our n o t a t i o n for a v e c t o r h e n c e f o r t h is a l e t t e r w h i c h is "outlined", e.g.- ~ is d e f i n e d h e r e as t h e u n i t - c e l l v e c t o r in t h e "x" d i r e c t i o n ) .
As you p r o b a b l y r e m e m b e r ,
a
"vector" is specified as a line w h i c h h a s b o t h d i r e c t i o n a n d d u r a t i o n f r o m a given p o i n t . We c a n n o w define a set of v e c t o r s called " t r a n s l a t i o n " v e c t o r s , i.e.- a , ~, a n d ~ in t e r m s of t h e following: 2.1.2.-
a. = a x ~
+ a y :y + a z g
b=bxz
+t~]] +bz~
= Cx :~
+ Cy ]
+ Cz
Here, t h e a , b, a n d ~ v e c t o r s are n o w d e f i n e d in t e r m s of t h e a, b, a n d c lattice c o n s t a n t s in e a c h of t h e x, y, a n d z d i r e c t i o n s of 2.1.1., w h e r e a, b, a n d c are lattice c o n s t a n t s . T h e y are real n u m b e r s ~ n g s t r o m (A) d i s t a n c e u n i t s , i.e.- 10- 8 c m .
corresponding
to
Note t h a t we n o w have: a as a v e c t o r in t e r m s of x, y a n d z v e c t o r s as a f u n c t i o n of t h e lattice d i s t a n c e s in t h e t h r e e d i r e c t i o n s ,
ax,
ay
& az.
Here, a = ax, ay & az, i.e.- a is c o m p o s e d of c o m p o n e n t s in e a c h of t h e t h r e e d i r e c t i o n s . T h e s a m e h o l d s for b, a n d ~ v e c t o r s .
34
In g e n e r a l , we u s e o n l y t h e lattice c o n s t a n t s to define t h e solid s t r u c t u r e ( u n l e s s we
are a t t e m p t i n g
to d e t e r m i n e
its synm~etry). We c a n
then
define a s t r u c t u r e factor k n o w n as t h e t r a n s l a t i o n vector. It is a e l e m e n t r e l a t e d to t h e u n i t cell a n d d e f i n e s t h e b a s i c u n i t of t h e s t r u c t u r e . We will call it ~ . It is d e f i n e d a c c o r d i n g to t h e following e q u a t i o n : 2.1.3.-
=
n l & + n2 5
w h e r e n l , n2 , a n d n3
+ n3
are i n t e r c e p t s of t h e u n i t - v e c t o r s , ~ , y , a , o n
t h e x, y, & z - d i r e c t i o n s in t h e lattice, r e s p e c t i v e l y . T h e u n i t cell vohxme is t h e n d e f i n e d as: 2.1.4.-
V
Vector
=
{ ~-
]
x a }
(This is a " d o t - c r o s s " v e c t o r p r o d u c t ) .
n o t a t i o n is b e i n g u s e d h e r e b e c a u s e t h i s is t h e
e a s i e s t w a y to
define t h e unit-cell. T h e r e a s o n for u s i n g b o t h u n i t lattice v e c t o r s a n d translation vectors parameters
lies in t h e
in t e r m s
fact t h a t we c a n n o w
of a, b, a n d c (which
specify
unit-cell
are t h e i n t e r c e p t s
of t h e
t r a n s l a t i o n v e c t o r s o n t h e lattice). T h e s e ceil p a r a m e t e r s are v e r y useful since t h e y specify t h e actual l e n g t h a n d size of t h e u n i t cell, usually in A., as we shall see. A l t h o u g h t h e cubic s t r u c t u r e looks like t h e s i m p l e s t o n e of t h o s e p o s s i b l e , it actually is t h e m o s t c o m p l i c a t e d in t e r m s of s y m m e t r y . W h a t t h i s m e a n s is t h a t we c a n "spin" t h e lattice by h o l d i n g
it at a c e r t a i n
point
and
r o t a t i n g it a r o u n d t h i s axis w h i l e still m a i n t a i n i n g t h e s a m e a r r a n g e m e n t of a t o m s in space. (Take a c u b e a n d do t h i s for yourself). T h e c u b i c l a t t i c e gives
rise
to
a great
synm~etrical l a t t i c e s
many (As we
symmetry will
see,
elements if t h e
in
lattice
to
less
is e l o n g a t e d
contrast
and
d i s t o r t e d f r o m cubic, s o m e of t h e s e synm~etry e l e m e n t s do n o t arise). In 1 8 9 5 , R 6 n t g e n e x p e r i m e n t a l l y d i s c o v e r e d "x-rays" a n d p r o d u c e d
the
first p i c t u r e of t h e b o n e s of t h e h u m a n h a n d . This w a s followed b y w o r k by von Laue in 1912 w h o s h o w e d t h a t solid c r y s t a l s c o u l d act as d i f f r a c t i o n gratings depended
to f o r m
symmetrical
patterns
of "dots"
whose
arrangement
u p o n h o w t h e a t o m s w e r e a r r a n g e d in t h e solid. It w a s s o o n
35
realized t h a t the a t o m s f o r m e d
"planes" w i t h i n the solid. In 1913,
Sir
William H e n r y Bragg a n d his son, William L a w r e n c e Bragg, analyzed t h e m a n n e r in w h i c h s u c h x-rays w e r e reflected
by p l a n e s of a t o m s in t h e
solid. T h e y s h o w e d t h a t t h e s e reflections w o u l d be m o s t i n t e n s e at c e r t a i n angles, a n d t h a t the values w o u l d d e p e n d u p o n the d i s t a n c e b e t w e e n t h e p l a n e s of a t o m s in the crystal a n d u p o n the w a v e l e n g t h of t h e x-ray. T h i s r e s u l t e d in t h e Bragg equation:
2.1.5.-
n~. = 2d sin 0
w h e r e d is t h e d i s t a n c e in a n g s t r o m s (A = 10 -8 cm) b e t w e e n p l a n e s a n d 0 is the angle in d e g r e e s of the reflection. In Bragg's x - r a y diffraction equation, i.e.- the a n g l e , 0 , is actually t h e angle b e t w e e n a given p l a n e of a t o m s in the s t r u c t u r e a n d the l m t h of the x - r a y b e a m . The unit, "d", is defined as the d i s t a n c e b e t w e e n p l a n e s of the lattice a n d k is t h e wavelength
of the
radiation.
It
was
Georges
Friedel
who
in
1913
d e t e r m i n e d t h a t the i n t e n s i t i e s of reflections of x - r a y s from t h e s e p l a n e s in the solid could be u s e d to d e t e r m i n e the s y m m e t r y of the solid. T h u s , by convention, we usually define planes, not points, in t h e lattice. We have i n t r o d u c e d the t e r m "symmetry" in the solid. Let u s n o w e x a m i n e exactly w h a t is m e a n t by t h a t t e r m . To illustrate this c o n c e p t ,
examine
the s y m m e t r y e l e m e n t s of o u r cube, given in the follovcing d i a g r a m , given on the n e x t page as 2 . 1 . 6 . In this case, we c a n s h o w t h a t the p l a n e s of the cubic lattice are d e f i n e d by m o v i n g various d i s t a n c e s in t h e lattice from t h e origin. W h a t is m e a n t by this t e r m i n o l o g y is t h a t as we move from the (0,0,0) origin j u s t 1 . 0 0 unit-cell d i s t a n c e in the x" d i r e c t i o n to the (1,0,0) point in the cubic lattice, we have defined t h e {100} p l a n e (Note t h a t ,are are u s i n g t h e n l i n t e r c e p t of the unit-cell). In a like m a n n e r , if we move in t h e "y" d i r e c t i o n a d i s t a n c e of j u s t 1 unitcell, we have defined the {010} plane. Using the the "z" d i r e c t i o n s gets us a set of o n e - d i m e n s i o n a l p l a n e s (See line A in 2 . 1 . 6 . ) .
36
By m o v i n g I unit-cell d i s t a n c e in the b o t h the x- a n d y - d i r e c t i o n s , t h e {110) h a s b e e n defined, etc. (Line B a b o v e - n o t e t h a t we have n o t i l l u s t r a t e d the {101} plane). Moving 1 unit-cell in all t h r e e d i r e c t i o n s t h e n gives u s t h e {111} plane. In a l i k e m a n n e r , we c a n o b t a i n the {200}, {020}
37
a n d {002} planes. A set of p l a n e s s u c h as the {003} a n d {004} series a r e not as c o m m o n , b u t do exist in s o m e solids. Also s h o w n are the r o t a t i o n a l axes of the cubic lattice, s h o w n as the diad, t r i a d a n d t e t r a d axes. "What this m e a n s is ff ,are spin t h e c u b e on its face, we u s e the t e t r a d axis to d e t e r m i n e t h a t it t a k e s a total of 4 t u r n s to b r i n g a n y specific c o r n e r b a c k to its original position. Likewise, the t r i a d axis u s e s t h e c o r n e r of the c u b e where
the lattice is m o v e d
a total of t h r e e
times,
a n d t h e diad axis
e m p l o y s the diagonal a c r o s s t h e cube to p e r f o r m the synm~ehur o p e r a t i o n . T h u s , t h e p l a n e s of the lattice are f o u n d to be i m p o r t a n t
and can be
defined by m o v i n g along one or m o r e of t h e lattice d i r e c t i o n s of the unitcell to define t h e m . Also i m p o r t a n t are the s y m m e t r y o p e r a t i o n s t h a t c a n be p e r f o r m e d w i t h i n the unit-cell, as we have i l l u s t r a t e d in the p r e c e d i n g diagram. T h e s e give rise to a total of 14 different lattices as we will s h o w below. But first, let us confine o u r d i s c u s s i o n to j u s t the simple cubic lattice. It t u r n s out t h a t t h e m e t h o d u s e d to decribe the p l a n e s given above for the cubic lattice c a n also be u s e d to define the p l a n e s of all of the k n o w n lattices, by u s e of t h e so-called "Miller Indices", w h i c h are r e p r e s e n t e d by: 2.1.7.-
{h,k,l}
T h e w a y t h a t Miller I n d i c e s a r o s e c a n be u n d e r s t o o d by c o n s i d e r i n g t h e h i s t o r y of crystal s t r u c t u r e work, a c c o m p l i s h e d by m a n y i n v e s t i g a t o r s . In 1921, E~wald d e v e l o p e d a m e t h o d of c a l c u l a t i n g the s u m s of diffraction i n t e n s i t i e s from different p l a n e s in the lattice by c o n s i d e r i n g called t h e
"Reciprocal
Lattice".
The
reciprocal
lattice
w h a t is
is o b t a i n e d
by
d r a w i n g p e r p e n d i c u l a r s to e a c h p l a n e in the lattice, so t h a t the axes of t h e r e c i p r o c a l lattice are p e r p e n d i c u l a r to t h o s e of the c r y s t a l lattice. This has t h e r e s u l t t h a t t h e p l a n e s of the r e c i p r o c a l lattice are at right angles (90 ~) to the real p l a n e s in the unit-cell. For o u r cubic lattice, t h e r e c i p r o c a l lattice -would look as s h o w n in t h e following d i a g r a m , given as 2.1.8 on t h e n e x t page.
38
In this diagram, a series of h e x a g o n - s h a p e d p l a n e s are s h o w n w h i c h are orthogonal, or 90 degrees, to each of the c o r n e r s of the cubic cell. E a c h plane c o n n e c t s to a n o t h e r plane (here s h o w n as a rectangle) on e a c h face of the unit-ceU. T h u s , the faces of the lattice unit-cell a n d t h o s e of t h e r e c i p r o c a l unit-cell c a n be s e e n to lie on the s a m e plane while t h o s e at the c o r n e r s lie at right angles to the c o r n e r s . The n o t i o n of a r e c i p r o c a l lattice arose from Ewald who u s e d a s p h e r e to represent
how the x-rays i n t e r a c t with any given lattice plane in t h r e e
d i m e n s i o n a l space. He e m p l o y e d w h a t is now called the Ewald Sphere to s h o w how reciprocal space could be utilized to r e p r e s e n t diffractions of xrays by lattice planes. Ewald originally r e w r o t e the Bragg e q u a t i o n as: 2.1.9.-
sin 0
=
n k/ 2d {hkl}
=
1 / d {hkl} 2/X
Using this equation, Ewald applied it to the case of the diffraction s p h e r e w h i c h we s h o w in the following d i a g r a m as 2.1.10.
on the n e x t page.
S t u d y this d i a g r a m carefully. In this case, the x-ray b e a m e n t e r s
the
s p h e r e e n t e r s from the left a n d e n c o u n t e r s a lattice plane, L. It is t h e n diffracted by the angle 20 to the p o i n t on the s p h e r e , P, w h e r e it
39
is r e g i s t e r e d as a diffaction p o i n t on the r e c i p r o c a l lattice. The d i s t a n c e b e t w e e n p l a n e s in the r e c i p r o c a l lattice is given as 1/dhkl w h i c h is r e a d i l y o b t a i n e d from the diagram. It is for t h e s e r e a s o n s , we c a n u s e the Miller Indices to indicate p l a n e s in the real lattice.
The
reciprocal
lattice
is useful in
defining
some
of the
electronic
p r o p e r t i e s of solids. T h a t is, w h e n we have a s e m i - c o n d u c t o r (or even a c o n d u c t o r like a metal), we find t h a t the e l e c t r o n s are confined in a b a n d , defined by the reciprocal
lattice. This h a s i m p o r t a n t
effects u p o n t h e
c o n d u c t i v i t y of any solid a n d is k n o w n as the "oand theory" of solids. It t u r n s out t h a t the r e c i p r o c a l lattice is also the site of the Brfllouin zones, i.e.- the "allowed" electron e n e r g y b a n d s in the solid. How this o r i g i n a t e s is e x p l a i n e d as follows. The free electron r e s i d e s in a q u a n t i z e d e n e r g y well, defined by k (in w a v e - n u m b e r s ) . This r e s u l t c a n be derived from the S c h r o e d i n g e r waveequation. However, in the p r e s e n c e of a periodic a r r a y of e l e c t r o m a g n e t i c p o t e n t i a l s arising f r o m the a t o m s c o n f i n e d in a crystalline lattice,
the
energies of the e l e c t r o n s f r o m all of the a t o m s are severely limited in orbit a n d are r e s t r i c t e d
to specific allowed e n e r g y b a n d s . T h i s p o t e n t i a l
o r i g i n a t e s from a t t r a c t i o n a n d r e p u l s i o n of the e l e c t r o n c l o u d s from t h e periodic array of a t o m s in the s t r u c t u r e . S o l u t i o n s to this p r o b l e m w e r e
40
made
b y B l o c h in
1930
who
showed
they
had
the
form
(for
a one-
as m o d i f i e d
by the
dimensional lattice). 2.1.11.-
=
e ikx u ( x ) - o n e d i m e n s i o n a l
~ k (a) =
where
e ika u k (X) - t h r e e d i m e n s i o n a l
k is t h e w a v e n u m b e r
of the
allowed
band
l a t t i c e , a m a y b e x, y o r z, a n d uk (x) is a p e r i o d i c a l f u n c t i o n w i t h t h e s a m e p e r i o d i c i t y as t h e p o t e n t i a l . O n e r e p r e s e n t a t i o n
is s h o w n in t h e f o l l o w i n g :
41
We have s h o w n the least c o m p l i c a t e d
one w h i c h
t u r n s o u t to be t h e
simple cubic lattice. S u c h b a n d s are called "BriUuoin" zones a n d , have said,
are the
allowed
energy
bands
of e l e c t r o n s
in
as w e
any given
crystalline latttice. A n u m b e r of m e t a l s a n d simple c o m p o u n d s have b e e n s t u d i e d a n d t h e i r Brilluoin s t r u c t u r e
determined.
However,
when
one
gives a r e p r e s e n t a t i o n of t h e e n e r g y b a n d s in a solid, a "band-model" is usually p r e s e n t e d . T h e following d i a g r a m s h o w s t h r e e b a n d m o d e l s : 2.1.13.- E n e r g y B a n d M o d e l s
In the solid, e l e c t r o n s r e s i d e in the valence b a n d b u t c a n be excited i n t o the c o n d u c t i o n b a n d by a b s o r p t i o n of energy. The e n e r g y gap of various solids d e p e n d s u p o n the n a t u r e of the a t o m s c o m p r i s i n g the solid. S e m i c o n d u c t o r s have a r a t h e r n a r r o w e n e r g y gap (forbidden
zone) vchereas
t h a t of i n s u l a t o r s is wide (metals have little or no gap). Note t h a t e n e r g y levels of the a t o m s "A" are s h o w n in the valence b a n d . T h e s e will vary d e p e n d i n g u p o n the n a t u r e a t o m s p r e s e n t . We will n o t delve f u r t h e r into this a s p e c t h e r e
since it is the s u b j e c t of m o r e
electronic a n d optical m a t e r i a l s .
advanced studies
of
42
R e t u r n i n g to t h e u n i t - c e l l , we c a n also utilize t h e v e c t o r m e t h o d to d e r i v e t h e origin of t h e Miller I n d i c e s . T h e g e n e r a l e q u a t i o n for a p l a n e in t h e l a t t i c e is: 2.1.14.-
~ x,y,z o ~
= d
w h e r e ~ x,y,z is t h e l a t t i c e u n i t v e c t o r in a n y of t h e t h r e e d i m e n s i o n s , ~ is t h e g e n e r a l v e c t o r of t h e l a t t i c e f r o m t h e origin a n d d is, of c o u r s e , t h e distance
between
planes
of
the
lattice
from
the
origin.
A better
p e r s p e c t i v e is s h o w n in t h e following d i a g r a m :
If ~ x,y,z is n o r m a l to t h e real l a t t i c e p l a n e (as in t h e r e c i p r o c a l Lattice}, we c a n define t h e x, y a n d z d i r e c t i o n s of t h e u n i t cell in t e r m s of t h e u n i t cell v e c t o r s a n d t h e c o r r e s p o n d i n g
intercepts
of t h e r e c i p r o c a l
lattice,
i.e.- h, k, a n d 1: 2.1.16.-
x=~/h
y=]
/k
z=a
/1
T h e n , t h e l a t t i c e u n i t v e c t o r will be: 2.1.17.-
~ h,k,1 = 1/ {h 2 + k 2 + 12} 1/2 {11 ~, + k :~ + 1 ~}
w h e r e we h a v e c o n v e r t e d t h e x, y a n d z d i r e c t i o n s into i n t e r c e p t s of t h e reciprocal
l a t t i c e cell. As we s h a l l see,
this equation
is also useful in
d e r i v i n g e q u a t i o n s d e s c r i b i n g s y n m l e t r y o p e r a t i o n s a n d p l a n e s p a c i n g s of t h e real l a t t i c e .
43
To s h o w t h a t t h e above d i s c u s s i o n is t r u e , c o n s i d e r t h e following. Let us set u p a p l a n e of a c u b i c lattice as s h o w n in t h e following d i a g r a m :
In t h i s case, we have s h o w n a {310} p l a n e of a c u b i c lattice. Note t h a t w e m o v e 3 s t e p s of "a" in t h e x - d i r e c t i o n
a n d o n e in t h e "y" d i r e c t i o n
to
define t h i s plane. S i n c e a p l a n e is t w o - d i m e n s i o n a l , t h i s r e p r e s e n t a t i o n is a c c u r a t e . T h e e q u a t i o n of a n y o n e of t h e e l e m e n t s of t h i s p l a n e is t h u s : 2.1.19.-
a = 3x + y
a n d if we h a d b or c (both of w h i c h e q u a l "a" in a c u b i c lattice), we c o u l d t h e n u s e a , b, & c to r e p r e s e n t t h e l e n g t h s of t h e s i d e s of t h e u n i t - c e l l w h i c h in t u r n define t h e p l a n e s w i t h i n t h e u n i t ceil. For t h e cubic l a t t i c e , t h e n we have: 2.1.20.-
Note
d = 1/(h 2 + k 2 + 1 2)1/2 . [ h ~ + h : y + h ~ ]
that just three
2.1.6.).
points
have been
u s e d to define
our plane
T h e original d e f i n i t i o n w a s given by W h e w e l l in
G r a s s m a n in 1829, b u t w a s p o p u l a r i z e d b y Miller in 1839.
1825
(see
a n d by
Since t h r e e
p o i n t s of a lattice c a n be u s e d to define a plane, it is obvious t h a t s u c h
44
p l a n e s c a n be d e f i n e d b y u s i n g o n l y t h r e e p o i n t s in s p a c e , i.e.- a , b & c, to c h a r a c t e r i z e t h e s e t of p l a n e s w i t h i n t h e l a t t i c e . Miller I n d i c e s are t h e r e c i p r o c a l s of t h e i n t e r c e p t s , a , b & c, of t h e c h o s e n p l a n e on t h e x , y , z - d i r e c t i o n s in t h e l a t t i c e (and r e l a t e to t h e n l, n2 a n d n3 i n t e r c e p t s w h i c h we u s e d in o u r d e f i n i t i o n of t h e unit-cell). How t h e y a r e u s e d is s h o w n in t h e following table: 2.1.21.-
P o i n t s on t h e L a t t i c e a n d C o r r e s p o n d i n g Miller I n d i c e s a,
b,
c
MILLER I N D I C E S
(1, 0, O)
{100}
( 1 / 2 , 0, 0 )
{200}
( o , ~/2, o)
{o2o}
(0, O, 1 / 2 )
{002}
Here, we h a v e d e f i n e d t h e s u m t o t a l of t h e i n t e r c e p t s in t e r m s of t h e u n i t cell d i s t a n c e b e i n g s e t e q u a l to 1.00, i.e.2.1.22.-
a/(1/h)
+b/(1/k)+c/(1/k)
= 1
Thus, these intercepts
are given in t e r m s of t h e a c t u a l u n i t - c e l l l e n g t h
f o u n d for t h e specific
structure,
and not the lattice
itself. T h e
Miller
I n d i c e s are t h u s t h e i n d i c e s of a stack of planes w i t h i n t h e lattice. P l a n e s are i m p o r t a n t in solids b e c a u s e , as we will see, t h e y are u s e d to l o c a t e a t o m p o s i t i o n s w i t h i n t h e lattice s t r u c t u r e . The
Final f a c t o r to c o n s i d e r
in o u r s t u d y of h o w to
define
the
s t r u c t u r e of solids is t h a t of t h e a n g l e b e t w e e n t h e x, y, a n d z d i r e c t i o n s in t h e lattice. directions
In o u r e x a m p l e
so far, all of t h e a n g l e s w e r e
9 0 ~ in all
(also called "orthogonal"). If t h e a n g l e s are n o t 9 0 ~ t h e n w e
h a v e a d d i t i o n a l l a t t i c e s to define. For a given u n i t - c e l l d e f i n e d b y t h e u n i t cell l e n g t h s , a, b & c, t h e c o r r e s p o n d i n g a n g l e s have b e e n d e f i n e d as: 2 . 1 . 2 3 . - N o t a t i o n U s e d for Del'ming Angles in t h e Solid L a t t i c e a=2~/n ~=2n/n 7=2~/n~
I
2
45
w h e r e ~ is t h e angle in t h e x - d i r e c t i o n , ~ is in t h e '~ d i r e c t i o n , etc. T h e i n t e r c e p t s are t h o s e of t h e lattice a n d n o t of t h e u n i t - c e l l .
Note t h a t c~ , ~,
Y = 9 0 o for t h e cubic lattice as given above as 2 . 1 . 1 .
This c o m p l e t e s o u r d i s c u s s i o n of t h e b a s i s a n d f a c t o r s d e v e l o p e d b y p a s t i n v e s t i g a t o r s to d e s c r i b e a n d c o n c e p t u l i z e t h e s t r u c t u r e of solids. You will n o t e t h a t we have n o t yet fully d e s c r i b e d t h e s y m m e t r y factor of solids. The r e a s o n for t h i s is t h a t we u s e s y m m e t r y f a c t o r s to c h a r a c t e r i z e s o l i d structure
without
resorting
to
the
theoretical
basis
of
structure
d e t e r m i n a t i o n . T h a t is, we h a v e a s t a n d a r d m e t h o d for c a t e g o r i z i n g s o l i d s t r u c t u r e s . We say t h a t salt, NaC1, is cubic. T h a t is, t h e Na § ion a n d t h e CI ion are a l t e r n a t e l y a r r a n g e d in a c l o s e - p a c k e d c u b i c s t r u c t u r e . T h e n e x t section now investigates these structure protocols. 2 . 2 . - Solid S t a t e S t r u c t u r e C o n v e n t i o n s a n d P r o t o c o l s We h a v e a l r e a d y d i s u s s e d s t r u c t u r e f a c t o r s a n d s y n m l e t r y as t h e y r e l a t e to t h e p r o b l e m of d e f i n i n g a c u b i c u n i t - c e l l a n d find t h a t still a n o t h e r f a c t o r exists if o n e is to c o m p l e t e l y define c r y s t a l s t r u c t u r e of solids.
This turns
o u t to be t h a t of t h e i n d i v i d u a l a r r a n g e m e n t of a t o m s w i t h i n t h e u n i t - c e l l . This t h e n gives u s a total of t h r e e (3) f a c t o r s are n e e d e d to define a g i v e n lattice. T h e s e c a n be s t i p u l a t e d as follows: 2 . 2 . 1 . - F a c t o r s N e e d e d to Fully Define a Crystal L a t t i c e
I
-
unit-cell a x e s , intercepts and angles
II - r o t a t i o n a l s y m m e t r y III - localized s p a c e g r o u p s y m m e t r y In t h e first F a c t o r , if t h e cell l e n g t h s are n o t equal, i.e. a ,
b
,
c, w e
no l o n g e r have a c u b i c lattice, b u t s o m e o t h e r type. A n d if t h e a n g l e s a r e no l o n g e r 9 0 ~ i.e.- ~ , b , g , t h e n w e have a c h a n g e in t h e lattice t y p e as well.
Additionally, we c a n have t h e s i t u a t i o n w h e r e r = ~ ,
and~,~,y,
or alternatively, a , ~
= Y, a = [3 ,
Y
anda,
y, ~,
~ = y
~,y.The
n u m b e r of c o m b i n a t i o n s t h a t w e c a n m a k e f r o m t h e s e 3 - l e n g t h s a n d 3angles is s e v e n (7) a n d t h e s e define t h e 7 u n i q u e lattice s t r u c t u r e s w h i c h
46
are called BRAVAIS LATFICES after the o r i g i n a t o r of the c o n c e p t . T h e s e have b e e n given specific n a m e s : 2.2.2.-
ORTHORHOMBIC
CUBIC HEXAGONAL
MONOCLINIC
T~GONAL
TRICLINIC
TRIGONAL We can t h e r e f o r e a r r a n g e the seven (7) s y s t e m s into a h i e r a r c h y b a s e d on s y m m e t r y , as s h o w n in the following d i a g r a m 2.2.3.-
IHierarchy of Crystal systems I
IHexag~
1 c~bic
j
!
!
IT~'g ~
I Orthorhomb, ci I M~176
I
I
ITriclinic I
I
Each System is a Special Case of Those Above It The lattice with the h i g h e s t s y m m e t r y is listed at the top, with the least s y m m e t r i c a l lattice b e i n g s h o w n at the b o t t o m .
E a c h of t h e s e
seven
lattices m a y have sublattices, the total being 14. The
following diagram, given on the next page as 2.2.4.,
shows
the
s y m m e t r y of t h e s e 14 Bravais space lattices in t e r m s of the seven crystal s y s t e m s given in 2.2.3. The specific r e s t r i c t i o n s are listed in Table 2-1 on the following page
along with
the
relation
between
axes a n d angles
47
48
a s s o c i a t e d w i t h e a c h s t r u c t u r e . C o n t r a s t b o t h t h e d a t a in T a b l e 2-1 a n d t h e d i a g r a m s in 2 . 2 . 4 .
in o r d e r
to get a c l e a r n o t i o n of t h e s y m m e t r y
f a c t o r s involved in t h e 14 Bravais l a t t i c e s .
TABLE 2- I T H E F O U R T E E N (14) BRAVAIS LATYICES IN T H R E E D I M E N S I O N S . N U M B E R OF
RESTRICTIONS
.LATTICES SYSTEM
ON UNIT C E I L
IN SYSTEM
Cubic
LATI'ICE SYMBOLS AXES AND ANGLES
P (primitive)
a=b=c =13
I(body-centered)
= "?' = 9 0 ~
F(face - c e n t e r e d ) Hexagonal
a=b~c (~ = ~ = ~ ((~ = ~ = 9 0 ~ (y = 1 2 0 o)
Tetragonal
a=
b r c =1~
Trigonal
R
=y=90
~
a=b=c (~ = ~ = 9 0 ~ 9 0 o > ~/ < 120 o
Orthorhombic
P
a~b,c
C
a = ~=~, = 9 0
~
I F Monoclinic Triclinic
P
as
C
a=
b~c 7 =90~
a,b#c
T h e f a c t o r s given in b o t h 2.2.4. a n d T a b l e 2-1 a r i s e d u e to t h e u n i t - c e l l axes, i n t e r c e p t s a n d
a n g l e s involved for a given c r y s t a l l a t t i c e s t r u c t u r e .
Also given a r e t h e l a t t i c e s y m b o l s w h i c h a r e g e n e r a l l y u s e d . T h e a x e s a n d a n g l e s given for e a c h s y s t e m a r e t h e r e s t r i c t i o n s on t h e u n i t cell to m a k e
49
it c o n f o r m to the p a r t i c u l a r type of lattice. T h e y c o m p l e t e l y define t h a t s t r u c t u r e except for the s y m m e t r y . These
14 Bravais Lattices are u n i q u e in t h e m s e l v e s .
If we a r r a n g e t h e
crystal s y s t e m s in t e r m s of s y m m e t r y , the c u b e h a s the h i g h e s t s y r m n e t r y a n d the triclinic lattice, the lowest s y m m e t r y , as we s h o w e d above. T h e s a m e h i e r a r c h y is m a i n t a i n e d in 2.2.4. as in Table 2-1. The s y m b o l s u s e d by c o n v e n t i o n in 2.2.4. to d e n o t e the type of lattice p r e s e n t are P
=
Primitive
I = I n v e r s i o n (or b o d y - c e n t e r e d ) F = Face-centered What tl~As m e a n s is t h a t the primitive lattice is c o m p o s e d of p o i n t s at t h e c o r n e r s of t h e lattice, w h e r e a s the i n v e r s i o n lattice h a s an additional p o i n t at the c e n t e r
of the
lattice,
i.e.-
"body-centered".
Face-centered
has
p o i n t s in the m i d d l e of e a c h face of the lattice in addition to t h o s e at t h e c o r n e r s of the lattice. If we n o w apply r o t a t i o ~ f l s y m m e t r y (Factor II given in 2.2.1) to the 14 Bravais lattices, we obtain the 32 P o i n t - G r o u p s w h i c h have the factor of s y m m e t r y i m p o s e d u p o n the 14 Bravais lattices. The s y m m e t r y e l e m e n t s t h a t have b e e n u s e d are: 2.2.5.-
Rotation axes Plane s y m m e t r y
< horizontal
vertical
Inversion s y m m e t r y ( m i r r o r ) We have already i l l u s t r a t e d r o t a t i o n axes in 2.1.6. Plane s y m m e t r y involves s y m m e t r y s u c h as t h a t of the h e x a g o n a l faces given above in 2.2.5. We will now e x a m i n e i n v e r s i o n or m i r r o r s y m m e t r y . One type m i r r o r s y m m e t r y is s h o w n in the following diagram, given as 2.2.6. on the n e x t page. If o n e h a s a s t r u c t u r e w h e r e t h e a t o m s are a r r a n g e d on the {001} p l a n e b u t are i n v e r t e d as s h o w n in the diagram, it is easy to see t h a t a m i r r o r p l a n e exists b e t w e e n t h e m . However, the a r r a n g e m e n t as s h o w n is
50
2.2.6.-
llnversionMirror Symmetry I
inverted. It is this k i n d of r o t a t i o n a n d
inversion t h a t will be s e e n to be
vital in fully d e s c r i b i n g the s t r u c t u r e of solids. We have already d e s c r i b e d
crystal s t r u c t u r e s in t e r m s
of p r o p a g a t i o n
units, i.e.- t r a n s l a t i o n , in w h i c h the crystal is c o m p o s e d of a small n u m b e r of individual a t o m s a r r a n g e d in a u n i t w h i c h is p r o l i f e r a t e d to form t h e solid. E a c h a s s e m b l y of atoms, i.e.- p r o p a g a t i o n units, is r e l a t e d to any o t h e r by one of four s i m p l e o p e r a t i o n s . T h e s e are: 2.2.7.- The Four Symmetry_ O p e r a t i o n s T r a n s l a t i o n , i.e.- from one plane to a n o t h e r Rotation about an axis of the crystal Reflection a c r o s s a p l a n e Inversion t h r o u g h a p o i n t T h e s e are the four m a i n o p e r a t i o n s r e q u i r e d to define the s y m m e t r y of a crystal s t r u c t u r e . The m o s t i m p o r t a n t is t h a t of t r a n s l a t i o n since each of the o t h e r p r o c e d u r e s ,
called s y m m e t r y o p e r a t i o n s , m u s t be c o n s i s t a n t
with the t r a n s l a t i o n o p e r a t i o n in the crystal s t r u c t u r e . T h u s , the r o t a t i o n o p e r a t i o n m u s t be t h r o u g h an angle of 2n / n, w h e r e n = 1, 2, 3, 4 or 6.
51
Note t h a t we have a l r e a d y s h o w n t h a t the cubic lattice c a n be r o t a t e d only in this m a n n e r , e x c e p t i n g six. We find t h a t t h e n u m b e r 6 c o m e s from t h e h e x a g o n a l lattice itself w h e r e the a r r a n g e m e n t of a t o m s is obvious (see 2.2.4.). E a c h of the o p e r a t i o n s involving crystal a s s e m b l y u n i t s c r e a t e s a special g r o u p : T r a n s l a t i o n a l symanetry o p e r a t i o n s g e n e r a t e the 14 Bravais lattices. The rotational o p e r a t i o n s g e n e r a t e a total of 32 Point G r o u p s d e r i v e d f r o m t h e s e s y m m e t r y o p e r a t i o n s on the 14 Bravais lattices. The reflections and inversions s y m m e t r y o p e r a t i o n s g e n e r a t e
a total of
231 groups, called Space Groups w h i c h i n c l u d e the 32 Point Groups. In
Point
Groups,
one
point
of the
lattice
remains
invarient
under
s y m m e t r y o p e r a t i o n s , i.e.- t h e r e is no t r a n s l a t i o n involved. S p a c e G r o u p s are s o - n a m e d b e c a u s e in e a c h g r o u p all t h r e e - d i m e n s i o n a l s p a c e r e m a i n s i n v a r i e n t u n d e r o p e r a t i o n s of the group. T h a t is, t h e y c o n t a i n t r a n s l a t i o n c o m p o n e n t s as well as the t h r e e s y m m e t r y o p e r a t i o n s . "We will not d w e l l u p o n t h e 231 S p a c e G r o u p s since t h e s e relate to d e t e r m i n i n g the e x a c t s t r u c t u r e of the solid. However, we will s h o w h o w the 32 Point G r o u p s relate to crystal s t r u c t u r e of solids. In 1890, Schoenflies f o r m u l a t e d a g r o u p of symbols d e s c r i b i n g the various r o t a t i o n s possible for Point Groups. T h e s e w e r e r e p l a c e d in 1936 by t h e International group
S y m b o l s or H e r m a n n - M a u g u i n
s y s t e m could
not
be
extended
to
Symbols, describe
since Space
the
point
Groups.
A
c o m p a r i s o n of the Point G r o u p Symbols are given in the following Table, given on the
next
page
as Table
2.2.
The
arrangement
shown
for
Schoenflies symbols in 2.2.8 on t h e n e x t page is inverted. It is this k i n d of r o t a t i o n a n d inversion t h a t will be s e e n to be vital in i~dlly d e s c r i b i n g t h e s t r u c t u r e of solids. S u b s c r i p t s in Table 2-2 are u s e d to i n d i c a t e the d e g r e e of the r o t a t i o n a l axes p r e s e n t , i.e.- C3 -- a three(3) fold r o t a t i o n a l axis. Horizontal s y n m l e t r y is i n d i c a t e d by "h" while vertical s y m m e t r y = v.
52
Table 2.2. - C o m p a r i s o n of Schoenflies a n d I n t e r n a t i o n a l S y m b o l s
crystaJ S y s t e m Name Cubic
Geometry a=b=c
r
Hexagonal
Tetragonal
Trigonal
Point Group S y s t e m
=7=90~
Bravais i
International
T
23
P
0 Th
432
I
m3
F
43m
Oh
m3m
a=13*c
C6
6
D6
622
(~=13 = 9 0 ~ (7 = 120 o)
C2h
6/m
C6v
6ram
C3h D3h
6 6m2
D6h
6/m
C4
4
b, c a = ~ = y = 9 0 ~ D4
i
or62m
422
C4h C4v
4/m
$4
D2d
4 4m2
D4h
4/mmm
4mm or 4 2 m
C3
a=b=c
D3 a = 13 = 9 0 ~ 9 0 o > y < 1 2 0 ~ C3v
32 3m
&
C3i
3 & 3 21m
D3d Orthorhombic
a~b~c a=
Monoclinic
as
~ =
b*c
a=~ Triclinic
7
=90~
a~b~c
,a,*
~'7
=
D2 9 0 ~ C2v
mm2
C
D2h
mmm
F
C2
2
P
7 C3
in
C
222
C2h
2/m
C1
1
q
,
,,
.
.
.
.
.
1
i
Lattice
Schoenflies
Td
a=
,,
P
53
In the Schoenflies notation, the e l e m e n t s defined a s 2.2.8.-
C = r o t a t i o n axis only D = d i h e d r a l (rotation p l u s d i h e d r a l r o t a t i o n axes) I = inversion s y m m e t r y T --- t e t r a h e d r a l s y m m e t r y 0-
octahedral symmetry
In t h e H e r m a n n - M a u g u i n Symbols, the s a m e r o t a t i o n a l axes are i n d i c a t e d , plus any inversion s y r m n e t r y t h a t m a y be p r e s e n t . T h e n u m b e r s i n d i c a t e the n u m b e r of r o t a t i o n s p r e s e n t , present
a n d the
inversion
m shows that a mirror
symmetry
is i n d i c a t e d
s y m m e t r y is
by a b a r over t h e
,_,-.
n u m b e r , i.e.- 5 . At this point, you m a y find t h a t the s u b j e c t of syrranetry in a c r y s t a l s t r u c t u r e to be confusing. However, by s t u d y i n g the t e r m i n o l o g y carefully in Table 2-2, one c a n begin to sort o u t t h e various l a t t i c e s t r u c t u r e s a n d the s y m b o l s u s e d to d e l i n e a t e t h e m . All of the crystal s y s t e m s c a n be described
by u s e of e i t h e r
Schoenflies
or H e r m a n n - M a u g u i n
symbols,
c o u p l e d w i t h t h e u s e of the p r o p e r g e o m e t r i c a l symbols. In 1965, specific d i a g r a m s w e r e developed by W e i n r e i c h to illustrate t h e 32 p o i n t - g r o u p
symmetries.
Appropriate
Schoenflies symbols w e r e
also
given. T h e s e d r a w i n g s are given on the following page as 2.2.10. If t h e y are e x a m i n e d differences
closely,
it b e c o m e s
in s y m m e t r y o p e r a t i o n s
easier
to a s s e s s
involved
and compare
for e a c h
the
type of l a t t i c e
s t r u c t u r e . As an example, c o n s i d e r the following. In the C l h
point group, t h e r e is a one-fold rotation axis p l u s h o r i z o n t a l
syTmnetry (horizontal mirror). Note also the difference b e t w e e n C l h a n d C2h. It is easy to see t h a t t h e s e point g r o u p s are r e l a t e d to one a n o t h e r , b u t t h a t t h e y specify quite different r o t a t i o n a l s y m m e t r i e s . In c o n t r a s t , C2 has a 2-fold r o t a t i o n axis b u t no h o r i z o n t a l s y m m e t r y (but C2h
has horizontal
s y m m e t r y ) . C o n t r a s t the C2v point g r o u p w i t h vertical s y m m e t r y to the C2
54
55
a n d C2h point g r o u p s . The D2h point g r o u p h a s a two-fold r o t a t i o n axis, a horizontal m i r r o r , a n d 2 diad r o t a t i o n axes. C o m p a r e also the Cv a n d D3v p o i n t g r o u p s a n d the C3h a n d D3h g r o u p s . Now e x a m i n e the s y m m e t r y e l e m e n t s for the cubic lattice. It is easy to s e e t h a t the n u m b e r
of r o t a t i o n
synmletry elements
is quite high. This is t h e
elements,
plus horizontal
and vertical
r e a s o n w h y the
Cubic
S t r u c t u r e is p l a c e d at the top of 2.2.3. Even t h o u g h the lattice p o i n t s of 2 . 2 . 1 . are deceptively e l e m e n t s are n o t
simple
for the
cubic
structure,
the
symmetry
T h e r e is one o t h e r factor c o n t r i b u t i n g to the overall s y m m e t r i e s of t h e lattice s t r u c t u r e . This factor involves t h e local s y m m e t r y of the a t o m i c g r o u p s w h i c h actually form the s t r u c t u r e . E x a m p l e s are the "solid-state building blocks" given above, e.g.- the t e t r a h e d o n - the group, PO43" a n d the o c t a h e d r o n - like group, NbO6-. It is easy to see t h a t if a s t r u c t u r e is composed
of s u c h building blocks,
t h e y will i m p o s e
s y m m e t r y on the lattice, in addition present. The
result
is t h a t
to the o t h e r
F a c t o r III of 2 . 2 . 6 .
given
a local s t r u c t u r a l
symmetries
already
above i m p o s e s
further
s y m m e t r y r e s t r i c t i o n s on the 32 point g r o u p s a n d we obtain a total of 2 3 1 space groups. We do not i n t e n d to delve f u r t h e r into this a s p e c t of l a t t i c e c o n t r i b u t i o n s to crystal s t r u c t u r e of solids, a n d t h e factors w h i c h c a u s e t h e m to vary in form. It is sufficient to k n o w t h a t t h e y exist. Having covered the e s s e n t i a l p a r t s of lattice s t r u c t u r e , we will e l u c i d a t e how o n e goes about d e t e r m i n i n g the s t r u c t u r e for a given solid. 2-3: HOW TO DETERMINE T H E STRUCTURE OF COMPOUNDS We w a n t to review how one goes about actually d e t e r m i n i n g t h e s t r u c t u r e of a given solid. T h e r e are two factors we n e e d to c o n s i d e r : 1) w h a t are the s t e p s r e q u i r e d in actually d e t e r m i n i n g a s t r u c t u r e ? 2) w h a t k i n d of i n f o r m a t i o n is o b t a i n e d ?
56
Since the c r y s t a l is a p e r i o d i c
a r r a y of a t o m s in w h i c h the i n t e r a t o m i c
d i s t a n c e s a n d i n t e r p l a n a r s p a c i n g s are of t h e s a m e o r d e r of m a g n i t u d e as t h e w a v e l e n g t h s of t h e readily available x-rays, e.g.- t h e K a r a d i a t i o n s , w e can use a target elements.
This
of t h e gives
x-ray tube composed
rise
to
charactersitic
of o n e
of t h e
monochromatic
heavier radiation
d e f i n e d by: 2.3.1.-
Mo = 0 . 7 1 1 fi,- Cu = 1 . 5 4 1 8 ft,- a n d Cr = 2 . 2 9 1 ft,.
A crystal therefore
acts as a t h r e e - d i m e n s i o n a l
diffraction
g r a t i n g for
t h e s e x-rays, a n d t h r e e e q u a t i o n s (the Laue e q u a t i o n s ) m u s t be satisfied if t h e r e is to be c o n s t r u c t i v e i n t e r f e r e n c e of t h e s e m o n o c h r o m a t i c x-rays. T h e Laue e q u a t i o n s to be e m p l o y e d are: 2.3.2.-
a(a-cto ) = h k
b (~-fio) = k k
c (7- ~/o ) = 1 k
w h e r e a, b a n d c are the r e p e a t d i s t a n c e s of t h e lattice, a a n d a o (etc.), are
the
direction
cosines
for
the
diffracted
and
incident
beams
r e s p e c t i v e l y , a n d h, k, a n d 1 are i n t e g e r s defining t h e o r d e r of t h e p a r t i c u l a r diffracted b e a m . k is, obviously, t h e w a v e l e n g t h b e i n g d i f f r a c t e d . It w a s W. L. Bragg w h o s h o w e d t h a t the above e q u a t i o n s are e q u i v a l e n t to t h e c o n d i t i o n for reflection of t h e x - r a y s b y the p l a n e w i t h i n d i c e s h k l , namely: 2.3.3.-
n k
= 2 d sin Ohkl
H e r e , 0 is the angle b e t w e e n plane,
hkl. Also, d is the
the i n c i d e n t
perpendicular
p l a n e s . If we w i s h to d e t e r m i n e
(or reflected) distance
b e a m for t h e
between
successive
t h e exact s t r u c t u r e of a n y given solid, w e
n e e d to follow the following s t e p s : I. Obtain a suitable x - r a y material. 2. D e t e r m i n e
pattern
t h e exact i n t e n s i t i e s
u s i n g a single
crystal of t h e
of the lines or p o i n t s
p a t t e r n by i n t e g r a t i o n of t h e diffracted e n e r g y .
in t h e
57
3. Calculate the values of d, the d i s t a n c e b e t w e e n a d j a c e n t p l a n e s in the crystal lattice by u s i n g the Bragg E q u a t i o n . 4 . D e t e r m i n e t h e s p a c i n g s of the lines in the p a t t e r n , a n d from t h e s e the d i m e n s i o n s of t h e unit-cell. 5. Scale o u r c a l u l a t e d i n t e n s i t i e s to o u r o b s e r v e d i n t e n s i t i e s by: E Ic = E Io a n d calculate a reliability factor, called R, from: R = E (Io - Ic ) /Z Io 6. D e t e r m i n e t h e s t r u c t u r e factor, F ( h k l ) 2 for the p a t t e r n . 7. Refine the s t r u c t u r e factor until it a p p r o a c h e s zero. Nowadays, m o s t of t h e s e s t e p s are done
using a Computer.
e n e r g y diffracted by {hkl} p l a n e s is p r o p o r t i o n a l
The
total
to the s q u a r e of t h e
s t r u c t u r e factor, viz2.3.4.-
E (hkl)
= F (hkl) 2
The s t r u c t u r e factor itself is e x p r e s s e d as the s u m of e n e r g y diffracted, over one unit-cell, of the individual s c a t t e r i n g factors, fl, for a t o m s l o c a t e d at x, y a n d z. Having done this, we c a n t h e n identify t h e exact locations of the
a t o m s (ions) w i t h i n
t h e unit-cell,
its p o i n t - g r o u p
symmetry,
and
crystal s y s t e m . This t h e n c o m p l e t e s o u r p i c t u r e of t h e s t r u c t u r e of t h e material. However, one is usually m o r e i n t e r e s t e d in identifying the n a t u r e of t h e c o m p o u n d by x - r a y analysis a n d does not usually w i s h to identify t h e s t r u c t u r e in detail. To do this, we p r o c e e d as follows. First of all, we s t a r t w i t h La~O3 and/~d203. After fh-ing a 1:11 m i x t u r e of the two, we u s e an xray diffraction i n s t r u m e n t to o b t a i n a series of diffraction lines as d e p i c t e d in t h e following diagram, given as 2.3.5. On the n e x t page. Because of the physical g e o m e t r y of the x - r a y diffraction g o n i o m e t e r ( a n g l e - m e a s u r i n g device), one o b t a i n s values of 20 directly. T h e i n t e n s i t i e s are r e a d from t h e diffraction c h a r t , scaled to the m o s t i n t e n s e
58
2.3.5.-
IA Typical X-ray Diffraction Pattern Obtained From a Diffra~,.tometer]
0
I0
20
30
40 50 :28 Degrees
60
70
80
90 100
line. If we do not k n o w w h a t the n a t u r e of the m a t e r i a l is, t h e n we c a n use the o b t a i n e d p a t t e r n to d e t e r m i n e its p r o b a b l e c o m p o s i t i o n . U s i n g the s e t of diffraction lines, we pick the t h r e e m o s t i n t e n s e l i n e s in t h e p a t t e r n . By r e f e r r i n g
to the
"POWDER DIFFRACTION FILE", p u b l i s h e d
AMERICAN SOCIETY FOR TESTING AND MATERIALS, 1916 Philadelphia,
Penna.
19103,
we
can
look
up
the
most
by t h e
Race St., probable
c o m p o s i t i o n . Usually, we will k n o w how the m a t e r i a l w a s m a d e a n d t h e c o m p o n e n t s u s e d to m a k e it. If not, we c a n analyze for c o n s t i t u e n t s . In this case, we w o u l d find La a n d AI, a n d w o u l d s u r m i z e t h a t we have an oxidic c o m p o u n d , since we m a d e the c o m p o u n d by firing the two o x i d e s together. T h e r e are two c o m p o u n d s possible, n a m e l y - LaA103 a n d ~ 1 1 0 1 8 . (How do we know?.- Consult the v o l u m e s p u b l i s h e d by the A m e r i c a n C e r a m i c Society e n t i t l e d "Phase D i a g r a m s for Ceramicists" for La203 a n d A1203 w h i c h s h o w t h a t only two c o m p o u n d s form w h e n t h e s e two oxides are reacted). In the Diffraction File, the 3 mc~'t i n t ~ m ~ l i n e s of ~ O 3
are d = 2 . 6 6 A
(I00), 3 . 8 0 A (80) a n d 2.19 A (80). w e fred t h a t this set of lines does n o t fit o u r p a t t e r n . We do Find t h a t the p a t t e r n given for L a ~ I I O I 8 is i d e n t i c a l to the
x-ray p a t t e r n
we
obtained.
Thus,
we
have
characterized
our
material. Then, the {h,k,l} values c a n be calculated from special f o r m u l a s developed for this p u r p o s e . T h e s e are given in the following Table 2-3. T h e s e e q u a t i o n s allow us to calculate {h,k,l} values, once we k n o w the d
59
values a n d s t r u c t u r e ,
as c a l c u l a t e d f r o m t h e 20 v a l u e s f o u n d f r o m
the
diffractometer, using the Bragg equation. T a b l e 2- 3 p l a n e S p a c i n g s for v a r i o u s L a t t i c e G e o m e t r i e s
CUBIC
TETRAGONAL
I/d 2 = h 2 + k 2 + 12 / a 2 I / d 2 = h 2 + k 2 / a 2 + 12 / c 2 tIE~_4,GONAL ' ORTI-IORIIOMBIC I / d 2 = 4 / 3 [(h 2 + k 2 + 1 2 ) / a 2] + 1 2 / c 2 I / d 2 = (h 2 / a 2) + ( k 2 / b 2) +(12/c 2) RIIOMBOIiEDRAL iltllll
iiiii
1 / d 2 = ( h 2 + k 2 + 1 2 l s i n 2 a + 2 ( h k + k l + h l ) ( c o s 2 ~ c o s a ) / c x 2 (1- 3 cos 2 a + 2 cos 3 a) MONOCLINIC ............... ,,,
i.,,1
1 / d 2 = { 1 / s i n 2 p}{ h 2 / a 2 + (k 2 s i n 2~) / [ b 2 + 1 2 / c 2 - 2 h l c o s ~ / a c ] TRICLINIC i / d 2 = I / V 2 { S I I h 2 + $22 k 2 + $33 12 + 2 S l 2 h k + 2 $ 2 3 k i + 2 S l 3 h l i
w h e r e : V = v o l u m e of u n i t cell, $22 = a 2 c 2 sin 2 ~,
$33
$23 = a 2 b c (cos ~ c o s y
S ll =
I|l
b 2 c 2 s i n 2(~ , S 2 2 = a 2 c 2
s i n 2 ~,
= a 2 b 2 sin2y, S12 = abc 2 (cos (~ cos ~ - cos y ), -cos
~)and
S13
= ab 2 c ( c o s y c o s ~
For t h e h e x a g o n a l c o m p o s i t i o n given above, i.e.- t h e c o m p o u n d
- cos~)
LaA]llO18
,
t h e {hkl} v a l u e s w e r e o b t a i n e d b y t r y i n g c e r t a i n v a l u e s in t h e h e x a g o n a l f o r m u l a a n d s e e i n g if t h e r e s u l t s give valid n u m b e r s , c o n s i s t a n t w i t h t h e n u m b e r s u s e d . T h a t is, a trial a n d e r r o r m e t h o d w a s u s e d to o b t a i n t h e c o r r e c t r e s u l t s . For e x a m p l e , o n e ,]could s t a r t w i t h {100} a n d d e t e r m i n e w h a t value of d c o n f o r m s to t h i s p l a n e . T h e n , {200} arid {300} w o u l d b e u s e d , etc. If we do this, we o b t a i n t h e v a l u e s s h o w n in T a b l e 2 - 4 as: TABLE 2-4 C o n v e r s i o n of 2 0 V a l u e s of t h e Diffraction 2O I / Io d {hld} 2 0 8.02 16 11.02 002 36.18 16.1 4.81 004 39.39 18.'86 32 4.71 001 40.94 20.12 28 4.41 012 42.79 22.07 10 4.03 45.01 013 24.23 21 3.67 001 53.36 24.55 11 3.63 014 58.57 32.19 44 2.78 I I0 60.07 32.50 15 2.76 008 67.35 33.23 15 2.70 112 71.61 34.02 100 2.64 017 95.42 .
.
.
.
P a t t e r n to {hkl} V a l u e s I / Io d {hkl} 74 2.48 I 14 2.29 023 27 2.20 0010 29 2. i'1 025 66 026 2.61 46 15 1.72 029 36 1.58 127 1.54 60 0211 1.39 48 220 1.32 0214 18 1.04 2214 14 .
.
60
This allows us to d e t e r m i n e the u n i t cell l e n g t h s for o u r c o m p o u n d as: Hexagonal: Additionally, we
ao = 5 . 5 6 . / k -
c a n list the
bo = 2 2 . 0 4 A
x-ray p a r a m e t e r s
and convert
them
to
s t r u c t u r a l factors as shown: T h e s e values are averaged over all of t h e reflections u s e d for calculation. Note t h a t this p a t t e r n h a s several p l a n e s w h e r e the "d" value is m o r e t h a n ten. Let u s c o n s i d e r one o t h e r example. S u p p o s e we o b t a i n e d the following set of 20 v a l u e s a n d intensities for a c o m p o u n d . These are given in the following Table 2-5: TABLE 2- 5
I/Io 96 100 56 50 14 18 14
DIFFRACTION LINES AND INTENSITIES OBTAINED 2 0 in degrees I/Io 2 0 in degrees 29.09 I0 90.55 48.40 17 97.80 48.40 19 118.26 57.48 11 121.00 60.28 7 144.34 78.38 9 148.49 80.78
In looking over the Table, we Fmd t h a t the first t h r e e
values are t h e
s t r o n g e s t diffraction lines. After calculating "d" values a n d looking u p t h e set of s t r o n g lines w h i c h c o r r e s p o n d to o u r set, we find t h a t the p r o b a b l e c o m p o u n d is CdO2, or c a d m i u m peroxide. This c o m p o u n d t u r n s o u t to be cubic in s t r u c t u r e , with ao
= 5.313 A .
W h e n we calculate the {h,k,1}
values of the diffracting planes, the s t r o n g e s t line is f o u n d to be {200}. We c a n t h e n
make
the
determination
that
since
Cd 2+ is a s t r o n g l y
diffracting a t o m (it h a s high atomic weight, w h i c h is one way of s t a t i n g t h a t it h a s m a n y e l e c t r o n
shells, i . e . - l s 2 2s 2 2 p 6 3s 2 3 p 6 3 d l0 4 s 2 4p6
4dlO), the s t r u c t u r e is p r o b a b l y f a c e - c e n t e r e d
cubic. Indeed,
this t u r n s
o u t to be the case. In the u n i t cell, Cd a t o m s are in the special p o s i t i o n s of:
{0,0,0},
{1/2,1/2,1/2};
0,1/2.1/2};
{1/2,1/2,0}.
There
are
four
m o l e c u l e s per u n i t cell. We could c o n t i n u e f u r t h e r so as to calculate intensities, I c , u s i n g atomic s c a t t e r i n g factors already p r e s e n t in p r i o r
61
l i t e r a t u r e . We w o u l d scale o u r c a l u l a t e d i n t e n s i t i e s to o u r o b s e r v e d i n t e n s i t i e s by X Ic = X I o . We t h e n calculate a reliability factor, called R, from R = X (Io - Ic ) /Y Io .
A low value i n d i c a t e s t h a t o u r selection of
lattice p a r a m e t e r w a s correct. K not, we c h o o s e a slightly different value a n d apply it. The details of t h e p r o c e d u r e for d e t e r m i n i n g exact s t r u c t u r e a n d atomic p o s i t i o n s in the lattice are well k n o w n , b u t are b e y o n d t h e scope of this C h a p t e r . 2.4, - SYMMETRY DISTRIBUTION OF CRYSTALS I n o r g a n i c m a t e r i a l s do n o t often p o s s e s s large unit-cells b e c a u s e t h e i r c h e m i c a l f o r m u l a e are m u c h s i m p l e r t h a n organic m o l e c u l e s .
Unit-cell
v o l u m e s for organic c r y s t a l s c a n be as large as 1 0 , 0 0 0 ,~3 a n d p r o t e i n s t e n d to be at least 10 to 100 t i m e s larger t h a n that. Most i n o r g a n i c cell v o l u m e s are in the r a n g e of 1 0 - 1 0 0 0 A 3 b u t SiC c a n have cell v o l u m e s up to 1500 A 3. C e r t a i n v i r u s e s (which are close to p r o t e i n s in c o m p o s i t i o n ) c a n have cell dimensions
u p to 3 6 0 0 A 3 a n d cell v o l u m e s of 46 billion ,Aft. P r o t e i n s
(which are actually p o l y p e p t i d e c h a i n s c o n s i s t i n g of a m i n o acids l i n k e d by p e p t i d e b o n d s ) c a n have m o l e c u l a r w e i g h t s in the millions. T h e h u m a n protein, h e m o g l o b u l i n , side-chains
called
is c o m p o s e d
"alpha"
and
two
of four p o l y p e p t i d e s , differing
side
two i d e n t i c a l
chains
of
similar
c o m p o s i t i o n called "beta". E a c h a l p h a c h a i n h a s 141 a m i n o acids a n d e a c h b e t a c h a i n h a s 146 a m i n o acids, giving a total m o l e c u l a r w e i g h t of about 64,500.
It is one of t h e s i m p l e r biological m o l e c u l e s . W h e n c r y s t a l l i n e
m a t e r i a l s are s u r v e y e d as to tile type of s y m m e t r y t h e y exhibit in the solid state, we find t h a t only t h o s e c o m p o u n d s w i t h s i m p l e c o m p o s i t i o n s have high sylmnekry, i.e.- t h e y crystallize in the cubic form. T h o s e t h a t do not, i n c l u d i n g m o s t organics, t e n d to form c r y s t a l s of low s y m m e t r y as s h o w n in the following table, given on t h e n e x t page. The p e r c e n t a g e s are b a s e d u p o n 5 5 7 2 inorganic, 3 2 1 7 organic a n d 2 2 4 p r o t e i n c o m p o u n d s . T w o - t h i r d s (66%) of the i n o r g a n i c c o m p o u n d s have s y m m e t r i e s h i g h e r t h a n o r t h o r h o m b i c w h e r e a s 85% of t h e o r g a n i c s do not.
62
Table 2-6 Distribution of Crystalline Materials Among the Seven Crystal Systems* System Inorganic Organic Proteins Triclinic 2% 6% 2% Monoclinic 14 49 35 O r t h o r h o m b i c 18 30 43 Trigonal 12 4 6 Tetragonal 14 6 6 Hexagonal 11 2 2 Cubic 30 4 5 * This data was taken from "Crystal Data"- Am. Crystallographic Assoc. Monograph - W. Nowacki- Ed. (1967) For inorganics, the leading space groups are: Fm3m, Pnma, P 6 3 / m m c , Fd3m, P 21/c, Pm3m, C2/c and R3m. Since complicated formulae tend to produce low symmetry, m a n y of the organic crystals appear in the lowest symmetry catagories like monclinic or triclinic. About 80% of inorganic and 60% of organic c o m p o u n d s t r u c t u r e s are centric, that is- they have a center of symmetry. Most protein s t r u c t u r e s are not centric since nearly all living systems, including humans, have a "handedness". The h a n d e d n e s s arises from the replication process in which helices (e.g.- proteins, RNA and DNA) wind and unwind, t h e r e b y t r a n s m i t t i n g genetic code. Helices possess a screw-axis s y m m e t r y so that most crystals of biological origin belong to space groups having s c r e w axes. Among the proteins, the most populous space groups are: P 21 21 21 (34%), P2 i,(23%), C2 (11%), and P 21 21 2 (7%). In biological molecules, inversion symmetry and mirror planes are virtually non-existant. Screw axes are also common among crystals of the simpler organic compounds. But, m a n y of these have mirror and inversion s y m m e t r y as well. The most c o m m o n space groups for organic c o m p o u n d s are: P 21/c (26%), P 21 21 21
(13%), P 21 (8%), and C2/c (7%).
Most of the differences between inorganic, organic and protein crystals lies in the fact that ionic forces (found mostly in inorganic s t r u c t u r e s ) depend upon interatomic distances but not on angle. In contrast, covalent bonds (such as those which p r e d o m i n a t e in organic and p r o t e i n
63
compounds) depend
upon
angle a n d
therefore
the crystal(s) is usually
acentric, i.e.- w i t h o u t a c e n t e r of syrranetry. The h u m a n b o d y is c o m p o s e d
of e u k a r y o t i c cells. S u c h cells have an
a s s o r t m e n t of i n t r a c e l l u l a r m e m b r a n e - b o u n d
organeUes w h i c h carry o u t
the f u n c t i o n s of t h a t p a r t i c u l a r cell. E x a m p l e s rrdght be liver cells vs: b r a i n cells. Every cell in the h u m a n b o d y c o n t a i n s c h r o m o s o m e s . A m o n g the m a n y o r g a n i s m s t h a t have s e p a r a t e sexes, t h e r e are two basic types of c h r o m o s o m e s : a u t o s o m e s a n d sex c h r o m o s o m e s . A u t o s o m e s control t h e i n h e r i t a n c e of all the c h a r a c t e r i s t i c s a n d f u n c t i o n s of the cell except t h e s e x - l i n k e d ones, w h i c h are c o n t r o l l e d by the sex c h r o m o s o m e s . H u m a n s have 22 pairs of a u t o s o m e s a n d one pair of sex c h r o m o s o m e s . living cell to p e r s i s t
from one g e n e r a t i o n
to a n o t h e r ,
For any
it m u s t
store
i n f o r m a t i o n a n d u s e it to p a s s to the next g e n e r a t i o n of cells. AU cells have
solved
this
problem
by
coding
information
in
certain
large
molecules, i.e.- deoxyribonuclecic acid= DNA) a n d ribonucleic acid= RNA. The c o m p o s i t i o n s of DNA a n d RNA have b e e n s h o w n to c o n s i s t solely of the 4 nucleic acids, Adenine (A), T h y m i n e (T), G u a n i n e (G) a n d Cytosine (C). The overall code of the c h r o m o s o m e s is called hhe " h u m a n g e n o m e " . In 1953, Crick a n d W a t s o n solved the s t r u c t u r e of DNA. With the help of Rosalin Franklin, a co-worker, (G+C a n d A+T) f o r m e d
they s h o w e d t h a t p a i r s of nucleic acids
a spiral m o l e c u l e
of high m o l e c u l a r weight in
w h i c h a double s t r a n d was t w i s t e d into a helix. In 1990, w o r k w a s s t a r t e d to c h a r a c t e r i z e the h u m a n g e n o m e w h i c h h a d b e e n s h o w n to c o n s i s t of about 3 billion b a s e pairs. The final r e s u l t was a n n o u n c e d in the year 2000. All of the c h r o m o s o m e s have b e e n c h a r a c t e r i z e d . The h u m a n genorne h a s b e e n s h o w n to c o n t a i n s o m e 3 0 , 0 0 0 g e n e s (which are s e c t i o n s of t h e c h r o m o s o m e w h i c h code for specific proteins). E a c h cell p r o d u c e s the type of p r o t e i n s n e e d e d for it to function. The function of mRNA is to t r a n s f e r i n f o r m a t i o n from t h e DNA, so as is to fix the Emits of the p r o t e i n n e e d e d . The vast m a j o r i t y of the p r o t e i n s f o u n d in living o r g a n i s m s are c o m p o s e d of only- 20 d i f f e r e n t k i n d s of a m i n o acids, r e p e a t e d m a n y t i m e s a n d s t r u n g t o g e t h e r in a p a r t i c u l a r order.
E a c h type of p r o t e i n h a s its o w n u n i q u e s e q u e n c e of
a m i n o acids. This s e q u e n c e ,
k n o w n as its p r i m a r y s t r u c t u r e ,
actually
64
determines
the s h a p e a n d f u n c t i o n of the protein.
The s e c o n d a r y a n d
t e r t i a r y s t r u c t u r e refers to the looping a n d folding of the p r o t e i n c h a i n b a c k u p o n itself.
This
overall
form
determines
the
actual
chemical
function of the individual protein. S o m e p r o t e i n s are e n z y m e s as well.
Although t h e r e are b u t 3 0 , 0 0 0 different g e n e s in the h u m a n body, it has b e e n s h o w n t h a t as m a n y as 2 0 0 , 0 0 0 p r o t e i n s are p r o d u c e d for u s e in t h e individual h u m a n cells. T h u s , it is clear t h a t the d a t a given in T a b l e 2 - 6 m a y be r e g a r d e d as p r e l i m i n a r y . Time will s h o w w h e t h e r the o b s e r v a t i o n s m a d e in Table 2-6 r e g a r d i n g p r o t e i n s t r u c t u r e are c o r r e c t .
2.5.- P h a s e R e l a t i o n s h i p s A m o n g Two .or More Solids
Up to this point, we have c o n s i d e r e d only one solid at a time. H o w e v e r , w h e n two (2) or m o r e solids are p r e s e n t , t h e y can form quite c o m p l i c a t e d s y s t e m s w h i c h d e p e n d u p o n the n a t u r e of e a c h of the solids involved. T o differentiate
a n d to be able to d e t e r m i n e
the differences
between
the
p h a s e s t h a t m a y arise w h e n two c o m p o u n d s are p r e s e n t (or are m a d e to react together), we u s e w h a t are t e r m e d " p h a s e - d i a g r a m s " to illustrate t h e n a t u r e of the i n t e r a c t i o n s b e t w e e n two solid p h a s e c o m p o s i t i o n s . You will note t h a t s o m e of this m a t e r i a l w a s p r e s e n t e d earlier in C h a p t e r 1. It is presented
here
again to f u r t h e r
emphasize
the
importance
of p h a s e
diagrams.
C o n s i d e r the following. S u p p o s e we have two solids, "A" a n d "B". It d o e s not m a t t e r w h a t the exact c o m p o s i t i o n of e a c h m a y be. A will have a specifc m e l t i n g p o i n t (ff it is stable a n d does not d e c o m p o s e at the M.P.) a n d likewise for the c o m p o u n d , B. We f u r t h e r s u p p o s e t h a t the M.P. of B is h i g h e r t h a n t h a t of A. F u r t h e r m o r e , we s u p p o s e t h a t A a n d B form a solid s o l u t i o n at all v a r i a t i o n s of c o m p o s i t i o n . What this m e a n s is t h a t f r o m 100% A-0% B to 50% A-50% B to 0% A-100% B, the two solids dissolve in one a n o t h e r to form a c o m p l e t e l y h o m o g e n o u s single p h a s e . If we p l o t the M.P. of the s y s t e m , we find t h a t t h r e e different c u r v e s could result, as s h o w n in the following diagram, given as 2.5.1. on the next page.
65
In this case, the melting point of the ideal solid solution shoul d i n c r e a s e linearly as the ration of B/A increases. However, it usually does not. E i t h e r a negative deviation or a positive deviation is regularly observed.
In any p h a s e diagram, c o m p o s i t i o n is plotted against t e m p e r a t u r e . In this way, we cart see how the i n t e r a c t i o n s b e t w e e n p h a s e s change as t h e t e m p e r a t u r e changes and the behavior as each solid p h a s e t h e n m e l t s . Either two - p h as e or three p h a s e s y s t e m s can be illustrated. This is s h o w n in the following:
66
Here, the t w o - p h a s e d i a g r a m is simplified to s h o w a h y p o t h e t i c a l p h a s e involving "A" a n d "B" c o m p o u n d s w h i c h form a solid solution from 100% A to 100% B. The solid solution is labelled as "~". The m e l t i n g t e m p e r a t u r e of A is h i g h e r t h a n t h a t of B. T h e r e f o r e , t h e m e l t i n g t e m p e r a t u r e of r d r o p s as the c o m p o s i t i o n b e c o m e s r i c h e r in B. At specific t e m p e r a t u r e s on the d i a g r a m (see 1. & 2.), a t w o - p h a s e s y s t e m a p p e a r s , t h a t of a liquid plus t h a t of r Finally, as the t e m p e r a t u r e r i s e s , the m e l t is h o m o g e n o u s a n d the solid, r
h a s m e l t e d . In the t h r e e - p h a s e
s y s t e m , only the r e l a t i o n s h i p b e t w e e n A, B a n d C c a n be i l l u s t r a t e d on a t w o - d i m e n s i o n a l drawing. A t h r e e - d i m e n s i o n a l d i a g r a m w o u l d be r e q u i r e d to s h o w the effect of t e m p e r a t u r e as well. The p h a s e d i a g r a m s we have s h o w n are b a s e d u p o n the fact t h a t A a n d B form solid m u t u a l l y soluble solid s t a t e solutions. If t h e y do not, i.e.- t h e y are not m u t u a l l y soluble in the
solid
state,
then
the
phase
diagram
b e c o m e s m o r e c o m p l i c a t e d . As an example, c o n s i d e r the following, w h i c h is the c a s e of limited solid solubility b e t w e e n A a n d B:
Here, we have the c a s e w h e r e A & B form two slightly d i f f e r e n t c o m p o n d s , a a n d I~. T h e c o m p o s i t i o n of a is AxBy while t h a t of ~ is AuBv , w h e r e the s u b s c r i p t s i n d i c a t e the ratio of A to B (these n u m b e r s m a y be whole n u m b e r s or t h e y m a y be fractional n u m b e r s ) . At low B
67
c o n c e n t r a t i o n s , a e x i s t s as a solid (the left side of t h e d i a g r a m ) . As t h e t e m p e r a t u r e i n c r e a s e s , a m e l t is o b t a i n e d a n d a r e m a i n s as a solid in t h e m e l t (L) {This is i n d i c a t e d by t h e details given j u s t below t h e s t r a i g h t l i n e in t h e diagram}. As t h e t e m p e r a t u r e is i n c r e a s e d , t h e n ~ m e l t s to form a u n i f o r m liquid.
In t h e
middle
concentrations,
a
and
~ exist
as t w o
s e p a r a t e p h a s e s . At 75% A-25% B, ~ m e l t s to form a liquid p l u s solid c~ w h e r e a s j u s t t h e o p p o s i t e o c c u r s at 25% A a n d 75% B. W h e n A e q u a l s B, t h e n b o t h a a n d ~ m e l t t o g e t h e r to form t h e liquid m e l t , i.e.- t h e " e u t e c t i c point". In two s i m i l a r c a s e s b u t differing c a s e s , i.e.- a s y s t e m w i t h
a
m e l t i n g p o i n t m i n i m u m a n d a n o t h e r w i t h a different type of l i m i t e d solid solubility, the b e h a v i o r differs as s h o w n in t h e following d i a g r a m :
In t h e c a s e on t h e left, a c o m p o s i t i o n exists w h i c h in w h i c h a m i n i m u m m e l t i n g p o i n t exists. Again, A a n d B form a w h i c h partially m e l t s to f o r m + L. However, two forms of a also exist, a c o m p o s i t i o n a l a r e a k n o w n as a "miscibility gap", i.e.- " a l a n d a2". But at h i g h e r t e m p e r a t u r e s ,
b o t h of
t h e s e m e l d into t h e single p h a s e , a. Finally, we o b t a i n t h e m e l t + a. N o t e t h a t at about 80% A-20% B, a m e l t i n g p o i n t m i n i m u m
is s e e n w h e r e
m e l t s d i r e c t l y i n s t e a d of f o r m i n g t h e t w o - p h a s e s y s t e m , a + L.
68
In t h e c a s e of l i m i t e d solid solubility, t h e p h a s e b e h a v i o r b e c o m e s m o r e c o m p l i c a t e d . Here, b o t h r a n d ~ f o r m ( w h e r e t h e a c t u a l c o m p o s i t i o n of is AxBy w h i l e t h a t of ~ is AuBv , as given before. Note t h a t t h e v a l u e s of x a n d y c h a n g e , b u t t h a t we still h a v e t h e a p h a s e . T h e s a m e h o l d s for u a n d v of t h e ~ p h a s e ) . At low A c o n c e n t r a t i o n s ,
r e x i s t s alone w h i l e ~ e x i s t s
alone at h i g h e r B c o n c e n t r a t i o n s .
exists where
system,
+
A region
exists. We n o t e t h a t as t h e t e m p e r a t u r e
t h e two p h a s e
is r a i s e d , a two p h a s e
s y s t e m is also s e e n c o n s i s t i n g of t h e m e l t liquid p h u s a solid p h a s e . T h e p h a s e - b e h a v i o r s h o w n o n t h e r i g h t side of t h e d i a g r a m a r i s e s b e c a u s e t h e two p h a s e s , A a n d B, h a v e l i m i t e d solubility in e a c h o t h e r . Now, let u s c o n s i d e r t h e c a s e w h e r e t h r e e (3) s e p a r a t e p h a s e s a p p e a r in t h e p h a s e d i a g r a m . In t h i s c a s e , w e h a v e t h r e e (3) s e p a r a t e p h a s e s t h a t a p p e a r in t h e p h a s e d i a g r a m . T h e s e p h a s e s are r ~, and o, whose c o m p o s i t i o n s are: r = AxBy, ~ = AuBv a n d ~ = AcBd , r e s p e c t i v e l y ( t h e values of x, y, u, v, c, a n d d all differ f r o m e a c h o t h e r so t h a t AxBy specific c o m p o u n d as a r e t h e o t h e r s ) . T h i s s h o w n as follows:
is a
69
By studing this phase diagram carefully, you can see how the individual phases relate to each other. As you can see, a phase diagram can b e c o m e quite complicated. However, in most cases involving real compounds, t h e phase diagrams are usually simple. Those involving c o m p o u n d s like silicates can be complex, but those involving alloys of metals show simple behavior like limited solubility. Now, let us r e t u r n to a further discussion of the properties of solids. Summarizing to this point, we have shown that only certain propagation units can be stacked to infinity to form c l o s e - p a c k e d solids. We have also shown how the units fit together to form specific solids with specific symmetries. T h e structure of solids has also been reviewed in some detail, including differences in crystal s y m m e t r y of inorganic and organic compounds. WTlat we find is that the solid contains stacking defects. T h a t is, we find that we cannot form the solid without encountering some sort of defect as we stack molecules to near infinity to form our "perfect" solid. Obviously, this arises because of the application of the 2nd Law of T h e r m o d y n a m i c s which involves entropy. The next chapter analyzes t h e defect solid in some detail. SUGGESTED READING 1. "Solids-Elementary Theory for Advanced Students"- G. Weinreich, J. Wiley & Sons, Inc., New York (1965). 2. "Solid State Physics" - A.J. Dekker, Prentice-Hall, Cliffs, NJ (1958). (See Chaps. 1,2 &3 in particular).
Inc., Englewood
3. "Stereographic Projections of the Colored Crystallographic Point Groups", J.A. McMillan, Am. J. Phys., 35, 1049 (1967). 4. "Imperfections in Crystal", J.M. Honig, J. Chem. Ed., 34, 224 (1957). 5. "The Physical Chemistry of Solids", R.J. Borg and G.J. Dienes, Academic Press, NY (1992). 6. "Solid State Chemistry", Prentice-Hall ,N. B. Hannay, Englewood Cliffs, NJ (1967)
70
P r o b l e m s for C h a p t e r 2.. I. R e d r a w the Figure given in 2. I. 15. a n d 2. i. 18 so as d e t e r m i n e the e q u a t i o n for the {420} plane. 2. Define the synm~etry e l e m e n t s for:
C2h
C6v D3h D4 & D2d
3. Given the following "d-spacings" for the diffraction lines of a given cubic powder, calculate the {h,k,l} v a l u e s of the p l a n e spacings. Intensity
2 0 in Degrees
96
29.09
I00
33.70
56
48.4
50
57.48
18
78.38
19
118.26
4. Iron (Fe) h a s the b o d y - c e n t e r e d s t r u c t u r e at 298 ~
a n d a d e n s i t y of
7.86 g m with a lattice s p a c i n g of ao = 2.876 A. Calculate Avogaddro's n u m b e r from these data.
71
Chapter 3
II
Defects in Solids In the first c h a p t e r , we defined the n a t u r e of a solid in t e r m s
of its
building b l o c k s p l u s its s t r u c t u r e a n d s y m m e t r y . In the s e c o n d c h a p t e r , we defined how s t r u c t u r e s of solids are d e t e r m i n e d .
In this c h a p t e r , w e
will e x a m i n e how the solid actually o c c u r s in Nature. C o n s i d e r t h a t a solid is m a d e up of a t o m s or ions t h a t are h e l d t o g e t h e r
by c o v a l e n t / i o n i c
forces. It is axiomatic t h a t a t o m s c a n n o t be pried t o g e t h e r a n d forced to form a periodic s t r u c t u r e w i t h o u t m i s t a k e s b e i n g m a d e . The 2 n d Law of T h e r m o d y n a m i c s d e m a n d s this. S u c h m i s t a k e s seriously affect the overall p r o p e r t i e s of the solid. T h u s , defects in the lattice are p r o b a b l y the m o s t i m p o r t a n t a s p e c t of the solid s t a t e since it is i m p o s s i b l e to avoid d e f e c t s at t h e atomistic level. Two factors are involved: 1) T h e e n t r o p y effect 2) The p r e s e n c e of i m p u r i t i e s in any given solid. W h a t we m e a n by this is t h a t the c h e m i c a l p r o p e r t i e s of the solid are not d e t e r m i n e d solely by its s t r u c t u r e b u t also by the n a t u r e of its c h e m i c a l c o m p o s i t i o n a n d in p a r t i c u l a r b y any d e f e c t s t h a t m a y be p r e s e n t . We will find t h a t b o t h physical a n d c h e m i c a l
properties
of a solid are largely
d e t e r m i n e d by the type a n d n a t u r e of defects p r e s e n t . inorganic
It is axiomatic in
c h e m i s t r y that:
'~rhe p e r f e c t solid d o e s n o t e x i s t in Nature and its reactive p r o p e r t i e s are d e t e r m i n e d , to a great extent, by the d e f e c t s p r e s e n t in its structure". We have a l r e a d y s t a t e d t h a t s o m e defects are r e l a t e d to the entropy of the
solid, a n d t h a t a perfect solid w o u l d violate the s e c o n d law of t h e r m o d y n a m i c s . T h e 2 n d law s t a t e s t h a t zero entropy is only possible at absolute zero t e m p e r a t u r e . However, m o s t solids exist at t e m p e r a t u r e s far
are defect-solids. The defects are usually "point defects", w h i c h are a t o m i s t i c above absolute zero. T h u s , m o s t of the solids t h a t we
encounter
72
defects in the lattice s u c h as a "vacancy" w h e r e the lattice s t r u c t u r e l a c k s an a t o m (ion). E n t r o p y effects are generally a s s o c i a t e d with point defects in the lattice. However,
e n t r o p y c a n form "stacking defects"
due e i t h e r
to "slipped"
p l a n e s in the solid or to t h r e e - d i m e n s i o n a l "faults" t h a t o c c u r r e d in t h e s t a c k i n g p r o c e s s . . How is this possible? You m i g h t c o n s i d e r that, for any given solid, as the t e m p e r a t u r e
rises from absolute zero, m o s t of t h e
e n e r g y g a i n e d goes into v i l m ~ o m ~ l e n e r g y (recall w h a t we said in the first c h a p t e r about the differences b e t w e e n gases, liquids a n d solids in t e r m s of the t h r e e
degrees
of f r e e d o m of a molecule or a s s e m b l y of atoms).
I n c r e a s i n g the e n e r g y in a solid does not r e o r d e r the lattice a n d d e c r e a s e the i n h e r e n t point defects. (See A p p e n d i x III at the e n d of this c h a p t e r ) . For example, an a t o m of a gas h a s t h r e e d e g r e e s of f r e e d o m (the t h r e e spatial c o o r d i n a t e s of the atom) a n d will, therefore, have an average total energy
of 3 / 2 k T .
For an a t o m in a solid,
vibratory m o t i o n
involves
p o t e n t i a l e n e r g y as well as r e s t r i c t e d kinetic energy, a n d b o t h m o d e s will contribute a term
1 / 2 k T , r e s u l t i n g in an average total e n e r g y of 3 k T .
T h u s , it is the e n t r o p y of m i x i n g t h a t forces the c r e a t i o n of a c e r t a i n n u m b e r of v a c a n t lattice p o s i t i o n s above 0.0 ~ natural
result
of t h e r m o d y n a m i c
equilibrium
Hence, v a c a n c i e s are t h e and
not
the
result
of
a c c i d e n t a l g r o w t h or s a m p l e p r e p a r a t i o n . The s e c o n d significant factor arises from the fact t h a t no solid is e v e r 100% pure. It is this lack of p u r i t y w h i c h gives rise to lattice d e f e c t s . C o n s i d e r the fact t h a t
those
inorganic
compounds
which
h i g h e s t p u r i t y k n o w n to date are about 9 9 . 9 9 9 9 9 9 9 9 %
are of t h e
pure. T h a t is, t h e
p u r i t y is about 1 / 1 0 p a r t per billion, i.e.- 1 x 10 -10. But, the c o m p o u n d still c o n t a i n s about 1014 a t o m s per mole, i.e.- per 6 . 0 2 x 1023 a t o m s , i.e.in t e r m s of a t o m s actually p r e s e n t in a m o l e : Impurity = Solid
=
100,000,000,000,000 atoms
= 1.7 x 1 0 lO
602,000,000,000, 000,000,000,000 atoms
Additionally, ff t h e s e i m p u r i t y a t o m s are n o t of the s a m e valence as t h o s e
73
of the h o s t c o m p o u n d , t h e n v a c a n c i e s a n d o t h e r lattice defects will b e present. We will be c o n s i d e r i n g p r i m a r i l y inorganic solids b u t m u s t k e e p in m i n d t h a t t h e s a m e p r i n c i p l e s also apply to organic solids. T h e r e f o r e , we i n t e n d to e x a m i n e the n a t u r e of point defects in t e r m s of t h e i r t h e r m o d y n a m i c s , equilibria a n d the e n e r g y r e q u i r e d for t h e i r formation. It will be s e e n t h a t point
defects
follow the
same
physical c h e m i s t r y
laws t h a t
apply to
inorganic c o m p o u n d s a n d physical p r o p e r t i e s in g e n e r a l . Of necessity, we c a n n o t be exhaustive, a n d t h e r e are m a n y t r e a t i s e s w h i c h deal solely with the t h e r m o d y n a m i c s of the point d e f e c t . 3.1- THE D E F E C T SOLID We have s h o w n t h a t by s t a c k i n g a t o m s or p r o p a g a t i o n u n i t s t o g e t h e r ,
a
solid w i t h specific
a
s y m m e t r y results. If we have done this properly,
perfect solid s h o u l d r e s u l t w i t h no holes or defects in it. Yet, the 2 n d law of t h e r m o d y n a m i c s
demands
that
a certain
number
of point
defects
(vacancies) a p p e a r in the lattice. It is i m p o s s i b l e to o b t a i n a solid w i t h o u t s o m e sort of defects. A p e r f e c t solid w o u l d violate this law. The 2 n d law s t a t e s t h a t z e r o e n t r o p y is only possible at absolute zero t e m p e r a t u r e . Since m o s t solids exist at t e m p e r a t u r e s far from absolute zero, t h o s e t h a t we e n c o u n t e r a r e defect-solids.
It is n a t u r a l to a s k w h a t the n a t u r e of
t h e s e defects m i g h t be. C o n s i d e r the surface of a solid. In the interior, we see a c e r t a i n s y m m e t r y which
depends
u p o n the
surface from t h e interior,
structure
of t h e solid. As we a p p r o a c h
the
the s y n m l e t r y b e g i n s to c h a n g e . At the v e r y
surface, t h e s u r f a c e a t o m s see only half t h e s y m m e t r y t h a t t h e i n t e r i o r a t o m s do (and half of the b o n d i n g as well). R e a c t i o n s b e t w e e n solids t a k e place at the surface. T h u s , the surface of a solid r e p r e s e n t s
a defect in
itself since it is not like the i n t e r i o r of t h e solid. In a t h r e e - d i m e n s i o n a l three
major
types
of
solid, we c a n p o s t u l a t e t h a t t h e r e defects,
having
either
one-,
tvr
o u g h t to b e or
three-
74
dimensions. Indeed,
this is exactly t h e c a s e f o u n d for defects in solids.
Specific n a m e s have b e e n given to e a c h of t h e s e t h r e e t y p e s of d e f e c t s . Thus
a
one-dimensional
dimensional
defect
defect
is
a "line" or "edge"
called
a
defect
"point"
defect,
a
two-
and a three-dimensional
defect is called a "plane" or "volume" d e f e c t . Point
defects
are c h a n g e s
at a t o m i s t i c levels,
while
line
and volume
defects are c h a n g e s in s t a c k i n g of p l a n e s or g r o u p s of a t o m s ( m o l e c u l e s ) in t h e s t r u c t u r e . Note t h a t t h e a r r a n g e m e n t ( s t r u c t u r e ) of t h e individual a t o m s (ions) are not affected, only t h e m e t h o d
in w h i c h t h e s t r u c t u r e
u n i t s are a s s e m b l e d . Let us n o w e x a m i n e e a c h of t h e s e t h r e e
t y p e s of
defects in m o r e detail, s t a r t i n g w i t h t h e o n e - d i m e n s i o n a l lattice d e f e c t a n d t h e n w i t h t h e m u l t i - d i m e n s i o n a l defects. We will f'md t h a t s p e c i f i c t y p e s have b e e n f o u n d to be a s s o c i a t e d w i t h e a c h type of d i m e n s i o n a l defect w h i c h have specific effects u p o n t h e stability of t h e solid s t r u c t u r e . a. The Point Defect in H o m o g e n e o u s Solids Point
defects
determine
were
mentioned
in a prior
chapter.
We n o w
need
to
how t h e y affect t h e s t r u c t u r e a n d c h e m i c a l r e a c t i v i t y of t h e
solid state. We will begin by identifying t h e various defects w h i c h c a n arise in solids a n d later will s h o w h o w t h e y c a n be m a n i p u l a t e d to o b t a i n d e s i r a b l e p r o p e r t i e s n o t found in n a t u r a l l y f o r m e d solids. Since we have a l r e a d y defined solids as e i t h e r h o m o g e n e o u s a n d h e t e r o g e n e o u s , let us look first at the h o m o g e n e o u s type of solid. We will first r e s t r i c t d i s c u s s i o n to solids w h i c h
are s t o i c h i o m e t r i c ,
our
a n d later will e x a m i n e
solids w h i c h c a n be classified as " n o n - s t o i c h i o m e t r i c " , or having an e x c e s s of one or a n o t h e r of one of t h e b u i l d i n g b l o c k s of t h e solid. T h e s e o c c u r in s e m i - c o n d u c t o r s as well as o t h e r t y p e s of e l e c t r o n i c a l l y or optically active solids. Suppose
you
were
given
the
problem
of identifying
defects
in
a
h o m o g e n e o u s solid. Since all of t h e a t o m s in this type of solid are t h e s a m e , t h e p r o b l e m is s o m e w h a t simplified over t h a t of t h e h e t e r o g e n e o u s solid (that is- a solid c o n t a i n i n g m o r e t h a n one type of a t o m or ion). After
75
s o m e i n t r o s p e c t i o n , you could s p e c u l a t e t h a t the h o m o g e n e o u s solid c o u l d have the foUowing t y p e s of p o i n t defects-
3.1.1.- T y p e s of Point Defects E x p e c t e d in a H o m o g e n e o u s Solid
~-
Vacancies
Substitutional Impurities
Self-interstitial
Interstitial I m p u r i t i e s
On the left, in 3. I . i . , are the two types of p o i n t defects w h i c h involve t h e lattice itself, while the o t h e r s involve i m p u r i t y a t o m s . I n d e e d , t h e r e
do
not s e e m to any m o r e t h a n t h e s e four, a n d indubitably, no o t h e r s have b e e n observed. Note t h a t we are limiting o u r defect fan~ly to point d e f e c t s in t h e lattice a n d are i g n o r i n g line a n d v o l u m e defects
of the lattice.
T h e s e four p o i n t defects, given above, are i l l u s t r a t e d in the following diagram, given as 3.1.2. on the n e x t page. Note t h a t w h a t we m e a n by a n "interstial" is an a t o m t h a t c a n fit into t h e s p a c e s b e t w e e n the m a i n a t o m s in the crystalline array. In this case, w e have s h o w n a h e x a g o n a l lattice a n d have labelled e a c h type of p o i n t defect. Note t h a t we have s h o w n a v a c a n c y in o u r h e x a g o n a l lattice, as well as a foreign interstitial a t o m w h i c h is small e n o u g h to fit into the i n t e r s t i c e between
the
atoms
of the
structure.
Also s h o w n
are
two
types
s u b s t i t u t i o n a l a t o m s , one larger a n d the o t h e r s m a l l e r t h a n the
of
atoms
c o m p o s i n g the p r i n c i p a l h e x a g o n a l lattice. In b o t h cases, the h e x a g o n a l p a c k i n g is d i s r u p t e d due to a "non-fit" of t h e s e a t o m s in the s t r u c t u r e . Additionally, we have i l l u s t r a t e d a n o t h e r type of defect
t h a t c a n arise
w i t h i n t h e h o m o g e n e o u s lattice of 3.1.2. (in addition to the v a c a n c y a n d s u b s t i t u t i o n a l i m p u r i t i e s t h a t are b o u n d to arise). This is called the "selfinterstitial". defect.
Note t h a t it h a s a decisive effect on the
Since
the
atoms
are
all the
same
size,
the
structure
at t h e
self-interstitial
i n t r o d u c e s a l i n e - d e f e c t in the overall s t r u c t u r e . It s h o u l d be evident t h a t t h e line-defect i n t r o d u c e s a difference in p a c k i n g o r d e r since the c l o s e p a c k i n g a t t h e a r r o w s h a s c h a n g e d to cubic a n d t h e n r e v e r t s to h e x a g o n a l in b o t h lower a n d u p p e r rows of a t o m s .
76
It m a y be t h a t this type of defect is a m a j o r c a u s e of the line or edge t y p e of defects t h a t a p p e a r in m o s t h o m o g e n e o u s solids. In c o n t r a s t , the o t h e r defects p r o d u c e only a d i s r u p t i o n in the localized p a c k i n g o r d e r of t h e h e x a g o n a l lattice, i.e.- the defect does not e x t e n d t h r o u g h o u t the lattice, b u t only close to the specific defect. Now, s u p p o s e t h a t we have a solid solution of two (2) e l e m e n t a l
solids.
Would the point defects be the same, or not? An easy way to visualize s u c h point defects is s h o w n in the following diagram, given as 3.1.3. on t h e next page. It is well to note h e r e t h a t h o m o g e n e o u s lattices usually involve m e t a l s or solid s o l u t i o n s of m e t a l s (alloys) in c o n t r a s t to h e t e r o g e n e o u s lattices w h i c h involve c o m p o u n d s s u c h as ZnS.
77
Here, we u s e a h e x a g o n a l l y - p a c k e d r e p r e s e n t a t i o n of a t o m s to d e p i c t t h e close-packed
solid.
In
this
case,
we
have
shown
h o m o g e n e o u s solids. T h a t is, o n e solid is c o m p o s e d
both
types
of
of t h e s a m e s i z e d
a t o m s w h i l e t h e o t h e r is c o m p o s e d of two d i f f e r e n t sized a t o m s . On t h e r i g h t a r e t h e t y p e s of p o i n t d e f e c t s t h a t c o u l d o c c u r for t h e s a m e sized a t o m s in t h e lattice. T h a t is, given a n a r r a y of a t o m s in a t h r e e d i m e n s i o n a l lattice, only t h e s e
two t y p e s of l a t t i c e p o i n t d e f e c t s
could
o c c u r w h e r e t h e size of t h e a t o m s are t h e s a m e . T h e t e r m " v a c a n c y " is self-explanatory but "self-interstitial" means into a s p a c e b e t w e e n
that one atom has slipped
t h e r o w s of a t o m s (ions).
In a l a t t i c e w h e r e
the
a t o m s a r e all of t h e s a m e size, s u c h b e h a v i o r is e n e r g e t i c a l l y v e r y difficult u n l e s s a s e v e r e d i s r u p t i o n of t h e l a t t i c e o c c u r s (usually a " l i n e - d e f e c t " r e s u l t s . T h i s b e h a v i o r is q u i t e c o m m o n solids.
In
a like
manner,
if t h e
in c e r t a i n t y p e s of h o m o g e n e o u s
metal-atom
were
to
have
become
m i s p l a c e d in t h e l a t t i c e a n d w e r e to h a v e o c c u p i e d o n e of t h e i n t e r s t i t i a l
78
positions, as s h o w n in the different sized a t o m solid, t h e n the lattice is d i s r u p t e d by its p r e s e n c e at the interstitial position. This type of d e f e c t has b e e n o b s e r v e d . S u m m a r i z i n g , t h r e e types of p o i n t defects are evident in a h o m o g e n e o u s lattice. In addition to the Vacancy, two types of s u b s t i t u t i o n a l defects can also be
delineated.
Both are
direct
s u b s t i t u t i o n s in the
"lattice",
or
a r r a n g e m e n t of the atoms. One is a smaller atom, while the o t h e r is l a r g e r than
the
atoms
comprising
the
lattice.
In
both
cases,
the
lattice
a r r a n g e m e n t affects the h e x a g o n a l o r d e r i n g of the lattice a t o m s a r o u n d it. The lattice is s e e n to be affected for m a n y lattice d i s t a n c e s . It is for this r e a s o n t h a t c o m p o u n d s c o n t a i n i n g i m p u r i t i e s s o m e t i m e s have quite different c h e m i c a l reactivities t h a n the p u r e s t ones. T h a t also h a s an effect u p o n the c h e m i c a l reactivity of the solid. However, the i n t e r s t i t i a l i m p u r i t y does not affect the lattice o r d e r i n g at all. Now, let us look at a n o t h e r type of defect in the solid. Let u s c o n s i d e r the h e t e r o g e n e o u s lattice b. The Point Defect in H e t e r o g e n e o u s Solids The situation c o n c e r n i n g
defects
in h e t e r o g e n e o u s
inorganic
solids is
similar to t h a t given above, except for one very i m p o r t a n t factor, t h a t of c h a r g e on the atoms. Covalent inorganic solids are a rarity while ionicity or partial ionicity s e e m s to be the n o r m . T h u s , h e t e r o g e n e o u s solids are usually c o m p o s e d of c h a r g e d moieties, half of w h i c h are positive (cations) a n d half negative (anions). In general, the total c h a r g e of the c a t i o n s will equal t h a t of the a n i o n s (Even in the case of s e m i - c o n d u c t o r s , w h e r e t h e total of the c h a r g e s is not zero, the excess c h a r g e (n- or p- type) is s p r e a d over the whole lattice so t h a t no single atom, or g r o u p of atoms, ever h a s a c h a r g e different from its neighbors).
In a given s t r u c t u r e ,
usually s u r r o u n d e d by anions, a n d vice-versa.
c a t i o n s are
Because of this, we can
r e g a r d the lattice as b e i n g c o m p o s e d of a cation s u b . l a t t i c e a n d an Rnlon mfl~lattice. ( R e m e m b e r w h a t w a s s t a t e d in C h a p t e r 1 c o n c e r n i n g the fact t h a t m o s t s t r u c t u r e s are o x y g e n - d o m i n a t e d ) . What we m e a n by a "sublattice" is i l l u s t r a t e d in the following diagram:
79
In this case, we have s h o w n b o t h the
cation
and
anion "sub-lattices
separately, a n d t h e n the c o m b i n a t i o n . It s h o u l d be clear t h a t all positive c h a r g e s in the cation sub-lattice will be b a l a n c e d by a like n u m b e r of negative c h a r g e s in the a n i o n sub-lattice, even if excess c h a r g e exists in one or the o t h e r of the sub-lattices. However, if an a t o m is m i s s i n g , t h e overall lattice r e a d j u s t s to c o m p e n s a t e for this loss of charge. If t h e r e is a different
atom
compensation
present,
having
a
differing
charge,
the
charge-
m e c h a n i s m again m a n i f e s t s itself. T h u s , a cation with an
extra c h a r g e n e e d s to be c o m p e n s a t e d by a like anion, or by a n e a r e s t n e i g h b o r cation w i t h a lesser charge. An e x a m p l e of this type of c h a r g e c o m p e n s a t i o n m e c h a n i s m for a divalent cation sub-lattice w o u l d be t h e following defect e q u a t i o n : : 3.1.5.-
2 C a 2+ ~
Li +
+
Sb3+
w h e r e the Sb 3+ a n d Li+ are s i t u a t e d on n e a r e s t n e i g h b o r cation sub-lattice sites, in the divalent Ca 2+ sub-lattice. Note t h a t a total c h a r g e of 4+ e x i s t s on b o t h sides of the above e q u a t i o n .
Thus, the charge compensation mechanism represents the single most important m e c h ~ n i ~ n which operates within the defect ionic solid.
80
We find t h a t the n u m b e r a n d t y p e s of defects, w h i c h c a n a p p e a r in t h e h e t e r o g e n e o u s solid, are limited b e c a u s e of two factors: 1) The c h a r g e - c o m p e n s a t i o n factor 2) The p r e s e n c e of two s u b - l a t t i c e s in the ionic solid. These
factors r e s t r i c t
the n u m b e r of p o i n t
defect
t y p e s we
need
to
c o n s i d e r in ionic h e t e r o g e n e o u s lattices (having b o t h c a t i o n s a n d anions p r e s e n t ) . For ionic solids, the following t y p e s of defects have b e e n f o u n d to existS c h o t t k y defects (absence of b o t h cation a n d anion) Cation or a n i o n v a c a n c i e s F r e n k e l defects (Cation vacancy p l u s s a m e cation as interstitial) Interstitial i m p u r i t y a t o m s (both cation a n d anion) S u b s t i t u t i o n a l i m p u r i t y a t o m s ( b o t h cation a n d anion) T h e s e defects are i l l u s t r a t e d in the following diagram, given as 3.1.6. on the next page. Note that, in general, a n i o n s are larger in size t h a n cations due to t h e extra e l e c t r o n s p r e s e n t in the former. A h e x a g o n a l lattice is s h o w n in 3.1.6. w i t h b o t h F r e n k e l a n d S c h o t t k y defects, as well as s u b s t i t u t i o n a l defects. T h u s , if a cation is m i s s i n g (cation vacancy) in the cation sublattice, a like anion will be m i s s i n g in the a n i o n sub-lattice. This is k n o w n as a S c h o t t k y defect (after the first investigator to note its e x i s t e n c e ) . In the case of the F r e n k e l defect, the
"square" r e p r e s e n t s
cation w a s s u p p o s e d to reside
lattice
in the
before
where
it m o v e d
the
to its
interstitial position in the cation sub-lattice. Additionally, "Anti-Frenkel" defects c a n exist in the anion sub-lattice. The s u b s t i t u t i o n a l defects are s h o w n as the s a m e size as the cation or anion it displaced. Note t h a t if t h e y were not, the lattice s t r u c t u r e w o u l d be d i s r u p t e d from r e g u l a r i t y at the p o i n t s of i n s e r t i o n of the foreign ion.
81
All of t h e s e point defects are i n t r i n s i c arise due to t h e p r e s e n c e
to t h e h e t e r o g e n e o u s
solid, a n d
of b o t h cation a n d a n i o n sub-lattices. T h e
factors r e s p o n s i b l e for t h e i r f o r m a t i o n are e n t r o p y effects ( s t a c k i n g faults) a n d i m p u r i t y effects. At t h e p r e s e n t
time, the h i g h e s t - p u r i t y m a t e r i a l s
available still c o n t a i n about 0.1 p a r t p e r billion of various i m p u r i t i e s , y e t are 9 9 . 9 9 9 9 9 9 9
% pure.
i m p u r i t y a t o m s p e r mole.
Such
a solid will still c o n t a i n
about
So it is safe to say t h a t all solids
1014
contain
i m p u r i t y a t o m s , a n d t h a t it is unlikely t h a t we shall ever be able to obtain a solid w h i c h is c o m p l e t e l y pure and d o e s n o t contAln d e f e c t s .
82
c. The Line Defect In a t h r e e - d i m e n s i o n a l lattice, we have o b s e r v e d p l a n e s of a t o m s (or ions) c o m p o s i n g the lattice. Up to now, we have a s s u m e d t h a t t h e s e p l a n e s m a i n t a i n a c e r t a i n relation to one a n o t h e r . T h a t is, we have s h o w n t h a t t h e r e are a set of p l a n e s as defined by the {hkl} values, w h i c h in t u r n d e p e n d s u p o n the type of Bravais lattice t h a t is p r e s e n t . However, we find t h a t it is possible for t h e s e rows of atoms to "slip" from their e q u i l i b r i u m positions. This gives rise to a n o t h e r type of lattice defect defects".
In the following diagram, we p r e s e n t
called "line
a h e x a g o n a l lattice
w h i c h a line defect is p r e s e n t :
Here, rows of a t o m s c o m p r i s i n g a h e x a g o n a l lattice are shown. The first
in
83
four layers are c o m p o s e d However,
of c l o s e - p a c k e d
at t h e p o i n t s h o w n w h e r e
h e x a g o n a l layers of a t o m s .
the line-defect
axes c r o s s in t h e
d i a g r a m , a row of a t o m s is rrdssing. This h a s c h a n g e d t h e p a c k i n g of t h e two a t o m layers c l o s e s t to t h e m i s s i n g row of a t o m s to t h a t of cubic closep a c k i n g . It is t h i s l a c k of c o n t i n u i t y w h i c h c a u s e s t h e Hne defect b e c a u s e one layer h a s s l i p p e d from its e q u i l i b r i u m position. While it rrdght n o t s e e m t h a t this s i t u a t i o n is serious, it c a u s e s a s t r a i n to a p p e a r in t h e lattice s t r u c t u r e in w h i c h a c o m p r e s s i o n is p r e s e n t on one side of t h e l i n e defect a n d a s t r a i n on t h e o t h e r . A r e p r e s e n t a t i o n of this is s h o w n in t h e following d i a g r a m :
Note t h a t a row of a t o m s is m i s s i n g . This h a s t h e effect of i n t r o d u c i n g a tension
on
the
lattice
since
the
underneath
rows
c o m p e n s a t e for t h e lack of t h e one row. T h e r e f o r e , the upper
of a t o m s
have to
a t e n s i o n is p l a c e d on
rows of a t o m s b e c a u s e of t h e m a n d a t e d
change
in l a t t i c e
s p a c i n g s in t h e lower rows, w h e r e a c o m p r e s s i v e force is p r e s e n t .
84
There
have b e e n several c a s e s w h e r e
observe
line
imperfections
it h a s b e e n possible to d i r e c t l y
by suitable
e x a m i n a t i o n of the surface in reflected
preparation
and
microscopic
light. One e x a m p l e is the MgO
crystal. MgO is a cubic crystal a n d it is possible to e t c h it along t h e { 100} direction
(this is the d i r e c t i o n along the x-axis). W h a t is o b s e r v e d is a
series of surface lines of specific length. The r e a s o n t h a t t h e s e d e f e c t lines s h o w u p is t h a t t h e y are m o r e d i r e c t i o n of the edge dislocation.
easily e t c h e d
by acid along t h e
Note t h a t in its s i m p l e s t form, an e d g e
dislocation is an o m i s s i o n of a line of a t o m s c o m p o s i n g the lattice. T h e a r e a w i t h i n the lattice a r o u n d the line defect is u n d e r b o t h c o m p r e s s i o n a n d t e n s i o n due to the difference in a t o m - d e n s i t y as one p a s s e s t h r o u g h it in a d i r e c t i o n p e r p e n d i c u l a r to the line defect. A n o t h e r view of the s a m e type of defect is s h o w n in the following d i a g r a m :
Here, the axis of slip is s h o w n in the h e x a g o n a l lattice as being on, or n e a r the surface of the a r r a y of a t o m s . In the cubic lattice, a slip p l a n e is d e p i c t e d w h e r e a line of a t o m s is m i s s i n g a n d the lattice h a s m o v e d to a c c o m m o d a t e this type of lattice d e f e c t . It s h o u l d be clear t h a t the p r e s e n c e of line defects in a crystal l a t t i c e leads to a d i s r u p t i o n of the c o n t i n u i t y of the lattice j u s t as the p r e s e n c e of point
defects
affects the p a c k i n g of a given lattice.
The
line
defect,
85
however, is a physical c h a n g e in t h e lattice w h e r e a s t h e p o i n t defect can be classified as a chernical change. T h a t is, the p o i n t c h a n g e in the electronic
defect
causes a
s t r u c t u r a l a r r a n g e m a n t of the a t o m s while t h e
line defect h a s no effect on the electronic p r o p e r t i e s . d. The Volume Defect The
in
two
d i m e n s i o n s . Let u s s u p p o s e t h a t a line defect h a s a p p e a r e d while
volume
defect
is s o m e w h a t
more
difficult
to
visualize
the
crystal s t r u c t u r e w a s forming. This w o u l d be a s i t u a t i o n similar to t h a t already s h o w n in 3.1.3. w h e r e a line defect w a s s h o w n . The c o m p r e s s i o n t e n s i o n a r e a of the defect h a s a definitive effect u p o n the growing crystal a n d c a u s e s it to d e f o r m a r o u n d the line defect. This is s h o w n in t h e following d i a g r a m :
In one case, we have s h o w n a b l o c k r e p r e s e n t a t i o n of the g r o w t h p a t t e r n of the crystal a n d in the o t h e r an a t o m i s t i c r e p r e s e n t a t i o n . What h a p p e n s is t h a t a series of "steps" a p p e a r a r o u n d t h e line defect a n d the crystal b e g i n s to a s s u m e a spiral g r o w t h p a t t e r n . T h a t is, the p o i n t s s h o w n as "a", b e i n g at least one a t o m u n i t h i g h e r in the crystal, begin to grow over t h e a t o m u n i t s at "o". This r e s u l t s in a g r o w t h s i t u a t i o n similar to t h a t s h o w n
86
in the following d i a g r a m . Here, the spiral p a t t e r n of g r o w t h is e v i d e n t , a n d p r o c e e d s from the line defect dislocation. Both a top view a n d a side view are given. This type of crystal g r o w t h arises from the p o i n t of t h e line defect w h i c h h a s i n t r o d u c e d the c o m p r e s s i o n - t e n s i o n factor into t h e growing lattice.
This type of v o l u m e defect in the crystal is k n o w n as a "screw dislocation", so-called b e c a u s e of its t o p o g r a p h y . Note t h a t the spiral dislocation of t h e growing lattice d e p o s i t s a r o u n d the line defect at fight angles to the line defect. In the following diagram, given as 3.1.12.
on the n e x t page, a n o t h e r
r e p r e s e n t a t i o n is shown, detailing how the dislocation line (line d e f e c t ) becomes a screw-dislocation. Note t h a t "b" in this d i a g r a m is the s a m e as t h a t in 3.1.8. B e c a u s e e d g e a n d v o l u m e defects
propagate
throughout
the
lattice,
t h e y affect t h e
physical p r o p e r t i e s of the solid, w h e r e a s it is the point defects t h a t affect the c h e m i c a l
properties
of the
solid. T h e s e
latter p r o p e r t i e s
electrical a n d resistive, optical a n d reactivity p r o p e r t i e s we c a n n o w classify d e f e c t s in solids
as:
EXTRINSIC - Edge & Volume (physical) INTRINSIC - Point ( c h e m i c a l )
include
of solids. T h u s ,
87 84
It is the i n t r i n s i c defects t h a t have t h e m o s t i n t e r e s t for us, since t h e y affect
the
havelittle
chemical effect.
properties
Extrinsic
of the
defects
are
solid
while
the
proper
extrinsic study
defects
for
those
i n t e r e s t e d in the m e c h a n i c s of solids, p a r t i c u l a r l y m e t a l s . A b r o a d variety of c o m m e r c i a l p r o d u c t s are b a s e d u p o n c o n t r o l l e d p o i n t defects.
These
color-television,
include
transistors,
integrated
circuits,
photosensors,
f l u o r e s c e n t l a m p s , j u s t to n a m e a few. None of t h e s e
w o u l d be possible
without
control
of point
defects.
As a n
example,
c o n s i d e r single crystal silicon. A boule is g r o w n about 2 0 0 to 3 0 0 ram. in d i a m e t e r (8 to 12 inches). T h e s e weigh about 2 0 0 Ibs before t h e y are sliced into fiat discs. The native defects in silicon g r o w n from the m e l t are v a c a n c i e s a n d interstials, i m p u r i t i e s a n d oxygen e n t e r i n g the c r y s t a l from the g r o w t h c o n d i c t i o n s
(from the SiO2 crucible u s e d to hold t h e
liquid m a s s a n d from t h e a h m o s p h e r e [here, the i n e r t gas u s e d to b l a n k e t the
growth
chamber
does
not
eliminate
all of t h e
surface-adsorbed
g a s e o u s molecules]). Si v a c a n c i e s a n d i n t e r s t i t u a l s t e n d to a g g l o m e r a t e to form "surface "pits" w h i c h i n t e r f e r e w i t h t h e f o r m a t i o n of the i n t e g r a t e d circuits on the surface of t h e silicon disc as t h e y are b e i n g m a n u f a c t u r e d .
88
J u s t recently, it w a s a n n o u n c e d t h a t crystal g r o w t h c o n d i t i o n s could be modified so t h a t v a c a n c i e s could be n e a r l y e l i m i n a t e d in the final c r y s t a l lattice. This i n c l u d e d oxygen a t o m s w h i c h were s u b s t i t u t e d as 0 - - i n t h e lattice a n d c a u s e s t a c k i n g faults (Note t h a t p a r t of t h e oxygen is usually lost as volatile SiO). This m i g h t n o t s e e m i m p o r t a n t until one realizes t h a t c o n d u c t i v e line w i d t h s on the silicon surface have b e e n n a r r o w i n g o v e r the y e a r s from 0 . 3 5 ~ n in 1995 to 0.13 ~ in 2002. Since the average atomic size is of the o r d e r of a n g s t r o m s , i.e.- 10 s c m or 0.01 ~rn, it predicted
t h a t line w i d t h s of i n t e g r a t e d circuits will r e a c h 0.07 ~rrt in
2 0 1 0 or t h a t of the individual a t o m s . Additionally, iron as Fe "~, one of t h e m o s t i n s i d i o u s of i m p u r i t i e s
in single
crystal silicon
(Si~),
has been
c o n t r o l l e d to < 1 0 i~ a t o m s per c m "~ Since silicon c o n t a i n s r o u g h l y 5 x 10 ~ a t o m s per c m a, this c o r r e s p o n d s to a p u r i t y of 2 x 1 0 i~ or 2 p a r t s p e r million-million (2 p a r t s per quadrillion). T h u s , control of intrinsic d e f e c t s is one of the m o s t i m p o r t a n t of the factors c o n t r i b u t i n g to the p r o p e r operation
of i n t e g r a t e d
circuits
devices
(computers,
and
all d e v i c e s
c o n t a i n i n g electronic circuits). 3.2.- Math.ematics a n d E q u a t i o n s of the Point Defect A c o n s i d e r a b l e b o d y of scientific w o r k h a s b e e n a c c o m p l i s h e d in the p a s t to define
and characterize
point
defects.
One
major
reason
is
that
s o m e t i m e s , the e n e r g y of a p o i n t defect c a n be calculated. In o t h e r s , t h e c h a r g e - c o m p e n s a t i o n w i t h i n the solid b e c o m e s a p p a r e n t . In m a n y cases, if one deliberately a d d s an i m p u r i t y to a c o m p o u n d to modify its p h y s i c a l p r o p e r t i e s , the c h a r g e - c o m p e n s a t i o n , intrinsic to the defect formed, can be p r e d i c t e d .
We are now r e a d y to d e s c r i b e
t h e s e defects in t e r m s of
their e n e r g y a n d to p r e s e n t e q u a t i o n s d e s c r i b i n g their equilibria. One way to do this is to u s e a "Plane-Net".
This is simply a t w o - d i m e n s i o n a l
r e p r e s e n t a t i o n w h i c h u s e s s y m b o l s to replace the s p h e r i c a l i m a g e s t h a t we u s e d above to r e p r e s e n t the a t o m s (ions) in the s t r u c t u r e . 8, THE PLANE N E T To begin, let us call the cation "M" a n d the anion "X". Although t h e y will be c h a r g e d in the h e t e r o g e n e o u s lattice, let u s ignore c h a r g e
for t h e
89
m o m e n t (or we c a n imagine t h a t e a c h h a s a single c h a r g e as in the NaCI lattice, i.e.- M + a n d X-). If we a r r a n g e b o t h the M cation a n d the X anion in a cubic array, we w o u l d have the foUowing r e p r e s e n t a t i o n of a s t r u c t u r e . This, we call a " p l a n e net". 3.2.1.-
[ A RepresentatiOn of a Plane N e t ]
ITypeso.f,,Defects]Mx M X M X
MX MXMXMX
ix M X M X M XM• X M X MXMXMX
.....
XMXMXM MXMXMX XMXMXM MXMXMX XMXMXM M MXMX MXMXMX XMXMXM XMXMXMXM MXMXMX MXMXMX XMX MXMX1VI XMXMXM XMX MXMXMXMXMXM [X-]IVIX M X M X M X M X M X M XMX MXMXMXMXMXM
XMXM MXMXMXMX [~~--~X M F]M X M X M MXMXMXMX
x
~
xMx M
It is also easy to see t h a t we c a n s t a c k a series of t h e s e "NETS" three-dimensional
solid. We c a n also s u p p o s e
t h a t the
to form a
same
type of
defects will arise in o u r Plane Net as in e i t h e r the h o m o g e n e o u s o r h e t e r o g e n e o u s solid a n d so p r o c e e d to label s u c h defects as M i , m e a n i n g an i n t ~ t i t i a l
cation. In the s a m e way, we label a c a t i o n v a c a n c y as VM,
a n d Xi is the i n t e r s t i t i a l anion, a n d Vx is t h e s y m b o l for the a n i o n vacancy. Also s h o w n are t h e symbols, Ms a n d Ks, w h i c h d e n o t e t h e s u r f a c e sites of the cubic s t r u c t u r e of the Plane Net. If we are dealing w i t h
an ionic
s t r u c t u r e , we w o u l d also e x p e c t to have defects w h i c h are c h a r g e d s i n c e the i n c o r p o r a t i o n of e i t h e r c a t i o n s or a n i o n s ha-ring differing c h a r g e s as
substitutional ions into either of the sub-lattices is to be expected (See 3.1.3. given above). Additionally, b o t h surface sites a n d i n t e r n a l ions can have c h a r g e s differing f r o m the m a j o r i t y of the c a t i o n s or anions.
90
T h e s e , t h e n , are t h e s e t of p o s s i b l e d e f e c t s for t h e P l a n e Net, following s u m m a r i z e s t h e t y p e s of i n t r i n s i c d e f e c t s e x p e c t e d . we h a v e u s e d t h e labelling: V = v a c a n c y ;
and the Note t h a t
i = i n t e r s t i t i a l ; M -- c a t i o n site;
X = a n i o n site a n d s = s u r f a c e site. We h a v e a l r e a d y s t a t e d t h a t s u r f a c e s i t e s are special.
Hence,
t h e y are i n c l u d e d
in o u r l i s t i n g of i n t r i n s i c
defects. 3.2.2-
CHARGED PARTICLES
VACANCIES
e- ,
V M , VX, V + M , V - x
SURFACE S I T E S
INTERSTITIAL SITI~S Mi,
Xi , M + i ,
X'i
/1;+
Ms, Xs, M+s, X's
Two i t e m s of i n t e r e s t c a n be n o t e d I) We c a n h a v e p u r e v a c a n c i e s in t h e l a t t i c e 2} T h e s e v a c a n c i e s c a n b e c h a r g e d . T h e s a m e c a n be s a i d for i n t e r s t i t i a l s i t e s a n d s u r f a c e s i t e s as well. W h a t t h i s m e a n s is t h a t t h e p o i n t d e f e c t c a n a c q u i r e a c h a r g e . For e x a m p l e , let u s c o n s i d e r a c a t i o n v a c a n c y in ZnS. T h e v a c a n c y c a n b e r e p r e s e n t e d a s : V z n 2 + . However, w i t h a V z n 2 + p r e s e n t , a l a c k of c h a r g e of 2+ e x i s t s in t h e lattice. T h i s deficit of c h a r g e m u s t b e c o m p e n s a t e d in t h e l a t t i c e b y a like a m o u n t of n e g a t i v e c h a r g e s u c h as a Vs2- . However, w e h a v e a l r e a d y s t a t e d t h a t t h e Vzn2+ p o i n t d e f e c t c a n also a c q u i r e a c h a r g e s u c h as V + z n 2 + . In t h i s c a s e we h a v e a total deficit Obviously, t h e p r e s e n c e
in c h a r g e
of 3+.
of t h e a n i o n v a c a n c y , Vs2- , is n o t sufficient to
m a i n t a i n c h a r g e c o m p e n s a t i o n in t h e lattice. T h e r e f o r e
some other mode
of c h a r g e c o m p e n s a t i o n is r e q u i r e d . O n e p o s s i b i l i t y is, of c o u r s e , t h e c h a r g e d a n i o n v a c a n c y , V-s2_ . T h e r e a r e o t h e r s as well. T h e c h a r g i n g of s u r f a c e s i t e s a n d i n t e r s t i t i a l s is n o t as c l e a r as t h a t of v a c a n c i e s , a n d w e will n o t dwell o n t h e m f u r t h e r at t h i s p o i n t . One m i g h t t h i n k t h a t p e r h a p s V M a n d V+• o u g h t to b e i n c l u d e d in o u r list of
vacancies.
However,
a
negatively-charged
cation
vacancy
alone,
p a r t i c u l a r l y w h e n it is s u r r o u n d e d b y n e g a t i v e a n i o n s , w o u l d n o t b e v e r y
91
stable. N e i t h e r
should a positively-charged
anion v a c a n c y be any m o r e
stable. E i t h e r a r r a n g e m e n t w o u l d r e q u i r e high e n e r g y stabilization to exist. T h e r e f o r e , we do not i n c l u d e t h e m in o u r listing. However, a VM could c a p t u r e a positive c h a r g e to b e c o m e V+M a n d likewise for the Vx which
then becomes
a V-x.
Both of t h e s e
o u g h t to be stable w h e n
s u r r o u n d e d by the o p p o s i t e l y c h a r g e d sites of the o t h e r sub-lattice ( a n d i n d e e d t h e y are as w e have i n d i c a t e d above). One s h o u l d note t h a t w h e n a c h a r g e d - i n t e r s t i t i a l is p r e s e n t in one sublattice, the o t h e r sub-lattice will c o n t a i n e i t h e r a l i k e - c h a r g e d i n t e r s t i t i a l or a l i k e - c h a r g e d s u b s t i t u t i o n a l ion w h i c h exactly b a l a n c e s t h e total c h a r g e p r e s e n t in the lattice. S u c h e q u a t i o n s m i g h t i n c l u d e one or b o t h of t h e following e q u a t i o n s : 3.2.3.-
[ M i 3+]Mi + ~ [Xi 3"]Xi" [ Mi 3+]Mi + ~
X3-x"
The first e q u a t i o n d e s c r i b e s the e q u i l i b r i u m b e t w e e n two i n t e r s t i t i a l s i t e s with e x c e s s charge, one on e a c h sub-lattice, while the o t h e r shows
the
equilibria b e t w e e n
the
interstitial
cation
equation
a n d t h a t of t h e
s u b s t i t u t i o n a l anion, b o t h h a v i n g a like e x c e s s charge. Obviously, various c h a r g e - c o m p e n s a t i n g c o m b i n a t i o n s of all of the 6 basic lattice defects a r e possible, i.e.- the VM ,Vx ,Mi, X4, Ms , a n d Xs d e f e c t s , as well as b e t w e e n the s u b s t i t u t i o n a l c a t i o n s or a n i o n s h a v i n g a c h a r g e differing from t h o s e c o m p r i s i n g the lattice. The n u m b e r of c o m b i n a t i o n s is thus: C = 6!/(6-2)! , or C = 3 0 Additionally, we c a n have at l e a s t four (4) t y p e s of c h a r g e d v a c a n c i e s a n d i n t e r s t i t i a l sites as given in 3.2.2. (Charged surface sites are n o t c o m m o n b u t are i n c l u d e d h e r e for the s a k e of c o m p l e t e n e s s ) . T h i s gives rise to 12 m o r e c h a r g e defect e q u a t i o n s or a total of 42 defect e q u a t i o n s t h a t we c a n write!
92
The
positive
electronic
hole
requires
further
equivalent of the electron,
explanation, e-,
n+
is the
positive
in solids a n d t h e y a n n i h i l a t e
each o t h e r u p o n r e a c t i o n : 3.2.4-
e-
+
n+
=
energy
The following d i a g r a m s h o w s h o w the positive hole c a n exist in the solid.
Note t h a t we have labelled all t h r e e p l a n e s a n d have r e m o v e d Plane "2" so as to s h o w the p r e s e n c e of 70Gf131 in the lattice. This type of c h a r g e s u b s t i t u t i o n a l defect is u s e d extensively in the S e m i c o n d u c t o r I n d u s t r y to
93
p r o d u c e i n t e g r a t e d circuits by deliberate "doping" of at om s w hi ch have a valency differing from t h a t of the major s t r u c t u r a l element, i.e. Si as Si 4§ A second kind of electronic defect involves the electron. Let us s u p p o s e t h a t the second plane of the cubic lattice has a vac~m~ i nst ead of a substitutional i m p u r i t y of differing valency. This m a k e s it possible for t h e lattice to cap tur e and localize an e x t r a n e o u s electron at the vacancy site. This is s h o wn in the following diagram. The c a p t u r e d electron t h e n endows the solid s t r u c t u r e with special optical p r o p e r t i e s since it can absorb p h o t o n energy. The s t r u c t u r e t h u s b e c o m e s optically active. T h a t is, it absorbs light w i t hi n a well-defined b a n d and is called a "color-center" since it i m p a r t s a specific color to the crystal.
The alkali halides are noted for their p r o p e n s i t y to f o r m color-centers. It has been found t h a t the p e a k of the b a n d c h a n g e s as the size of the cation in the alkali halides increases. There a p p e a r s to be an inverse rel at i on b etween the size of the cation (actually, the polarizability of the cation) a nd the p e a k energy of the absorption band. These are the two types of electronic d e f ect s t h a t are found in crystals, n a m e l y positive "holes" and negative "electrons", and their p r e s e n c e in the s t r u c t u r e is related to t h e fact t h a t the lattice t e n d s to b e c o m e u p o n the type of defect p r e s e n t .
charge-compensated,
depending
94
R e t u r n i n g to t h e s u b j e c t of lattice defect f o r m a t i o n , we
can now proceed
to w r i t e a s e r i e s of defect r e a c t i o n s for t h e d e f e c t s w h i c h we f o u n d for o u r
plane net" 3.2.7.-
SCHO~
:
MX ~ M l . 5
Xl_5
FRENKEL :
MX --~ M1-5 X
ANTI-FRENKEL:
MX ~
F - CENTER:
MX ~ M X l - 5
MXI-5
+ 5Vm
+ 5Mi
+
+ 5Vx
+ 5Vx 5Vm
+
5Xi
+ {Vx/e-} +
5/2
x2~
In t h i s case, we u s e 5 as a s m a l l f r a c t i o n since t h e actual n u m b e r of d e f e c t s is s m a l l in r e l a t i o n to t h e overall n u m b e r of ions actually p r e s e n t . For t h e F-Center, the brackets enclose
the
complex
consisting
of a n e l e c t r o n
c a p t u r e d at a n a n i o n vacancy. Note t h a t t h e s e e q u a t i o n s e n c o m p a s s all of the
mechanisms
t h a t we
have p o s t u l a t e d
for e a c h
of t h e
individual
r e a c t i o n s . T h a t is, we s h o w t h e p r e s e n c e of v a c a n c i e s in t h e S c h o t t k y c a s e a n d i n t e r s t i t i a l c a t i o n s for t h e F r e n k e l c a s e involving e i t h e r t h e c a t i o n o r anion. T h e latter, involving a n i n t e r s t i t i a l a a i o n is called, by c o n v e n t i o n , t h e "Anti-Frenkel" case. The defect r e a c t i o n involving t h e "F-Center" is also given. Actually, t h e f o r m a t i o n of a n F - c e n t e r
is m o r e
complicated
t h a n this.
A l t h o u g h F - c e n t e r s c a n be f o r m e d by several m e t h o d s , t h e b e s t w a y to do so is b y e x p o s i n g a s o d i u m c h l o r i d e c r y s t a l to s o d i u m m e t a l v a p o r s . In t h a t case, t h e following defect r e a c t i o n s have b e e n o b s e r v e d to t a k e p l a c e : 3 . 2 . 8 . - Defect
R e a c t i o n s for t h e NaCI Crystal Na o ,g_... -7 Na + + e Na + + { N a +,C1-} # 2 { N a + I C 1 - , VCI]}
VC1
+
e- ~
[ Vc1 / e-]
These equations illustrate how the crystal responds
to t h e p r e s e n c e
of
s o d i u m vapor, i.e.- e x c e s s Na + , by f o r m i n g a n i o n v a c a n c i e s , to f o r m t h e Fcenter. Up to t h i s point, we h a v e only c o n s i d e r e d s t o i c h i o m e t r i c lattices. Let us
95
now c o n s i d e r n o n - s t o i c h i o m e t r i c lattices. W h a t we m e a n by this is that, in n o n - s t o i c h i o m e t r i c crystals, t h e h e t e r o g e n e o u s lattice c a n c o n t a i n an excess of either the cation or the anion in c o n t r a s t to the h o m o g e n e o u s lattice w h i c h m a y only c o n t a i n an excess of charge. W h a t h a p p e n s t h e n is t h a t the h e t e r o g e n e o u s lattice r e s p o n d s by c r e a t i o n of even m o r e l a t t i c e defects. 3-3 : NON-STOICHIOMETRIC SOLIDS In a n o n - s t o i c h i o m e t r i c crystal, the lattice m a y have e i t h e r excess c h a r g e or excess cations a n d / o r a n i o n s s i t u a t e d in the lattice. C o n s i d e r the s e m i conductor,
Ge. It is a h o m o g e n e o u s
solid a n d is e x p e c t e d
to c o n t a i n
excess charge. The defect r e a c t i o n s a s s o c i a t e d w i t h the f o r m a t i o n of ptype a n d n - t y p e lattices are: 3.3.1-
n-tylm:
Ge + 5As
-% [ Ge/Ass]
+
Be-
l~type:
Ge+SGa
-% [Ge/Ga5 ]
+
8~+
w h e r e 8 is a small excess over s t o i c h i o m e t r y . The excess c h a r g e s s h o w n are s p r e a d over the entire lattice, as s t a t e d before. In the h e t e r o g e n e o u s
solid, a different
mechmnism concerning
charge
d o m i n a t e s . If t h e r e are a s s o c i a t e d vacancies, a different type of e l e c t r o n i c defect, called the "M-center", prevails. In this case, a m e c h m n i s m s i m i l a r to t h a t already given for F - c e n t e r s o p e r a t e s , except t h a t two (2) e l e c t r o n s o c c u p y n e i g h b o r i n g sites in the crystal. The defect e q u a t i o n for f o r m a t i o n of the M - c e n t e r is: 3.3.2.-
M-center:
KC1 ~ KCII_5
+
5/2 C12 ~ + 5/4 [ V-c1 I V'Cl ]
The following diagram, given as 3.3.3. on the n e x t page, i l l u s t r a t e s t h e "M-Center": This
type of e l e c t r o n i c
defect,
found
only in
heterogeneous
solids,
c o n s i s t s of two associated, n e g a t i v e l y - c h a r g e d a n i o n vacancies, one o n e a c h p l a n e as s h o w n .
96
T h e y are usually j o i n e d along the {I I0} p l a n e of t h e lattice of the facecentered
salt crystal, a l t h o u g h we have not s h o w n t h e m this w a y ( T h e
{I00} p l a n e is i l l u s t r a t e d in the diagram). Note t h a t e a c h v a c a n c y has c a p t u r e d an e l e c t r o n in r e s p o n s e to the c h a r g e - c o m p e n s a t i o n m e c h a n i s m w h i c h is operative for all defect r e a c t i o n s . In this case, it is the anion w h i c h is affected w h e r e a s in the "F-center", it w a s t h e cation w h i c h was affected (see e q u a t i o n 3.2.8. given above). T h e s e
associated, negatively-
c h a r g e d , v a c a n c i e s have quite different a b s o r p t i o n p r o p e r t i e s t h a n t h a t of the F - c e n t e r . Additionally, the h e t e r o g e n e o u s solid will c o n t a i n defects in its lattice, as n o t e d above. This involves h e t e r o g e n e o u s solids c o n t a i n i n g i m p u r i t i e s a n d we u s e the s a m e type of n o t a t i o n given above. For the case of an AgCI c r y s t a l c o n t a i n i n g the Cd 2+ cation as an i m p u r i t y , we have: 3.3.4-
2 Ag+
~
[ Cd2+Ag+ ' VAg+]
w h e r e t h e Cd 2+ cation o c c u p i e s one Ag + site a n d the v a c a n c y t h e other, as n e a r e s t n e i g h b o r s . T h i s is an e x a m p l e of a h e t e r o t y p r
impurity system
since different c a t i o n s are involved. Although the v a c a n c y o c c u p i e s o n e site, it is n o t c h a r g e d since t h e total c h a r g e differential lies on the Cd2+Ag site. Note t h a t the symbol t h a t we have u s e d d e n o t e s
a doubly-charged
97
c a d m i u m cation on a m o n o v a l e n t silver cation site in the lattice. T h i s i l l u s t r a t e s the fact t h a t t h e n o r m a l lattice of an i n s u l a t o r c o m p o u n d t e n d s to c h a r g e c o m p e n s a t e itself fully, b u t excess c h a r g e does not a p p e a r . T h e same
is n o t
true
with
semi-conducting
compounds,
which
m a y be
h e t e r o g e n e o u s or h o m o g e n e o u s in n a t u r e . A n o t h e r h e t e r o t y p e e x a m p l e is CdCI2 c o n t a i n i n g Sb3+. Here, we c a n w r i t e at least t h r e e different e q u a t i o n s involving defect equilibria: 3.3.5.- Defect R e a c t i o n s Involving the CdCI2:Sb 3+ S y s t e m 2 Cd 2+
--7~
Sb 3+ +
2 Cd2+
--Tz'-
Sb3+
2 Cd2+
-7~
Sb3+
n+
+
+
VCd
V+Cd
+
Li+
In the last equation, we have the i n s t a n c e w h e r e c h a r g e - c o m p e n s a t i o n has o c c u r r e d due to i n c l u s i o n of a m o n o v a l e n t cation. A vacancy does not f o r m in this case. All of t h e s e e q u a t i o n s are c a s e s of i m p u r i t y s u b s t i t u t i o n s in the n o r m a l lattice.. A n o t h e r g e n r e is the so-called h o m o t y p e i m p u r i t y s y s t e m . One e x a m p l e is the
s u b s t a n c e , n i c k e l o u s oxide, w h i c h
is a p a l e - g r e e n
insulator w h e n
p r e p a r e d in an i n e r t a t m o s p h e r e . If it is r e h e a t e d in air, or if a m i x t u r e of NiO a n d Li + is r e h e a t e d in an i n e r t a t m o s p h e r e , the NiO b e c o m e s a b l a c k semi-conductor.
This
is a classical
example
of the
effect
of d e f e c t
r e a c t i o n s u p o n the i n t r i n s i c p r o p e r t i e s of a solid. The defect r e a c t i o n s involved are3.3.6.-
2 N i 2+ ~
[ N i 3+ / V N i ]
2 N i 2+ ~
Ni 3+ +
+
n+
Li +
This b e h a v i o r is typical for t r a n s i t i o n m e t a l s w h i c h easily u n d e r g o c h a n g e s in valency in the solid state.
T h a t is, h o m o t y p e i m p u r i t y s y s t e m s usually
involve c a t i o n s w h i c h can u n d e r g o valence c h a n g e s easily, i.e.- t r a n s i t i o n m e t a l cations. In the NiO case, we have gone f r o m an i n s u l a t o r to a s e m i c o n d u c t o r j u s t b y i n t r o d u c i n g lattice defects t h r o u g h a t h e r m a l effect.
98
Having i n t r o d u c e d
these
examples,
let u s n o w e x a m i n e
a method
of
s y m b o l i s m u s e f u l in c h a r a c t e r i z i n g defect r e a c t i o n s in solids. 3 . 4 . - D E F E C T EQUATION SYMBOLISM Whether
you realize
s y m b o l i s m for d e f e c t s
it or
not,
we
and defect
have already
developed
our
own
r e a c t i o n s b a s e d o n t h e P l a n e Net.
It
m i g h t b e well to c o m p a r e o u r s y s t e m to t h o s e of o t h e r a u t h o r s , w h o h a v e also c o n s i d e r e d wrote
the
represent
t h e s a m e p r o b l e m in t h e p a s t . It w a s R e e s (1930)
first m o n o g r a p h
on d e f e c t s
in solids.
Rees
t h e c a t i o n v a c a n c y , as did Libowitz (1974).
used
who
a b o x to
This has certain
a d v a n t a g e s s i n c e w e c a n w r i t e e q u a t i o n 3 . 3 . 5 . as s h o w n in t h e following: 3.4. I-
S y m b o l i s i z m U s e d for Defect E q u a t i o n s
2Cd=+
7-7
+C d
2 Cd 2+
-Tz'--
~-~
2 Cd 2+
z_ --7
~
I
+
+
Ca
+
Cd
Ni
+
Cd
i Cd
+
~+
Likewise, t h e o t h e r e q u a t i o n s of 3.3.6. w o u l d b e c o m e : 3.4.2-
2 Ni 2+
z._ -7
Ni3+ +
2 Ni2+
z._
Ni3+
[
[N i + n+ §
+
[~-] N i
A l t h o u g h t h e r e s u l t s a r e e q u a l as far as utility is c o n c e r n e d , c o n t i n u e to u s e o u r s y m b o l i s m , for r e a s o n s w h i c h will b e c o m e
we
shall
clearer
l a t e r on. T h e following T a b l e is a c o m p a r i s o n of defect s y m b o l i s m , as u s e d b y p r i o r A u t h o r s . Note t h a t o u r s y m b o l i s m m o s t r e s e m b l e s t h a t of Kroeger, b u t n o t in all a s p e c t s . T h e s e p r i o r a u t h o r s also c o n s i d e r e d o t h e r i n t r i n s i c d e f e c t s t h a t we h a v e n o t t o u c h e d , "anti-structure"
occupation.
namely interstices
and the so-called
99
Table 3- i C o m p a r i s o n of P o i n t Defect N o t a t i o n b y V a r i o u s A u t h o r s Rees{ 19301 Kroeffer [ 1 9 5 4 ) Libowitz ( 1 9 7 4 ) v Cation Site Vacancy:
DM
Anion Site Vacancy:
~x
VM
[~M
Vx
Cation I n t e r s t i t i a l
AM
Mi , M+i
Mi
Anion Interstitial
AX
Xi,
Xi
X- i
Negative Free C h a r g e
e
e-
e-
Positive Free C h a r g e
p
h+
h+
Interstices
~V.
Unoccupied Interstitial
---
V.1
Anti-structure Occupation
---
aV.
I
1
A
M M , X X, M x , X M
T h e l a t t e r d e a l s w i t h a n i m p u r i t y _Rnlon o n a c a t i o n site c o u p l e d w i t h an i m p u r i t y c a t i o n o n a n a n i o n site, b o t h w i t h t h e p r o p e r c h a r g e . We have mentioned
interstices
b u t n o t in detail. T h e y
appear
as a f u n c t i o n of
s t r u c t u r e (Refer b a c k to C h a p t e r 1 - D i a g r a m 1.3.2.). T h e r e
is o n e in a
t e t r a h e d r o n , four in a b o d y - c e n t e r e d c u b e , a n d six in a s i m p l e cube. T h u s , r in {c~Vi} is 1, 4 or 6, r e s p e c t i v e l y . We shall n e e d t h i s s y m b o l later, as well as V i , t h e u n o c c u p i e d i n t e r s t i t i a l . Before
we
proceed
to
analyze
defect
reactions
by a m a t h e m a t i c a l
a p p r o a c h , let u s c o n s i d e r a n a p p l i c a t i o n s of solid s t a t e c h e m i s t r y . In t h i s e x a m p l e , t h e effect of a defect o n t h e p r o p e r t i e s of t h e solid is d e s c r i b e d . 3-5 - SOME APPLICATIONS FOR D E F E C T C H E M I S T R Y In o r d e r to u n d e r s t a n d s o m e of t h e a s p e c t s of t h e s e e x a m p l e s , we n e e d to d i s c u s s a c e r t a i n a m o u n t of b a c k g r o u n d for e a c h a r e a of t h e solid s t a t e being considered.
I00
a. P h o s p h o r s : P h o s p h o r s are i n o r g a n i c m a t e r i a l s w h i c h c o n v e r t i n c i d e n t r a d i a n t e n e r g y to visible light w i t h i n a device. T h e device c h o s e n c a n be a c a t h o d e - r a y tube, i.e.- a television tube, or a f l u o r e s c e n t lamp. A p h o s p h o r c o n s i s t s of a m a t r i x modified by a n additive c h o s e n so t h a t it b e c o m e s optically active w i t h i n the matrix, or c o m p o u n d . This is an e x a m p l e of a s u b s t i t u t i o n a l i m p u r i t y in a lattice w h e r e i n
t h e additive, usually called an "activator",
i n t r o d u c e s a lattice defect t h a t is optically active. However,
the a d d e d
i m p u r i t y still follows all of the r u l e s found for defects in a lattice, as s h o w n by the following e x a m p l e . In the prior l i t e r a t u r e , it w a s found (Kinney-
1955)
t h a t Ca2P207 (i.e.-
c a l c i u m p y r o p h o s p h a t e ) could be activated by Sb 3+ to form a p h o s p h o r : Ca2P207: Sb.02. This f o r m a l i s m actually i n d i c a t e s the c o m p o s i t i o n : [(Cao.99, Sbo.ol)2 P2 07)]. where
a solid-state
solution
of c a l c i u m
pyrophosphate
and
antimony
p y r o p h o s p h a t e is i n d i c a t e d . T h e b r i g h t n e s s r e s p o n s e of this p h o s p h o r w a s m o d e r a t e w h e n excited by ultraviolet r a d i a t i o n b u t w a s i m p r o v e d four t i m e s by t h e addition of Li+. T h e o p t i m u m a m o u n t of Li+ p r o v e d to be t h a t exactly equal to the a m o u n t of Sb 3+ p r e s e n t in the p h o s p h o r , i.e.2 Ca 2+ ~-~ Sb 3+ + Li+. The
explanation
lies
in
f o r m a t i o n of the p h o s p h o r
the
defect
itself. The
reactions defect
controlling
reactions
the
occurring
w e r e found to be the s u b s t i t u t i o n of a trivalent cation on a divalent site a n d t h e defects r e a c t i o n s t h e r e b y associated. This is s h o w n in the following table w h i c h c o m p a r e s t h e s e two m e t h o d s of p r e p a r i n g s u c h m a t e r i a l s . In this case, the i n c r e a s e in b r i g h t n e s s w a s f o u n d to be r e l a t e d to the a m o u n t of activator actually b e i n g i n c o r p o r a t e d into the lattice. proportional
It to
is well k n o w n t h a t p h o s p h o r b r i g h t n e s s is t h e n u m b e r s of Sb 3+ ions (activators) actually
i n c o r p o r a t e d into cation sites of t h e p y r o p h o s p h a t e s t r u c t u r e .
101
Table 3 - 2 Defect R e a c t i o n s W h i c h Occur in the P h o s p h o r : (Ca.99, Sb.ol )2 P2 07). PHOSPHOR 2 Ca 2+ z.._ 2 Ca 2+
Sb3+Ca or 2 Ca 2+ ~ ~Sba+ca
+ VCa + ~+ Sb3+Ca + V+Ca +
Li+ca
BRIGHTNESS 25 % 100 %
P h o s p h o r s are p r e p a r e d by h e a t i n g the i n g r e d i e n t s at high t e m p e r a t u r e (> 1000 ~
to o b t a i n a c o m p o u n d having high crystallinity. The s i n t e r i n g
p r o c e s s d e c r e a s e s e n t r o p y a n d is c o u n t e r p r o d u c t i v e to the f o r m a t i o n of v a c a n c i e s in the p y r o p h o s p h a t e lattice. In the a b s e n c e of Li + , vacancyf o r m a t i o n w a s r e t a r d e d w i t h the r e s u l t t h a t the a m o u n t of Sb 3+ w h i c h could be i n c o r p o r a t e d into activator sites actually d e c r e a s e d . In c o n t r a s t , four t i m e s as m a n y activator ions were i n c o r p o r a t e d into the lattice w h e n the c h a r g e - c o m p e n s a t i n g Li + ions w e r e p r e s e n t on n e a r e s t n e i g h b o r sites. Since it w a s n e c e s s a r y to have a v a c a n c y w h i c h could form the c h a r g e c o m p e n s a t e d site, i.e.- V+Ca , r e q u i r e d for the i n c o r p o r a t i o n of t h e impurity, Sb3+ca2+, t h e s e lattice sites did not form, due to t h e s i n t e r i n g p r o c e s s m a n d a t o r y for f o r m i n g the p h o s p h o r . Note t h a t we have w r i t t e n two defect r e a c t i o n s for the case of vacancy f o r m a t i o n in Table 3-2. P y r o p h o s p h a t e is an i n s u l a t o r a n d the f o r m a t i o n of a p o s i t i v e l y - c h a r g e d vacancy is m u c h less likely t h a n the v a c a n c y p l u s a free positive charge. This b r i n g s us to a rule f o u n d in defect c h e m i s t r y t h a t s e e m s to be universal, namely: ALTHOUGH MORE THAN ONE DEFECT REACTION MAY BE APPLICABLE TO A GIVEN SITUATION, PREVAILING
ONLY ONE IS USUALLY FAVORED BY T H E
THERMODYNAMIC
AND
ELECTRON-COMPENSATION
CONDITIONS. 3 , 6 , - DEFECT EQUILIBRIA AND THEIR ENERGY J u s t as c h e m i c a l r e a c t i o n s c a n be d e s c r i b e d a n d c a l c u l a t e d in t e r m s of t h e r m o d y n a m i c c o n s t a n t s a n d c h e m i c a l equilibria, so c a n we also d e s c r i b e
102
defect f o r m a t i o n in t e r m s of equilibria. U s i n g t h e Law of Mass ,action, viz3.6.1-
Law of Mass Action: bB + cC
~ dD + e E
9K =
adD fieE / abB aCc
w h e r e t h e e q u i l i b r i u m c o n s t a n t , K, is w r i t t e n in t e r m s
of t h e a c t i v i t i e s
a n d coefficients of t h e e q u a t i o n given o n t h e left side of 3.6.1. We c a n also w r i t e a n e q u a t i o n for a n y given defect
in t h e lattice. For t h e i n t r i n s i c
defects in a n MX lattice, we w o u l d have: 3.6.2.-
F r e n k e l Defects {for t h e lVlX c r y s t a l )
Mx 3.6.3.-
-7
Mi
z_.
+
VM
9 KF
=
aM i av M / aM
S c h o t t k y Defects (for t h e MX c r y s t a l ] MX
~
V M + VX
. KSh
= aVM aVM / aMx
Note t h a t we have also specified t h e s e e q u i l i b r i u m c o n s t a n t s in t e r m s of t h e activity of t h e ~ i a t e d
defects.
We c a n also w r i t e t h e r m o d y n a m i c
e q u a t i o n s for t h e s e d e f e c t s : 3.6.4.-
Chemical Thermodynamics
AG = AH - T A S 3.6.5.-
=-RTlnK
K=
exp
A S / R - exp - A H / R T
Defect T h e r m o d y n a m i c s Kd = exp
ASd / R - exp - A H d / R T
w h e r e d refers to t h e specific defect. Note t h a t we m u s t k n o w e i t h e r AHd or ASd in o r d e r to c a l c u l a t e t h e e q u i l i b r i u m c o n s t a n t . Alternately, if we k n o w t h e e q u i l i b r i u m c o n s t a n t (or c a n e s t i m a t e it), we n e e d to k n o w only o n e of t h e o t h e r s to c a l c u l a t e t h e e n e r g y associated
with
the
defect.
The
following
summarizes
k n o w l e d g e we h a v e d e v e l o p e d above for t h e S c h o t t k y a n d F r e n k e l
the
103
defects: I. T h e r e
is an Activation E n e r g y for defect
formation.
In m a n y
cases, this e n e r g y is low e n o u g h t h a t defect f o r m a t i o n o c c u r s at, o r slightly above, r o o m t e m p e r a t u r e . 2. Defects m a y be d e s c r i b e d in t e r m s of t h e r m o d y n a m i c c o n s t a n t s a n d equilibria. The
presence
vibrational f r e q u e n c i e s
of defects
changes
both
the
local
in the vicinity of the defect a n d the local
lattice configuration a r o u n d the d e f e c t . One q u e s t i o n we m a y logically a s k is h o w are we to k n o w w h a t t y p e s of defects will a p p e a r in a given solid? T h e a n s w e r to this q u e s t i o n is as follows:
IT HAS BEEN FOUND: "There are two associated effects on a given solid w h i c h have o p p o s i t e effects on s t o i c h i o m e t r y . Usually, one involves the cation site and the other the anion site. Because of the d i f f e r e n c e s in d e f e c t - f o r m a t i o n - e n e r g i e s , t h e c o n c e n t r a t i o n of o t h e r d e f e c t s is ummlly negligible". T h u s , if F r e n k e l Defects p r e d o m i n a t e in a g i v e n solid, o t h e r defects are usually not p r e s e n t .
Likewise, for the S c h o t t k y
applies for ~ i a t e d types
of
Defect.
Note
that this
defects. If t h e s e are not p r e s e n t , t h e r e will still be 2
defects
present,
each
having
an
opposite
effect
upon
stoichiometry.
3 . 7 - DEFECT EQUIIJBRIA IN VARIOUS TYPES OF COMPOUNDS Up
to now,
hypothetical concepts
to
we
have b e e n
example more
of the
concerned solid
complicated
with
state. ones
c o m p o u n d s . We will u s e the p r e c e p t s
the
We will such
as
MX c o m p o u n d now
extend
binary
and
a l r e a d y developed
as a these
ternary
for the s i m p l e
MX c o m p o u n d . For t h e s a k e of simplicity, we r e s t r i c t ourselves to b i n a r y c o m p o u n d s , t h a t is- one cation a n d one anion.
An e x a m p l e of a t e r n a r y
104
c o m p o u n d is AIg(S, w h e r e A a n d B are different cations, a n d S is a s m a l l whole n u m b e r . Our e x a m p l e of a b i n a r y c o m p o u n d will be:
MXs In t h i s case, we m a y have: MX 2 , MX 3 or
even MX4. We c a n d i s t i n g u i s h
b e t w e e n four s t a t e s for t h e s e h y p o t h e t i c a l c o m p o u n d s , i n c l u d i n g s p e c i f i c c o m b i n a t i o n s of t h e s e s t a t e s , to wit: s t o i c h i o m e t r i c vs: n o n - s t o i c h i o m e t r i c non-ionized
vs: i o n i z e d
This gives us four c o m b i n a t i o n s :
1) Non-ionized S t o i c h i o m e t r i c 2) Ionized S t o i c h i o m e t r i c 3) N o n - i o n i z e d N o n - s t o i c h i o m e t r i c 4) Ionized N o n - s t o i c h i o m e t r i c
We will
deal
stoichiometric
with case
the and
first 2)
two
cases,
ionization
of
namely defects
1) in
defects
in
the
stoichiometric
c o m p o u n d s . Since t h e c a s e of n o n - s t o i c h i o m e t r i c c o m p o u n d s c a n be v e r y c o m p l i c a t e d , we will p r e s e n t t r e a t m e n t of t h e last two in t h e A p p e n d i x at t h e e n d of this C h a p t e r . a. .STOICHIOMETRIC BINARY ..COMPOUNDS OF MXs In t h e real world of defect c h e m i s t r y , we find t h a t in a d d i t i o n to t h e s i m p l e defects, o t h e r t y p e s of defects c a n also a p p e a r , d e p e n d i n g
upon
t h e type of c r y s t a l we are d e a l i n g with. T h e s e m a y be s u m m a r i z e d as s h o w n in t h e following, given as 3.7.1. on t h e n e x t page. A c c o r d i n g to o u r n o m e n c l a t u r e , as u s e d in t h e table, V M is a v a c a n c y at an M c a t i o n site, etc. The first five p a i r s of defects given above have b e e n o b s e r v e d e x p e r i m e n t a l l y in solids, w h e r e a s t h e last four have not. T h i s a n s w e r s t h e q u e s t i o n p o s e d above, n a m e l y t h a t defects in solids o c c u r in pairs.
105
3.7.1-
Defects in the MXs C o m p o u n d PAIRS OF DEFECTS ...... i'i'
ii ii
i
i
i
Schottky
VM
+ VX
Frenkel
VM
+ Mi
Anti-Frenkel Anti-Structure
Xi XM
+ Vx + MX
Vacancy- ~ m t i S t r u c t u r e
VM
+
-
i
i
i'
i
i
ii
MX i
i
i
Mi
Interstitial
+
A n ~ - S t r u c t u r e I n t e r s t i t i a l MX + Anti-Structure Interstitial A n t i - S t r u c t u r e Vacanc~r
Xi
Xi i
XM + XM +
Mi Vx
We have now i n t r o d u c e d into our n o m e n c l a t u r e
a distinction b e t w e e n
s t r u c t u r e and a n t i - s t r u c t u r e defects. What this m e a n s is t h a t s t a c k i n g faults can s o m e t i m e s result in the formation of XM and M• defects. T h e s e have been recognized as high-energy defects since they exist as cations (anions) s u r r o u n d e d by a complete positive (negative) charge. In fact, it is difficult to see j u s t how they could exist. However, there have been s o m e cases s tu d ied w he r e they do exist, and so we have included t h e m in our listing of defects although we originally st at ed t h a t s u c h defects are n o t likely to be very prevalent. However, note t hat these defects generally exist as a vacancy plus the a n t i - s t r u c t u r e defect, not as associated antis t r u c t u r e defects together, solid.
as we showed above for the h o m o g e n e o u s
Table 3-3, given on the next page, s u m m a r i z e s the various pairs of defect s possible for binary c o m p o u n d s .
Equilibria
are
given
along with
the
a p p r o p r iate equilibrium c ons t ant . Note t h a t these equations are r a t h e r simple and can be u s e d to specify the equilibrium c o n s t a n t s for t h e s e defects p r e s e n t in t h e lattice. These types of defects have been o b s e r v e d and s tu d ied in the c o m p o u n d s given u n d e r "Example" in t h i s Table. T h e s e are
the
major
types
of defects
to be
expected
in
most
c o m p o u n d s , wh e r e the n u m b e r of sites in the lattice is c o n s t a n t .
i norgani c
106
TABLE 3-3 POSSIBLE DEFECTS IN THE MXs COMPOUND (For a C o n s t a n t N u m b e r of Sites) Type of Defect
Defect Pair E x a m ' ) l e Defect E q u a t i o n
Schottky Frenkel
VM + Vx
,
VM + Mi
ZnO
,
Equilibrium Constant
0 --~ VM + S Vx +(~Vi
KSh = VM Vx S V i a
MM + o~Vi-~ VM + Mi K F - V M Mi / MM Vi a
,
Anti-Frenkel
Xi + Vx
Lfla2 Xx + [~ Vi ~ Xi + Vx
KAF = Xi VX / XX Vi~
,
Anti-Struct. If t h e r e
XM+MX
AuZn MM + Xx ~ Mx + XM KAS = M x X M / M M Xx
is an excess of sites p r e s e n t
in the lattice,
s o m e w h a t different (and m u c h m o r e complicated).
the
s i t u a t i o n is
In at least one case,
one type h a s b e e n o b s e r v e d a n d so we c a n n o t c o m p l e t e l y ignore t h e m , even t h o u g h t h e y are fairly r a r e . Table 3-4 gives a c o m p l e t e listing of t h e s e types of defects a n d the n a m e s given to t h e m . TABLE 3 - 4 (Excess N u m b e r of Sites) Name of
Defect
Defect
Pair Type Vac.-Struc. VM + MX
Defect E q u a t i o n 5MM ~ 6Mx +(1-6) VM
Equilibrium Constant KVS =
MSXVMI+Svi a / M5+ (x IV i
Struct.Vac.
Vx + XM
6Xx~XM ( 1 +6)Vx +ctVi
KSV =XM VX 1+5 Vi a/XSx
Interstitial
Mi + Xi
6(MM+SXx) --~Mi+S Xi
Ki = M i X i S V i l + 5 + a [MM 5 XxS5 1
- ( 1 +6+a)Vi
Interstitial
Mx+Xi
MX KIS = MX Xi 1+SVi(1+5+a) / MM Xx 1+5 +( 1 +6)Xi( 1 +8+a)Vi
Mi+XM
(I+6)MM
Struct. StructInterstial These
/
five defects
MM + ( I + 6 ) X x
+
~
SXx
(1+6)Mi + 5XM
KSI = MiXM a / MM 1+5 XXS
are b a s e d u p o n an excess in the n u m b e r of sites
available. This excess we call "8". Note t h a t we are not s p e a k i n g of t h e ratio of c a t i o n s to anions, i.e.- s t o i c h i o m e t r y , b u t of the total n u m b e r of sites. To see how this is possible, c o n s i d e r the V a c a n c y - S t r u c t u r e type.
107
We have a VM (a cation vacancy) a s s o c i a t e d w i t h an M x , an M a t o m on an anion site.The total n u m b e r of a t o m s r e m a i n s c o n s t a n t , b u t t h e r e is an e x c e s s of cations, notably M x . F o r t u n a t e l y , we do not have to deal w i t h t h e s e e q u a t i o n s very m u c h b u t i n c l u d e t h e m for the s a k e of c o m p l e t e n e s s . Note t h a t we have u s e d a h y p o t h e t i c a l c o m p o u n d to r e p r e s e n t
all of t h e
possible c o m p o u n d s t h a t we m i g h t e n c o u n t e r . In o r d e r to relate t h e s e e q u a t i o n to the real world, t h e following table lists the e q u a t i o n s given in Table 3-3 in t e r m s of a CaC12 crystal. TABLE 3- 5 POSSIBLE DEFECTS IN THE CaC12 COMPOUND (For a C o n s t a n t N u m b e r of Sites) Type of Schottky
VCa+ VC1
0 --~ VCa + 2Vc1 +(1Vi
Equilibrium Constant KSh = VCa V2C1 V i a
Frenkel
Vea+ Cai
MM + (~Vi ~ VM + Mi
KF =VCa Cai / Caca Vi a
ClCl + ~ Vi ~
KAF = Cli VC1 / C1c1Vi~
Defect
Anti-Frenkel Anti-Struct.
Defect Pair
Cli + VC1
Defect E q u a t i o n
Cli + VC1
C1Ca+Cac1 C~2a + C1C1--~ C1Ca+Cac1
KAS = C1Ca-~ac1
~a+
C1c1
We have u s e d CaC12 b e c a u s e it is a familiar m a t e r i a l a n d the e q u a t i o n s w h i c h r e s u l t are r a t h e r simple. Note t h a t in m o s t cases, the e q u i l i b r i u m c o n s t a n t is given in t e r m s of the r a t i o of defects to the n u m b e r of ions in t h e i r correct position in t h e lattice. Let us n o w c o n s i d e r the c o n c e n t r a t i o n of defects t h a t m i g h t a p p e a r in t h e MXs crystal. b . . D E F E C T CONCENTRATIONS IN ~
COMPOUNDS
To see h o w t h e s e e q u a t i o n s m i g h t be used, c o n s i d e r t h e following. First, s u p p o s e we w a n t to be able to d e t e r m i n e the n u m b e r of intrinsic d e f e c t s in a given solid. Since p a i r s of defects p r e d o m i n a t e in a given solid, t h e n u m b e r of e a c h type of i n t r i n s i c defect, Ni (M) or Ni (X), will equal e a c h
108
other, For S c h o t t k y defects in the MXs crystal, we have: 3.7.2-
Ni(VM)
= Ni(S Vx)
This m a k e s o u r m a t h e m a t i c s s i m p l e r since we can rewrite the S c h o t t k y e q u a t i o n of Table 3-3 as: 3.7.3-
0 -~ Ni (VM) + S Ni (VM) + a Vi
Here, we have e x p r e s s e d the c o n c e n t r a t i o n as the ratio of defects to t h e n u m b e r of M- a t o m sites (this h a s c e r t a i n a d v a n t a g e s as we will see). We can t h a n rewrite the defect equilibria e q u a t i o n s of Table 3-3
a n d 3-4 in
t e r m s of n u m b e r s of i a t r i m ~ r defect c o n c e n t r a t i o n s , s h o w n as follows: S o m e of t h e s e e q u a t i o n s are c o m p l i c a t e d a n d we n e e d to e x a m i n e t h e m in m o r e detail so as to d e t e r m i n e h o w t h e y are to be used. 3.7.4.-
EQUILIBRIUM CONSTANTS a n d INTRINSIC DEFECTS
SCHO~:
kSh = Ni (S N i ) 2
= S s NiS+l
FRENKEL:
kF
ANTI-FRENKEL:
kAF = Ni 2 / (S- Ni)(r
ANTI-STRUCT:
kAS = Ni 2 / ( 1 - N i ) ( S - N i ) S
VAC.-STRUCT:
kvs
= S s (S + 1 )S+l. Ni2S+l / (S-Ni -S Ni )S
STRUCT-VAC:
ksv
= (S+ 1)S+l NiS+2 / (S - N i - S Ni)
INTERSTIAL:
kI
= S S Ni S+I / (a - N i - SNi) a+S+I
= Ni 2 / (1- Ni) (r
Ni)
,.
Ni)
E q u a t i o n 3.6.10. given above s h o w s t h a t intrinsic defect c o n c e n t r a t i o n s will i n c r e a s e with i n c r e a s i n g t e m p e r a t u r e a n d t h a t t h e y will be low for high E n t h a l p y of defect formation. This arises b e c a u s e the e n t r o p y effect is
a positive
exponential.
exponential Consider
the
while
the
enthalpy
effect
following
examples
of
is
various
a
negative types
c o m p o u n d s a n d the n a t u r a l defects w h i c h m a y o c c u r ( d e p e n d i n g how the c o m p o u n d s w e r e originally f o r m e d ) :
of
upon
109
TiO
is c u b i c w i t h t h e NaCI s t r u c t u r e . A s a m p l e w a s a n n e a l e d at 1 3 0 0 ~
D e n s i t y a n d X-ray m e a s u r e m e n t s r e v e a l e d t h a t t h e i n t r i n s i c d e f e c t s w e r e S c h o t t l ~ in n a t u r e (VTi + VO) a n d t h a t t h e i r c o n c e n t r a t i o n w a s 0 . 1 4 0 . I n t h i s c a s e , S = 1 so t h a t : 3.7.5.-
KSh
= 0.0196 = 2 x I 0 -2
T h i s c r y s t a l is q u i t e d e f e c t i v e s i n c e i o u t of 7 T i - a t o m - s i t e s ( 0 . 1 4 -I) is a v a c a n c y , a n d l i k e w i s e for t h e o x y g e n - a t o m - s i t e s . A n o t h e r e x a m p l e isFrom intrinsic
thermodynamic
defects
were
measurements,
Anti-Frenkel
in
it w a s
nature,
i.e.-
found
that
the
(Hi
VH).
An
+
e q u i l i b r i u m c o n s t a n t w a s c a l c u l a t e d as: 3.7.6.-
kAF
--
3 . 0 x 10 -4
at a t e m p e r a t u r e of 6 0 0 ~
T h i s c o m p o u n d h a s t h e c u b i c fluorite s t r u c t u r e w i t h o n e o c t a h e d r a l i n t e r s t i c e p e r Ce a t o m . T h e r e f o r e , a = 1, a n d S = 2 for C e l l 2 . We c a n therefore write3.7.7.-
kAF
=
Ni 2 / (2- Ni )(1- Ni)
Ni
=
2.4 x 10 -2
= 3 . 0 x I 0 -4
or
(600 ~
T h i s m e a n s t h a t I o u t of 4 2 h y d r i d e a t o m s is i n t e r s t i t i a l , a n d I o u t of 8 4 h y d r i d e - a t o m - s i t e s is v a c a n t . Let u s n o w r e v i e w w h a t w e h a v e c o v e r e d c o n c e r n i n g s t o i c h i o m e t r i c b i n a r y compoundsI. We h a v e s h o w n t h a t d e f e c t s o c c u r in p a i r s . T h e r e a s o n for t h i s lies i n t h e c h a r g e - c o m p e n s a t i o n p r i n c i p l e w h i c h o c c u r s in all ionic solids.
110
2.
Of
the
nine
defect-pairs
possible,
only
5
have
actually
been
e x p e r i m e n t a l l y o b s e r v e d in solids. T h e s e areSchottky Frenkel Anti-Frenkel Anti-Structure Vacancy-Structure. 3. We have given d e f e c t - e q u a t i o n s for all n i n e types of defects, a n d t h e E q u i l i b r i u m C o n s t a n t s t h e r e b y associated. However, calculation of t h e s e equilibria would r e q u i r e values in t e r m s of e n e r g y at e a c h site, values w h i c h are difficult to d e t e r m i n e . A b e t t e r m e t h o d is to c o n v e r t t h e s e EC e q u a t i o n s to t h o s e involving n u m b e r s of each type of intrinsic defect, as a ratio to an intrinsic cation or anion. This w o u l d allow u s to calculate t h e actual n u m b e r of i n t r i n s i c defects p r e s e n t in the crystal, at a s p e c i f i e d temperature.
Let us n o w s u m m a r i z e w h a t we have c o v e r e d : 1. We have s h o w n t h a t defect e q u a t i o n s a n d equilibria c a n be w r i t t e n for t h e MXs c o m p o u n d , b o t h for s t o i c h i o m e t r i c a n d n o n s t o i c h i o m e t r i c cases. 2. In addition, we have s h o w n t h a t f u r t h e r defect f o r m a t i o n c a n be i n d u c e d by e x t e r n a l r e a c t i n g species, a n d t h a t t h e s e act to f o r m specific types of defects, d e p e n d i n g u p o n the c h e m i c a l n a t u r e of t h e crystal lattice. 3. We have also s h o w n t h a t the i n t r i n s i c defects c a n b e c o m e ionized to form s p e c i e s not found in n a t u r e . 3-8,-
THE E F F E .CI'S OF PURITY [AND. I M P U R I T I E S )
Our s t u d y h a s led us to the point w h e r e we c a n realize t h a t t h e p r i m a r y effect of i m p u r i t i e s in a solid is the f o r m a t i o n of defects, p a r t i c u l a r l y t h e F r e n k e l a n d S c h o t t k y types of a s s o c i a t e d defects. T h u s , the p r i m a r y effect
III
obtained in a high purity solid is the m i n i m i z a t i o n of defects. I m p u r i t i e s , particularly those of differing valencies t h a n those of the lattice, cause c h ar g ed vacancies a n d / o r interstitial sites. "We can also increase t h e reactivity of a solid to a certain extent by m a k i n g it m o r e of a defect crystal by the addition of selected impurities. It is not so a p p a r e n t as to w h a t h a p p e n s to a solid as we cont i nue to purify it. To u n d e r s t a n d this, w e need to examine the various grades of purity as we normally e n c o u n t e r them. Although we have e m p h a s i z e d inorganic c o m p o u n d s t h u s far (and will co n tin u e to do so), the s a m e principles apply to organic crystals as well. COMMERCIAL GRADE is usually about 95% purity (to o r i e n t ourselves, w h a t we m e a n is t h a t 95% of the m at eri al is t h a t specified, w i t h 5% being different (unwanted-?) material. Laboratory or "ACS-REAGENT GRADE" averages about 99.8% in purity. The GRADES listed are n a m e d for the usage to w h i c h they are applied, and are usually m i n i m u m purities r e q u i r e d for the particular application. Fiber optic materials are c u r r e n t l y p r e p a r e d by chemical vapor d e p o s i t i o n t e c h n i q u e s b e c a u s e any h a n d l i n g of m a t e r i al s i n t r o d u c e s i m p u r i t i e s . 3.8. I.- GRADES OF PURITY FOR COMMON CHEMICALS_ I m p u r i t y Atoms p e r GRADE
%
Commercial
95
50,000
Laboratory
99.8
2000
Luminescent
.
Mole of C o m p o u n d
Dgm
....
99.99 .
.
100 .
. .
1.2 x 1021 6 x 1019 .
Semi-conductor
99.999
Crystal G r o w t h
99.9999
1
6 x 1018 6 x 1017
Fiber-Optics
99.999999
0. 01
6 x 1015
,,,
10
3.0 x 10 22
F u r t h e r m o r e , this is the only way found to date to p r e p a r e the r e q u i r e d materials at this level of purity. The frontiers of purity a c h i e v e m e n t p r e s e n t l y lie at the fraction of p a r t s per
quadrillion
level.
However,
because
of E n v i r o n m e n t a l
Demands,
analytical m e t h o d o l o g y p r e s e n t l y available far exceeds this. We can n o w
112
analyze m e t a l s a n d anions at the femto level (parts p e r quadrillion = 10 -15) if we w i s h to do so.
Nevertheless, it is becoming apparent that as h/gh purity inorganic solids are being obtained, we observe that their physical properties may be somewhat different than those usually accepted for the same compound of lower Imrity. The h i g h e r - p u r i t y c o m p o u n d m a y u n d e r g o solid state r e a c t i o n s s o m e w h a t different t h a n t h o s e c o n s i d e r e d "normal" for the c o m p o u n d . If we r e f l e c t b u t a m o m e n t , we realize t h a t this is w h a t we m i g h t e x p e c t to o c c u r as w e obtain c o m p o u n d s (crystals) c o n t a i n i n g far fewer intrinsic d e f e c t s . It is p r o b a b l y true t h a t m a n y of the d e s c r i p t i o n s of physical a n d solid state r e a c t i o n m e c h a n i s m s n o w existing in the l i t e r a t u r e are only partially correct.
It would a p p e a r
that part
of the
frontier
of k n o w l e d g e
C h e m i s t r y of The Solid State will lie in m e a s u r e m e n t
for
of physical a n d
c h e m i c a l p r o p e r t i e s of inorganic c o m p o u n d s as a function of purity. S.u~ested Reading 1. A.C. D a m a s k a n d G.J. Dienes, Point Defects in Metals, G o r d o n Breach, New York ( 1 9 7 2 ) . 2. G.G. Libowitz, "Defect Equilibria in Solids", Treatice
&
on Solid State
Chem.- (N.B. Hannay- Ed.), I, 3 3 5 - 3 8 5 , ( 1 9 7 3 ) . 3. F.A. Kroeger, The Chemistry of Imperfect Crystals, N o r t h - H o l l a n d , Amsterdam (1964). 4. F.A. Kroeger & H.J. Vink in Solid State Physics, Advances in Research and Applications (F. Seitz & D. TurnbuU-Eds.), pp. 3 0 7 - 4 3 5 ( 1 9 5 6 ) . 5. J.S. A n d e r s o n
in Problems
of Non-Stoichiometry (A. Rabenau-Ed.),
p p . 1 - 7 6 , N. Holland, A m s t e r d a m ( 1 9 7 0 ) . 6. W. Van Gool, Principles of Defect chemistry of Crystalline Solids, Academic Press, New York ( 1 9 6 4 ) . 7. G. Brouwer, "A General A s y m m e t r i c Solution of Reaction E q u a t i o n s C o m m o n in Solid State Chemistry", Philips Res. Rept., 9 , 3 6 6 - 3 7 6 (1954)
113
Pairs in Ionic Crystals", Phys. Rev., 1 1 2 , 5 4 - 5 5
8. A. B. Lidiard, " r (1958). 9. J.S. A n d e r s o n ,
"l'he C o n d i t i o n s of E q u i l i b r i u m of N o n s t o i c h i o m e t r i c
C h e m i c a l C o m p o u n d s , Proc. Roy. Soc. (London), 1 1 8 5 , 6 9 - 8 9 ( 1 9 4 6 ) . 10. N.N. G r e e n w o o d , Ionic Crystals, Lattice Defects & Non-Stoichtometry, Butterworths, London (1968). PROBLEMS FOR CHAFTER 3 I. Identify the t y p e s of p o i n t defects likely to a p p e a r in a h o m o g e n e o u s solid.
Contrast
those
to t h e
typical defects
which
may appear
in
a
h e t e r o g e n e o u s solid. 2. Given the s t r o n t i u m
chloride
crystal, write
the
defect
reaction(s)
e x p e c t e d ff l i t h i u m chloride is p r e s e n t as an i m p u r i t y . Do likewise for t h e a n t i m o n y chloride i m p u r i t y . Also, write t h e defect r e a c t i o n s e x p e c t e d if b o t h i m p u r i t i e s are p r e s e n t in e q u a l q u a n t i t i e s .
3. D r a w o n e or m o r e "plane-nets" for the "P" cation c o m b i n e d w i t h a "U" anion. I n d i c a t e all of the possible
defects
t h a t c a n a p p e a r . Write t h e
symbol of e a c h as you p r o c e e d . I n c l u d e p a i r s of defects as n e e d e d .
4. Write e q u a t i o n s for as m a n y of the t h i r t y (30) defects r e a c t i o n s of y o u r "PU" plmne-net as you can. Do not forget t h e d e f e c t - p a i r s . 5. For a divalent lattice c o n t a i n i n g b o t h Ca 2+- a n d S = , write all 30 of t h e e q u i l i b r i u m e q u a t i o n s if b o t h As3+ a n d CI- are s u b s t i t u t i o n a l i m p u r i t i e s in the lattice. ( I n c l u d e all of t h e possible v a c a n c i e s a n d i n t e r s t i t i a l sites). Be s u r e to i n c l u d e t h e site w h e r e e a c h ion is s i t u a t e d . 6. Calculate the activation e n e r g y at r o o m t e m p e r a t u r e for a cubic c r y s t a l c o n t a i n i n g 3 x 10 -3 v a c a n c i e s .
114
7. Rewrite all of the e q u a t i o n s in Table 3-2 in t e r m s of the c o m p o u n d , CaCI2, a n d c o m p a r e t h e m to t h o s e given in Table 3-3. What effect d o e s n o n - s t o i c h i o m e t r y have u p o n the n u m b e r s a n d types of defects t h a t m a y be p r e v a l e n t ? Do the s a m e for the c o m p o u n d AsCI3. 8. Write a series of e q u a t i o n s for the F r e n k e l defect, similar to t h o s e given for the S c h o t t l ~ defect, i.e.- E q u a t i o n s 3.7.2 to 3.7.3. 9. Using a "MX" plane net, illustrate the defects s h o w n in 3.7.1. for t h e h y p o t h e t i c a l c o m p o u n d , MX. Do the s a m e for the c o m p o u n d , M X 2 , u s i n g the configuration: X-M-X. I0. Given: kSh = 3 x I 0 3
for CaCI2, calculate the n u m b e r of i n t r i n s i c
defects p r e s e n t in this crystal. If CaCI2 is f a c e - c e n t e r e d
cubic, u s e t h e
s a m e e q u i l i b r i u m c o n s t a n t to calculate the intrinsic Frenkel, A n t i - F r e n k e l a n d I n t e r s t i a l defects e x p e c t e d in this crystal. 11. The native defects in ZnO are: V=zn, Z n i , VO, Zn+i, VO+ , & V z n . a. Write the defect r e a c t i o n s leading to their f o r m a t i o n . b. Write the defect r e a c t i o n s for ZnO t h a t h a s b e e n s u b j e c t e d to a r e d u c i n g a t m o s p h e r , i.e.- a r e a c t i o n with H2. Predict the i n t r i n s i c defects w h i c h will be p r e s e n t . 12. Draw a h e t e r o g e n e o u s lattice, u s i n g circles a t o m p o s i t i o n s in a simple
cubic lattice.
a n d s q u a r e s to i n d i c a t e
Indicate
both
Schottky
and
F r e n k e l defects, p l u s the simple lattice defects. Hint- u s e b o t h cation a n d anion sub-lattices. 13. The following v a c a n c y p a r a m e t e r s have b e e n m e a s u r e d for a solid as: AH v = 2 2 0 0 cal / mol ASv = 2.0 k Calculate the vacancy c o n c e n t r a t i o n at 160 ~ A p p e n d i x III)
a n d at 298 ~
(Hint: see
115
14. The following vacancy p a r a m e t e r s have b e e n m e a s u r e d for gold as: AH v = 2 1 . 6 2 kcal / mol ASv= 2.0 K Calculate the v a c a n c y c o n c e n t r a t i o n at the m e l t i n g p o i n t of 1063 ~ a n d at 298 ~
Appendix I. C o n c e n t r a t i o n s of Defects in Non-Ionized N o n - S t o i c h i o m e t r i c C o m p o u n d s This
presentation
is p r e s e n t e d
for t h o s e w h o w i s h
to
examine
the
m a t h e m a t i c s of b o t h n o n - s t o i c h i o m e t r i c intrinsic- defect c o m p o u n d s a n d the ionization of defects in b o t h s t o i c h i o m e t r i c
and nonstoichiometric
c o m p o u n d s as r e p r e s e n t e d by:
MXs• A. DEFECTS IN NON-STOICHIOMETRIC MXs + 8 COMPOUNDS We now p r o c e e d as we did for the s t o i c h i o m e t r i c case, n a m e l y to d e v e l o p defect- c o n c e n t r a t i o n e q u a t i o n s for the n o n , s t o i c h i o m e t r i c case. C o n s i d e r the effect of A n t i - F r e n k e l defect p r o d u c t i o n . F r o m Table 2-1, we get KAF, with its a s s o c i a t e d equation,
kAF
9 In Table 2-2, we u s e Kxi
for X-
interstitial sites. C o m b i n i n g these, we get:
App 1.1.-
KAF = KVx " Kxi
When both Vx
and
Xi
=
Ni 2 / (S-Ni} (r
coexist
in
the
s t o i c h i o m e t r y (from 3.7.10.) b e c o m e s : Appl.2.-
5
= [Xi] -
[Vx]
Using the e q u i l i b r i u m c o n s t a n t of 3.7.9., i.e.-
Ni )
lattice,
the
deviation
from
116
App 1.3.-
Kv x =
Px2 I/2 [Vx] /Xx
=
pX 2 1/2 [Vx] / S - [Vxl
a n d t h e a p p r o p r i a t e o n e f r o m Table 3-2 {i.e.- Kxi ), we get {assume for s i m p l i c i t y t h a t S = ~ = 1) 9 App 1.4.-
5
= ct Px21/2 K x i / p x 2 Kxi + 1
-
S K v x / Kv x + Px21/2
We c a n r e a r r a n g e t e r m s in App 1.4. to obtain: App 1.5.-
Kxi {I- 5} p x 2- 6( K v x K x i + 1) Px2 I/2 -Kvx 2 {1- 6 }
U s i n g App I . I . a n d Ni << App 1.6.-
=
0
I, we n o w obtain:
Ni 2 (1- 5}px 2- 6 Kv x Px21/2-
Kvx 2 ( I - 6) = 0
Solving for p x 2 yields 9
App 1.7.p x 2 = KVx 2 ( 82+ 2 N i ( l -
Since
at s t o i c h i o m e t r i c
62 ) + 6 1 6 2 + 4 N i ( I - 5 2 ) ] I 1 2 1 2 N i 4 (I-6) 2
composition,
5 must
e q u a l zero,
this
rather
f o r m i d a b l e e q u a t i o n r e d u c e s to:
App 1.8.where
Px2 o
Px2~ = Kv x 2 ! Ni2 is t h e p r e s s u r e of X2
gas in e q u i l i b r i u m w i t h t h e MXs
c r y s t a l at t h e s t o i c h i o m e t r i c c o m p o s i t i o n . T h i s gives u s t h e o p p o r t u n i t y to divide App 1.7. by App 1.8. to obtain:
App 1.9.- Px2 /Px2 ~
= 82 + 2 Ni (I- 62) + 6162 + 4 Ni { I - 6 2 } 1 2 N i 2 { i - 5 ) 2
We c a n t h e r e f o r e c a l c u l a t e 5 in t e r m s of t h e ratio of Px2 to Px2 o a n d Ni. T h i s r e s u l t is s h o w n in t h e following d i a g r a m ;
117
H e r e i n is s h o w n h o w 8 c h a n g e s f r o m n e g a t i v e to p o s i t i v e at t h e h i g h e r p r e s s u r e r a t i o s. For a h y p o t h e t i c a l MXs c o m p o u n d (S = 1), w h i c h c o n t a i n s A n t i - F r e n k e l d e f e c t s , to o b t a i n a 0 . 7 % d e v i a t i o n f r o m t h e s t o i c h i o m e t r i c c o m p o s i t i o n r e q u i r e s a p r e s s u r e i n c r e a s e of s o m e 5 0 0 0
fold, w h e n
the
o r i g i n a l i n t r i n s i c d e f e c t c o n c e n t r a t i o n is 10 -4 . H o w e v e r , if it is 10 -2 , o n l y a two-fold i n c r e a s e in p r e s s u r e is n e e d e d
to c a u s e t h e s a m e effect on a
d e v i a t i o n of 0 . 7 % , :i.e.- 6 = + 0 . 0 0 7 in MXs+8.
This means that a
hlghly d e f e c t i v e
t h e f o r m a t i o n of m a n y m o r e defects
s t r u c t u r e is m u c h m o r e p r o n e t o c a u s e
defects
than one contslniug
only a few
118
A l t h o u g h we will n o t t r e a t t h e o t h e r t y p e s of p a i r s of defects, it is well to n o t e t h a t s i m i l a r e q u a t i o n s c a n also b e d e r i v e d
for t h e o t h e r i n t r i n s i c
defects. W h a t we h a v e really s h o w n is t h a t e x t e r n a l r e a c t a n t s c a n c a u s e f u r t h e r c h a n g e s in t h e n o n - s t o i c h i o m e t r y of t h e solid. Let u s n o w c o n s i d e r ionized defects.
It s h o u l d be c l e a r t h a t a n e x t e r n a l g a s e o u s f a c t o r h a s a
m a j o r effect u p o n d e f e c t f o r m a t i o n . T h e e q u a t i o n s given above are v e r y c o m p l i c a t e d a n d r e p r e s e n t m o r e closely w h a t actually h a p p e n s in t h e r e a l w o r l d of defect f o r m a t i o n in c r y s t a l s .
APPENDIX I I ANALYSIS OF A REAL CRYSTAL USING A THERMODYNAMIC M E T H O D In t h e n o n - s t o i c h i o m e t r i c the m a t h e m a t i c s
case where
i o n i z a t i o n of d e f e c t s is t h e n o r m ,
b e c o m e too c o m p l i c a t e d so t h a t t h e e q u a t i o n s are n o t
solvable. However, we c a n u s e a t h e r m o d y n a m i c r e s u l t s we w a n t . We will p r e s e n t u s e in p h o t o g r a p h i c
film
method
to o b t a i n t h e
h e r e t h e c a s e of silver b r o m i d e w h o s e
highlights
the
u s e of d e f e c t
chemistry
for
practical purposes.
I. T H E At!Br CRYSTAL WITH A DIVALENT IMPURITY, Cd 2+ v
C o n s i d e r t h e crystal, AgBr. B o t h c a t i o n a n d a n i o n are m o n o v a l e n t , i.e.- Ag + a n d B r - . T h e a d d i t i o n of a d i v a l e n t c a t i o n s u c h as Cd 2+ s h o u l d i n t r o d u c e vacancies, VAg,
into
mechanism.
maintain
To
the
c r y s t a l , b e c a u s e of t h e electro-neutrality,
we
charge-compensation prefer
to
define
the
s y s t e m as: App. 2 - 1 . -
(1-6) Ag + Br- : 6 Cd 2+ S =
F o r t u n a t e l y , AgBr is e a s y to g r o w as a single crystal, u s i n g S t o c k b a r g e r Techniques.
Possession
and
facilitates o u r m e a s u r e m e n t
measurement
of d e f e c t s .
T h e d e f e c t s we e x p e c t to find are:
of a single
crystal
greatly
119
App. 2-2.-
WAg , Agi , e- , n+, CdAg , a n d
[CdAg, VAg]
The last defect is one involving two n e a r e s t n e i g h b o r cation l a t t i c e - s i t e s The following Table p r e s e n t s t h e defect r e a c t i o n s g o v e r n i n g this case.
TABLE 2-App D E F E C ~ REACTIONS IN THE AgBr CRYSTAL CONTAINING Cd 2+ a.
0
b. c.
AgA4~ + ( x V i AgAg + (~ Vi
d.
e_ VAg
z._
-7 ~.--
-7
Ag i
+ 71;+ + Agi
VAg
+ Agi +
--7
Agi + + eBrBr + VBr
e.
1 / 2 Br2
-7
f.
CdA_g ~'-7
CdAg+ + e-
g.
CdAg + VAg
L._
[CdAg, VAg]
h.
CdAg+ + WAg-
-7
lea N , v~l
i. For C o n s t a n t Cd CdT = CdAg + CdAg+ + [CdAg , WAg] = K j. For E l e c t r o - n e u t r a l i t y e- +VAg- = ~+ + A g i +
+ CdAg+
E x p e r i m e n t a l l y , we find t h a t if we fix the Cd 2+ c o n t e n t at s o m e c o n v e n i e n t level, it is n e c e s s a r y to a n n e a l the AgBr c r y s t a l s at a fixed t e m p e r a t u r e for t i m e s long e n o u g h to achieve c o m p l e t e equilibrium. If t h e t e m p e r a t u r e is c h a n g e d , t h e n b o t h type a n d relative n u m b e r s of defects m a y also c h a n g e . S i n g l y - c h a r g e d defects p r e d o m i n a t e , i.e.-
App. 2-3.-
2VAg
=
Agi +
+
CdA~
T h e s e in t u r n m a y form the c o m p l e x : App. 2-5.-
CdAg+ +
App. 2-6.-
VAg ~
WAg-~
WAg
[CdAg
+ a+
, VAgl
120
B. DEFECT DISORDER IN A~Br- A THERMODYNAMIC Ap.PROA.CH. v
To i l l u s t r a t e yet o n e a p p r o a c h to analysis of defect f o r m a t i o n , c o n s i d e r t h e i n f l u e n c e of Br2 gas u p o n defect f o r m a t i o n in AgBr. T h e
free e n e r g y of
f o r m a t i o n , AG, is r e l a t e d to t h e r e a c t i o n :
App. 2 - 8 . -
Ago + 112 Br2 {g) ~
AgBr{g)
{AG~
}
T h i s c a n be r e w r i t t e n as: App. 2 - 9 . -
aAg p l / 2
Br 2
=
exp AG ~
/ RT
It m a k e s n o difference as to w h i c h of t h e activities w e use. If w e n o w fix PBr 2 at s o m e low value, we Fred t h a t t h e ~ / e crystal, as i n f l u e n c e d b y t h e e x S e m a / f a v t a r ,
App. 2- I 0 .
Agi + , WAg , Bri-
d e f e c t s in o u r AgBr
PBr2, will be-
, VBr + , e
and
~+
B e c a u s e of t h e h i g h e l e c t r o s t a t i c e n e r g y r e q u i r e d to m a i n t a i n t h e m in an ionic c r y s t a l s u c h as AgBr, w e c a n safely i g n o r e t h e following lac~aible defects:
App. 2 - 1 1 .
AgBr + , AgBr ++ ,
BrAg
, BrAg = .
If we h a v e t h e r m a l d i s o r d e r at r o o m t e m p e r a t u r e
(I do n o t k n o w of any
c r y s t a l for w h i c h t h i s is n o t t h e case), t h e n we c a n e x p e c t t h e f o l l o w i n g defect r e a c t i o n r e l a t i o n s :
App. 2 - 1 2 . -
Agi +
=
WAg"
Bri
=
Agi +
VAg-
=
VBr +
Bri -
=
VBr +
121
At e q u i l i b r i u m , t h e following e q u a t i o n s arise, as s h o w n in A p p . 2 - 1 3 . App. 2 - 1 3 . -
P-gAg
+ 1 / 2 Br2 {g) ~
K6 =
WAg-
AgBr{s) + VAg
+ n+
~+ / p l / 2 B r 2
T h i s gives u s a t o t a l of eight (8) c o n c e n t r a t i o n s to calculate. T h e y involve: App. 2 - 1 4 . -
Ag~,
BrBr , A g i ,
Bri
, WAg- , VBr + , e- ,
n+
O u r p r o c e d u r e is to set u p a site b a l a n c e in t e r m s of lattice m o l e c u l e s , i.e.- AgBr: App. 2 - 1 5 . -
AgAg , + WAg- + e-
= 1
(e-
BrBr
= 1
(~+
+ VBr + + ~+
~-
Ag-Ag) Br+Br )
S i n c e Br2 {gas} is t h e d r i v i n g force for defect f o r m a t i o n , w e n e e d also to c o n s i d e r d e v i a t i o n f r o m s t o i c h i o m e t r y , 6 . T h u s , w e also set a Ag1=8 Br balance: App. 2 - 1 6 . -
Aga.g + A g i +
+e-
BrBr + Bri-
=
+~+
1+6
=
1
To m a i n t a i n e l e c t r o - n e u t r a l i t y , t h e following e q u a t i o n is a p p l i c a a b l e : App. 2 - 1 7
.-
Agi +
+ VBr +
+ n+
=
Bri-
+ WAg
+ e-
We also set u p t h e following e q u a t i o n s : App. 2 - 1 8 . -
Ag~
+
r
~
Agi +
BrBr
+
r
~
Bri-
+~+
~
e-
0
+ VAg+
VBr +
Ke
= Agi+VAg-/ Vi a
Ky = B r i - V B r + / V i a K~ =
e-
~+
Note t h a t we h a v e d i s t i n g u i s h e d b e t w e e n t h r e e (3) s i t u a t i o n s , to wit: a. E l e c t r o - n e u t r a l i t y b. T h e r m a l D i s o r d e r
122
c. N o n - s t o i c h i o m e t r y (excess c a t i o n ) These
are t h e eight e q u a t i o n s
(App. 2-12.
to App.
2-18.)
required
to
c a l c u l a t e t h e defect c o n c e n t r a t i o n s a r i s i n g f r o m t h e effects of t h e e x t e r n a l factor, PBr2-
From
measurements
migration
of
of
charged
conductivities,
species),
transfer
lattice
numbers
constants
and
(electro-
experimental
d e n s i t i e s , it h a s b e e n s h o w n t h a t F r e n k e l defects p r e d o m i n a t e
(Lidiard -
1957). T h i s m e a n s that:
App. 2 - 1 9 . -
Agi + , WAg-
F u r t h e r m o r e , VAg-
>>
Bri-
,
VBr +
_~ Agi + so t h a t ill t e r m s of o u r e q u i l i b r i u m c o n s t a n t s
we get: App. 2-20.-
FOR F R E N K E L D E F E C T S :
K~ >> K~
a n d K~
T h u s , we n e e d only to c o n s i d e r t h e above two (2) defects,
>> K8
n a m e l y - VAg-
a n d Agi + , since t h e y are t h e m a j o r c o n t r i b u t o r s to n o n - s t o i c h i o m e t r y . c a l c u l a t i n g POBr 2 as before ( w h e n 6 = 0 ,
see 2 . 7 . 2 2 & 2.7.23.),
By
we c a n
e x p r e s s o u r overall defect e q u a t i o n as:
App. 2-21 .-
pl/2Br2 / (POBr2) 1/2 = {6 / 2e +[ ( 1+ 8/2e )211/ :2 } {6/218 + [ 1+(8/2[~)211 / 2 }
B e c a u s e of t h e c o n d i t i o n s given in App. 2-14., t h e first half of t h e e q u a t i o n can be set equal to one. equih'brium
App. 2 - 2 2 . -
constants
e ~
NotethRtwe
are using
8 ,
~
,
and
y
as the
. i.e. -
Ke 1/2
~
In t h e r e m a i n i n g p a r t of t h e e q u a t i o n ,
-~
K~ 1/2
y ~
K71/2
6 >> ~ . By t a k i n g l o g a r i t h m s , w e
123
c a n t h e n obtainApp. 2 - 2 3 . -
1/21n
/po
PBr 2
=
Br2
ln5
- In [3
T h i s r e s u l t t h e n l e a d s us to a plot of the effect of p a r t i a l p r e s s u r e of Br2 on t h e deviation from s t o i c h i o m e t r y , 5 , for the AgBr crystal. (This w o r k is d u e to G r e e n w o o d - 1 9 6 8 ) . For ~ = 0 , t h e r e is a point of inflection w h e r e the slope of the line is defined by the e q u i l i b r i u m c o n s t a n t , i.e.- ~
=
K~Y2 . The larger t h i s
value, the flatter is the curve. All r e l a t i o n s r e g a r d i n g the defects c a n n o w be derived. The m a j o r defects t u r n o u t to be-
App. 2-24.-
VAg-
e-
F__
w
Agi +
---
K5 ( 1 / K e ) 1/2
pl/2
~
(Ks) 1/2 (1/Ks) K~ ( 1 / P B r 2 ) 1/2
Br 2
T h i s s h o w s t h a t b o t h n+ arid e- are rrdnority defects d e p e n d e n t on PBr2. The following gives the s t a n d a r d E n t h a l p y a n d E n t r o p y of t h e s e d e f e c t r e a c t i o n s , a c c o r d i n g to Kroeger ( 1965)-
App. 2 - 2 5 . AgAg ~
D E F E C T REACTION
AS
Agi + + VAg ( F r e n k e l )
Ag/~ + BrBr --7
VAg"
+
AH
Cal. / mol / ~ 25.6
VBr +
Kcal. / mol. 29.3
- 13.3
36
25
78
4.9
25.4
,
0~
e- + n+
1/2Br2
+ AgAg ~ AgBr + "gAg
It is a p p a r e n t
.....
that the Frenkel
p r o c e s s are t h e p r e d o m i n a t i n g
+ n+
process
coupled
with
the
electronic
m e c h a n i s m s in f o r m i n g defects in AgBr
t h r o u g h the a g e n c y of e x t e r n a l r e a c t i o n w i t h Br2 gas.
124
A Final c o m m e n t : we c a n use t h e s e t h e r m o d y n a m i c values to calculate t h e e q u i l i b r i u m c o n s t a n t s a c c o r d i n g to: App. 2 - 2 7 . -
Ki =
exp-
AGi o / R T
a n d c a n also obtain the activity of the silver a t o m in AgBr from App. 2-9. By u s i n g e q u a t i o n App. 2-9., we c a n s h o w : App. 2 - 2 8 .
For aAg
= I , @ T = 277 ~
For PBr2 = I atm.
@ 277 ~
9 6 = + 1012 9 6 =- I0 7
w h e r e the p l u s or m i n u s indicate an excess or deficit of the silver a t o m in AgBr. This r e s u l t is due to W a g n e r ( 1 9 5 9 ) . Apt)endix I ! I Statistical M e c h a n i c s a n d the Point Defect The m a t h e m a t i c a l m e t h o d , statistical m e c h a n i c s , w a s developed by J a m e s Clerk Maxwell of S c o t l a n d a n d Ludwig B o l t z m a n n of G e r m a n y to p r e d i c t a n d explain
the
measurable properties
of m a c r o s c o p i c
systems,
i.e.-
solids, on the basis of the p r o p e r t i e s a n d b e h a v i o u r of the m i c r o s c o p i c constituents
of t h o s e
systems,
i.e.-
atoms.
Statistical m e c h a n i c s ,
for
example, i n t e r p r e t s t h e r m a l e n e r g y as the e n e r g y of atomic p a r t i c l e s in disordered energy
states and temperature
is s h a r e d
among
such
as a q u a n t i t a t i v e m e a s u r e
particles.
Statistical
mechanics
of h o w draws
heavily on the laws of probability, so t h a t it does not c o n c e n t r a t e on t h e b e h a v i o u r of every individual particle in a m a c r o s c o p i c s u b s t a n c e b u t o n the average b e h a v i o u r of a large n u m b e r of particles of the s a m e k i n d . One law of statistical m e c h a n i c s
s t a t e s that,
in a s y s t e m in t h e r m a l
equilibrium, on the average, an equal a m o u n t of e n e r g y will be a s s o c i a t e d with e a c h i n d e p e n d e n t
e n e r g y state. This law s t a t e s specifically t h a t a
s y s t e m of particles in e q u i l i b r i u m at absolute t e m p e r a t u r e T will have an average e n e r g y of 1 / 2 kT a s s o c i a t e d with e a c h degree of f r e e d o m ( w h e r e k
is the
Boltzmann
constant).
In
addition,
any degree
of f r e e d o m
c o n t r i b u t i n g p o t e n t i a l e n e r g y will have a n o t h e r 1 / 2 k T a s s o c i a t e d w i t h it.
125
For a s y s t e m of n d e g r e e s of f r e e d o m , of w h i c h t h a v e a s s o c i a t e d p o t e n t i a l e n e r g i e s , t h e total a v e r a g e e n e r g y of t h e s y s t e m is 1 / 2 ( n + t ) k T . For a n a t o m in a solid, v i b r a t o r y m o t i o n involves p o t e n t i a l e n e r g y as w e l l as k i n e t i c e n e r g y , a n d b o t h m o d e s vail c o n t r i b u t e a t e r m 1 / 2 k T , r e s u l t i n g in a n a v e r a g e total e n e r g y of 3kT. T h u s , it is t h e e n t r o p y of m i x i n g t h a t forces t h e c r e a t i o n of a c e r t a i n n u m b e r of v a c a n t l a t t i c e p o s i t i o n s above 0.0
~
Hence,
vacancies
are
the
natural
resultof
thermodynamic
e q u i l i b r i u m a n d n o t t h e r e s u l t of a c c i d e n t a l g r o w t h or s a m p l e p r e p a r a t i o n . In o r d e r to u s e t h i s m e t h o d , o n e s t a r t s b y d e f i n i n g t h e n u m b e r of s t a t e s t h a t m a y b e p r e s e n t . Let NL b e t h e t o t a l n u m b e r of l a t t i c e s i t e s a n d Nv b e t h e n u m b e r of v a c a n c i e s . T h e n u m b e r of w a y s t h a t Nv v a c a n c y - s i t e s c a n b e a r r a n g e d o n NL s i t e s will b e a s i m p l e c o m b i n a t i o n , d e f i n e d b y a m i x i n g entropy: App3.1.-
g~ =
NL! Nv f {N~ - N v) !
T h e m i x i n g e n t r o p y is d e f i n e d by: App3.2.-
ASM = k In g~
In o r d e r to solve c o m b i n a t o r i a l e q u a t i o n s like A p p 3 .1,, a m e t h o d
called
S t i r l i n g ' s a p p r o x i m a t i o n for l a r g e n u m b e r s is u s e d . T h i s givesApp3.3.where
N L
AS M _= k [ N L In N L - Nv In N v - (N L - Nv) ln()] is t h e n u m b e r of l a t t i c e s i t e s a n d N v is t h e n u m b e r of v a c a n c i e s .
It is well to n o t e h e r e t h a t App3.4.-
N L > >
Nv SO t h a t t h e e n t r o p y of m i x i n g will be-
AS M= IN v In N L - N v In N v ] or
AS M = - k N v l n ( N v / N L) = - R X v l n X ~
w h e r e Xv is t h e q u o t i e n t of
Nv/N
L .
T h i s e x p r e s s i o n is o n l y valid for n o n -
126
interacting
d e f e c t s . A n d , it is t h e s a m e a s t h e
entropy
of m i y d n g of a n
i d e a l s o l u t i o n , vis: App3.5.-
AS M= -R [X^ In X. + Xv In X v l
S i n c e X . is a n y a t o m in t h e solid, X A -= i, t h e e n t r o p y of m i x i n g b e c o m e s : App3.6.-
AS M= - R X v In X v
T h e c o m p l e t e H e l m h o l t z f r e e e n e r g y of t h e s y s t e m is t h e n w r i t t e n : App3.7.-
AFv = - Nv [AEv- TASW] + RT [ [ N , - NvI In N_a._:_NNv + N v In __Nv_l [ N L N L N~I~KLI
w h e r e AS v
is t h e c h a n g e in v i b r a t i o n a l e n t r o p y a r i s i n g f r o m a c h a n g e i n
v i b r a t i o n a l e n e r g y a r o u n d t h e v a c a n r l a t t i c e s i t e . If w e m i n i m i z e
the free
e n e r g y w i t h r e s p e c t to t h e v a c a n c y c o n c e n t r a t i o n , w e g e t : App3.8.-
0Fv
=0=AE
v-TAS~v+RTIn
Nv N L -'N v
H e r e , AEv a n d ASv a s t h e s t a n d a r d i n t e r n a l e n e r g y a n d s t a n d a r d e n t r o p y o f t h e d e f e c t s , r e s p e c t i v e l y . T h i s g i v e s u s a final r e s u l t of: App3.9.-
In
Nv_ = In X v = - AE v - T&.Sv NL- Nv
As w e
have already stated,
RT NL >>
Nv so
that
the
atomic
fraction
of
v a c a n c i e s isApp3.10.-
X v = e x p (-AF v /RT) ,~
OF:
Xv
=e
exp {-aGv / R T )
_ AE/RT
S i n c e , AGv = hFv + PAV (at c o n s t a n t p r e s s u r e ) , w e c a n t a k e t h e d e r i v i t i v e of A p p 3 . 1 0 . to o b t a i n :
127
App3.11-
0(AGv / RT} = d In AGv OT-1 dT 1
AH v R
w h i c h is a f o r m of t h e G i b b s - H e l m h o l z e q u a t i o n . Note t h a t we c a n u s e t h e s a m e s t a t i s t i c a l m e c h a n i c a l a p p r o a c h to c a l c u l a t e S c h o t t s k y p a i r s , F r e n k e l p a i r s , d i v a n c i e s (which are a s s o c i a t e d v a c a n c i e s ) , i m p u r i t y - v a c a n c y c o m p l e x e s , a n d line d i s l o c a t i o n - p o i n t d e f e c t c o m p l e x e s .
This Page Intentionally Left Blank
129
M e c h a n i s m s a n d R e a c t i o n s in t h e Solid S t a t e We have i n v e s t i g a t e d the s t r u c t u r e of solids in the s e c o n d c h a p t e r a n d t h e n a t u r e of point defects of t h e solid in t h e t h i r d c h a p t e r . We are n o w r e a d y to d e s c r i b e how solids react. T h i s will i n c l u d e t h e m e c h a n i s m s involved w h e n solids form b y r e a c t i o n from c o n s t i t u e n t c o m p o u n d s . We will also d e s c r i b e s o m e m e t h o d s of m e a s u r e m e n t a n d h o w one d e t e r m i n e s e x t e n t a n d r a t e of the solid s t a t e r e a c t i o n actually t a k i n g place. We will also s h o w how t h e p r e s e n c e
a n d / o r f o r m a t i o n of p o i n t defects affect reactivity in
solid s t a t e r e a c t i o n s . T h e y do so, b u t n o t in the m a n n e r t h a t you m i g h t s u s p e c t . We will also s h o w h o w solid s t a t e r e a c t i o n s p r o g r e s s , p a r t i c u l a r l y those
involving silicates w h e r e
several d i f f e r e n t
phases
appear
as a
function of b o t h time a n d relative ratios of r e a c t i n g c o m p o n e n t s . Solids are g e n e r a l l y c o n s i d e r e d
c h e m i c a l l y i n e r t at r o o m t e m p e r a t u r e s
a n d the m o s t c o m m o n - p l a c e e v i d e n c e is often overlooked. T h a t is, solids do not a p p e a r to be reactive until t h e y are h e a t e d . However, t h e a t o m s o r ions c o m p r i s i n g
solids are u n d e r
constant vibratory motion
with
the
lattice a n d c a n "diffuse" from site to site. If v a c a n c i e s are p r e s e n t , t h e y are c o n t i n u a l l y b e i n g "filled" a n d "emptied" even at r o o m t e m p e r a t u r e . T h o s e solids b a s e d u p o n iron (Fe) u n d e r g o c o n t i n u o u s oxidation to form a layer of "rust". T h u s , solids are n o t c o m p l e t e l y stable a n d are u n d e r c o n t i n u o u s c h a n g e over t i m e . It s h o u l d be clear by n o w t h a t inorganic solids {which c o n s i s t of a t o m s b o u n d t o g e t h e r by b o t h covalent a n d ionic forces} do n o t r e a c t by e i t h e r c h a n g i n g the b o n d i n g w i t h i n a m o l e c u l a r s t r u c t u r e or by r e a c t i n g o n e - o n one in a mobile p h a s e s u c h as a liquid, as do organic c o m p o u n d s . Solids c a n only r e a c t at t h e haterfaee of a n o t h e r solid, or in the c a s e of a liquidsolid r e a c t i o n , r e a c t w i t h the liquid m o l e c u l e at the solid i n t e r f a c e . For a solid w h i c h exists as a powder,
a useful m e n t a l c o n c e p t is t h a t of
p i n g - p o n g bails of several colors. Here, we i m a g i n e t h a t r e a c t i o n r e s u l t s w h e n the layers b e c o m e mixed. F u r t h e r m o r e , r e a c t i o n c a n only t a k e p l a c e
130
b etween neighboring balls of differing color, provided they are n e a r e s t neighbors. Thus, it should be clear t hat if we pour balls of the same color into a j a r and t h e n p o u r a n o t h e r layer of c o n t r a s t i n g color on top, r e a c t i o n can only take place at the interface of the layers, between bails of differing colors. One color can only "diffuse" into the other layer by replacing a ball of the o t h e r color. Our first step will be to delineate k n o w n solid state reaction m e c h a n i s m s . M e c h a n i s m s Relating to Solid State Reactions Phase c h a n g e s Formation of p h a s e b o u n d a r i e s Rate process c h a n g e s in solids Nucleation Diffusion p r o c e s s e s Diffusion-controlled solid state reactions. We can further separate t h e s e reaction m e c h a n i s m s into two types, t h o s e involving a single p h a s e (homogeneous) and those involving two different p h a s e s (heterogeneous). We will examine each of these in turn, s t a r t i n g with p h a s e changes. By p h a s e changes, we m e a n t r a n s f o r m a t i o n s of f o r m or s t r u c t u r e within the solid state. 4,1, - PHASE CHANGES We can distinguish seven (7) types of p h a s e t r a n s f o r m a t i o n s . For t h e h o m o g e n e o u s solid, these include the types of changes given in 4.1.1. on the next page. These seven t r a ns f or m at i ons, w h i c h involve j u s t o n e composition, are familiar to most. We t o u c h e d u p o n t h e m briefly in t h e first c h a p t e r w h e n we c o n s i d e r e d the t r a n s f o r m a t i o n s involving w at er. Now consider p h a s e c h a n g e s involving two solids and the types of r e a c t i o n m e c h a n i s m s w hi c h m a y occur. These are called h e t e r o g e n e o u s r e a c t i o n s and are p r e s e n t e d in Table 4-1, also given on the next page.
131
4.1.1.-
PHASE TRANSFORMATIONS (SINGLE PHASE) DESIGNATION
CHANGE Gas to Liquid
Condensation
G~L
Gas to Solid
Condensation
G~S
Liquid to Gas
Evaporation
L~ G
Liquid to Solid
Solidification
L~ S
Solid to Gas
Sublimation
S ~ G
Solid to Liquid
Melting
S~L
Solid to Solid
Polymorphic Transformation
S~S
TABLE 4 - I TYPES OF SOLID STATE H E T E R O G E N E O U S REACTIONS Final Product E x a m p l e of Reaction. Type of R e a c t i o n 3 AuCI ~ AuCI3 + 2 Au 1. D e c o m p o s i t i o n CaCO3 ~ CaO + C02 A~B+C N H4CI ~ N H3 ~ + HCI 2 Agl + Hgl2 ~ Ag2 HgI4
2. S y n t h e s i s A+B~C
MgO + A1203 ~ Mg•J2 04 MgO + S i 0 2
~ MgSi03
S + S
C u + AgCI ~
CuCI+ Ag
A+B~C+D
S+G
BaC03 + T i 0 2 ~
4. C o n s e c u t i v e A~ B~C
S + S
i) La203 + 11 A1203 ~
3. S u b s t i t u t i o n
Note
2 ~03
+ 10A1203
ii) 2 l_aAl03 + 10 A1203 ~ ~ 1 1 0 1 8
In b o t h 4.1.1. a n d Table 4-1, S , respectively.
BaTi03 + 0 0 2
that
we
have
L & G refer to solid, liquid a n d gas, also
classified
these
heterogeneous
m e c h a n i s m s in t e r m s of t h e s a m e PHYSICAL CHANGES given above for h o m o g e n e o u s t r a n s f o r m a t i o n s . For t h e m o s t part, t h e initial m a t e r i a l will be a solid while t h e n a t u r e of t h e final p r o d u c t will vary a c c o r d i n g to t h e type of m a t e r i a l u n d e r g o i n g solid s t a t e r e a c t i o n . Review t h e s e e x a m p l e s carefully. T h e y are typical of t h o s e e n c o u n t e r e d in solid s t a t e c h e m i s t r y . T h u s , "A" r e a c t s to f o r m "B +C" ( D e c o m p o s i t i o n ) or
132
"A + B" r e a c t s to form "C" (Synthesis"). etc. T h e s e r e a c t i o n s cover m o s t of t h o s e n o r m a l l y f o u n d in solid s t a t e c h e m i s t r y .
Once you have m a s t e r e d
t h e s e t y p e s of r e a c t i o n s , you will be able to identify m o s t solid s t a t e reactions
in t e r m s
of the r e a c t a n t s
a n d p r o d u c t s . This is i m p o r t a n t ,
especially w h e n you m a y be trying to form an new c o m p o s i t i o n n o t well k n o w n in solid state science. Addionally, you m a y w i s h to form a specific c o m p o s i t i o n by a new
method
to see
ff it h a s s u p e r i o r
physical o r
c h e m i c a l p r o p e r t i e s over t h a t s a m e m a t e r i a l f o r m e d by a different solid state m e c h a n i s m or reaction. In m a n y cases, this h a s b e e n f o u n d to be t r u e a n d this factor h a s b e e n r e s p o n s i b l e for several scientific a d v a n c e s in the solid-state. T h a t is- ff you c a n fund a different m e t h o d for m a k i n g a material, its p r o p e r t i e s m a y prove to be s u p e r i o r to t h a t already k n o w n . 4 . 2 . - T H E ROLE OF PH/~_SE BOUNDARIES IN SOLID STATE REACTIONS C o n s i d e r two (2) solids, A a n d B. It s h o u l d be obvious t h a t t h e y will r e a c t only w h e n in close proximity, a n d usually w h e n t h e y are i n t i m a t e l y m i x e d a n d h e a t e d (if t h e y are powders). What this m e a n s is i l l u s t r a t e d by t h e following d i a g r a m :
In the case w h e r e two p a r t i c l e s are involved, t h o s e t h a t are n o t in c l o s e p r o x i m i t y will not react, w h e r e a s t h o s e t h a t are close will u n d e r g o solid state r e a c t i o n with ease. This is due to the fact t h a t c a t i o n s a n d / o r a n i o n s from
one
structure
must
be
transported,
or
interchange
by
some
m e c h a n i s m , to the o t h e r s t r u c t u r e in o r d e r to form a c o m p l e t e l y n e w c o m p o u n d . T h u s , t h e degree
of d i s p e r s i o n a n d m i x i n g of one r e a c t i n g
solid w i t h a n o t h e r is i m p o r t a n t to the overall m e c h a n i s m of solid s t a t e
133
reaction. This c a n n o t be o v e r e m p h a s i z e d since lack of dispersion is the p r i m a r y cause for p r o d u c t i o n of u n w a n t e d p h a s e s (or lack of p r o d u c t i o n t h a t is, w h e n the solid state reaction
does not proceed
according to
e xp ectio n ) . As an example, c o n s i d e r the following. S u p p o s e we have a crucible halffilled with a powder. We now fill the crucible with a n o t h e r powder of different c o m p o s i t i o n and t h e n heat the Failed crucible. Any solid state reaction which does occur can only do so at the b o u n d a r y of the two layers of powders. If the reaction is: A + B ~ AB, t h e n we find t hat the r e a c t i o n product, which is also a solid, forms as a p h a s e b o u a d a l ~ b e t w e e n the two layers. The same condition exists in a solid state reaction bet w een two crystalline particles having differing compositions. That is, they can only react at the interface of each particle. This is illustrated in the following diagram, which is a model of how the c o m p o n e n t s react t h r o u g h a p h a s e boundary:
In this case, we have given b o t h the star'ring conditions and those of t h e i n t e r m e d i a t e stage of solid state reaction. It should be clear t h a t A r e a c t s with B, and vice versa. Thus, a p h a s e b o u n d a r y is formed at the interface of the b u lk of each particle, i.e.- between A and AB, and bet w een B and AB. The p h a s e boundary, AB, t h e n grows o u t w a r d as shovm above. Once the p h a s e b o u n d a r y is established, t h e n each reacting specie m u s t diffuse t h r o u g h the p h a s e {AB} to reach its opposite p h a s e b o u n d a r y in order to react. That i s - * A " m u s t diffuse t h r o u g h "AB" to the p h a s e b o u n d a r y
134
between
"AB" a n d "B" before it can r e a c t with "B" to form "AB" a n d
f u r t h e r i n c r e a s e the d i m e n s i o n s of "AB" at the e x p e n s e of b o t h "A" a n d "B'.
It
is
quite
important
that
you m a s t e r
this
concept
which
is
f u n d a m e n t a l t o w a r d s u n d e r s t a n d i n g b o t h p h a s e b o u n d a r i e s of solid s t a t e r e a c t i o n a n d diffusion c o n d i t i o n s t h a t prevail. However,
this is not h o w it o c c u r s in Nature. We have p r e s e n t e d t h e
above c o n c e p t
because
it
occur.
is
easier
Thus,
the
to
understand
overall
solid
than state
the
actual
conditions
which
reaction
is
dependent
u p o n the rate of diffusion of the two (2) species. T h e s e two
r a t e s may, or m a y not, be the same. The r e a s o n t h a t A a n d / o r B do n o t react in the middle, i.e.- the p h a s e {AB}, is t h a t AB h a s a c e r t a i n o r d e r e d s t r u c t u r e w h i c h p r o b a b l y differs from either A or B. But t h e r e is a m o r e i m p o r t a n t r e a s o n w h i c h is not easily i l l u s t r a t e d in any d i a g r a m . The actuality is t h a t any given a t o m of A d o e s n o t m o v e t h r o u g h AB to t h e p h a s e b o u n d a r y of A a n d AB. W h a t really h a p p e n s is t h a t any given a t o m displaces o n e of t h e A a t o m s in {AB}. The d i s p l a c e d A-atom t h e n c a u s e s a n o t h e r d i s p l a c e m e n t by a "hopping" m o t i o n . The s t a t e d d i s p l a c e m e n t t h e n travels to the right until the o t h e r edge of the p h a s e b o u n d a r y is e n c o u n t e r e d . There, r e a c t i o n of the final, d i s p l a c e d A - a t o m o c c u r s with a B - a t o m to form AB. S i m u l t a n e o u s l y , d i s p l a c e d B - a t o m s are diffusing to t h e left by the s a m e "hopping" m o t i o n . T h u s , the walls of {AB} move in a t h r e e - d i m e n s i o n a l direction at the e x p e n s e of b o t h of the atomic v o l u m e s of A a n d B. A d e p i c t i o n
of this m e c h a n i s m
is given in the following
diagram, given as 4.2.3. on the next page. Here,
we
have s h o w n
an "A" ion
(shown
as a b l a c k s p h e r e )
which
a p p r o a c h e s the surface of "AB" a n d displaces an "A" ion in this solid p h a s e . A series of "hops", i.e.- from "1" to "7", t h e n o c c u r s in the AB-phase w i t h the final "A" ion e n d i n g w i t h i n the B - p h a s e w h e r e a d i s p l a c e m e n t in t h e n o r m a l l y cubic "B" p h a s e occurs. At the s a m e time, the d i s p l a c e d "B" ion is diffusing in the o p p o s i t e d i r e c t i o n by a series of "hops", i.e.- from "a" to "e" to the interface of "AB" with "A". Note t h a t the "A" p h a s e is s h o w n as a h e x a g o n a l p h a s e while "B" is a cubic p h a s e (as is the "AB" phase). It s h o u l d be clear t h a t the rate of diffusion of "A" will differ from t h a t of "B".
135
Note also t h a t a c h a n g e in s t r u c t u r e h a s o c c u r r e d as the AB a r r a n g e m e n t grows. Let u s t a k e a n o t h e r example, u s i n g the s a m e type of model, in w h i c h A is a gas a n d B is a solid. A d i a g r a m i l l u s t r a t i n g this m e c h a n i s m is given as follows:
Here, only
one
i n t e r f a c e forms as the r e a c t i o n t a k e s place initially at t h e
surface of "B". Once t h e AB-phase h a s formed, g a s e o u s A a t o m s m u s t t h e n diffuse t h r o u g h to the p h a s e b o u n d a r y in o r d e r for the r e a c t i o n to o c c u r . T h e wall of {AB} t h u s m o v e s in two (2) d i m e n s i o n s i n s t e a d of t h e t h r e e , in c o n t r a s t to the c a s e of 4 . 2 . 2 . C o n s i d e r a n o t h e r e x a m p l e involving difflasion a n d reactivity, s u c h as t h e r e a c t i o n b e t w e e n p a r t i c l e s of:
136
4.2.5.-
BaO + SiO2 =~, BaSiO3
In t h i s case, t h e s t r u c t u r e of BaO c o n s i s t s of d i s c r e t e a t o m s of 139_2+ a n d 0 = , a r r a n g e d in a c u b i c s t r u c t u r e . S i 0 2 , o n t h e o t h e r h a n d , c o n s i s t s of S i 0 4 tetrahedra
bound
at
the
apices
through
mutual
oxygen
atoms,
and
a r r a n g e d in a t h r e e - d i m e n s i o n a l n e t w o r k . T h i s is s h o w n in t h e f o l l o w i n g diagram:
We Find t h a t t h i s solid s t a t e r e a c t i o n is v e r y slow, even at 8 0 0 ~
, and
o c c u r s at t h e i n t e r f a c e of t h e two t y p e s of p a r t i c l e s . T h e r e a c t i o n is s l o w b e c a u s e it is d i f f u s i o n - l i m i t e d . W h a t is h a p p e n i n g is t h a t s i n c e t h e silican e t w o r k is t h r e e - d i m e n s i o n a l l y b o u n d , t h e ozfly re.action t h a t o c c u r s is c a u s e d b y t h e diffusion of Ba2+ a t o m s w i t h i n t h e n e t w o r k , as s h o w n in t h e following:
137
Note
that
diffusion o c c u r s
only in o n e
d i r e c t i o n b e c a u s e the
silica-
t e t r a h e d r a are n o t free to m o v e . What is actually h a p p e n i n g is t h a t t h e three-dimensional
network
of t e t r a h e d r a
is being r c a r r t m g e d to f o r m
a n o t h e r s t r u c t u r e . This i l l u s t r a t e s the fact t h a t the actual s t r u c t u r e a n d composition
of t h e
two
reacting
species
are
the
major
factor
in
d e t e r m i n i n g the n a t u r e a n d s p e e d of the solid state r e a c t i o n . On the o t h e r h a n d , if we u s e BaC03 as a r e a c t a n t , vis: 4.2.8.-
BaC~3 + Si02 ~ BaSiO3 + CI~)2 II
we find t h a t the r e a c t i o n is very fast. This h a s n o t h i n g to do w i t h t h e g a s e o u s CID2 p r o d u c e d , b u t w i t h the form of the BaO particles. In t h i s case, the initial r e a c t i o n is: 4.2.9.-
BaC03 ~
BaO + O32
The BaO is p r o d u c e d in the form of very small p a r t i c l e s of n e a r l y a t o m i c p r o p o r t i o n s w h i c h r e a c t i m m e d i a t e l y to form the tdlicatr rate of r e a c t i o n is p r o p o r t i o n a l to the n u m b e r of a u r
Actually, t h e
produced per unit
volume. A n u c l e u s is a p o i n t w h e r e a t o m s or ions have r e a c t e d a n d b e g u n the f o r m a t i o n of the p r o d u c t s t r u c t u r e . In the c a s e of the BaO r e a c t i o n , the n u m b e r of nuclei f o r m e d per u n i t of time is small a n d f o r m a t i o n of the s t r u c t u r e is difl~asion limited. In the case of Ba(X)3 d e c o m p o s i t i o n , t h e a t o m i c - p r o p o r t i o n e d BaO r e a c t s n e a r l y as fast as it is f o r m e d so t h a t t h e n u m b e r of nuclei p e r u n i t v o l u m e is e n o r m o u s l y i n c r e a s e d .
It is t h u s
a p p a r e n t t h a t if we w i s h to i n c r e a s e solid state r e a c t i o n rates, one way to do so is to u s e a d e c o m p o s i t i o n r e a c t i o n to s u p p l y the r e a c t i n g s p e c i e s . we will f u r t h e r a d d r e s s this type of r e a c t i o n later on in o u r d i s c u s s i o n . Note
also t h a t we
have j u s t i n t r o d u c e d
the
concepts
n u c l e a t i o n in o u r s t u d y of solid state r e a c t i o n p r o c e s s e s .
of nuclei
and
Our next s t e p
will be to e x a m i n e s o m e of the m a t h e m a t i c s u s e d to define r a t e p r o c e s s e s in solid state r e a c t i o n s . We will not delve into the p r e c i s e e q u a t i o n s h e r e b u t p r e s e n t t h e m in A p p e n d i c e s at the e n d of this c h a p t e r . But first, w e n e e d to e x a m i n e r e a c t i o n rate e q u a t i o n s as a d a p t e d for t h e solid state.
138
4.3.-
REACTION RATE P R O C E S S E S IN SOLIDS
As s t a t e d
above, we c a n classify solid s t a t e r e a c t i o n s
as b e i n g
either
h o m o g e n e o u s or h e t e r o g e n e o u s . T h e f o r m e r involves r e a c t i o n s by a s i n g l e c o m p o u n d w h e r e a s t h e l a t t e r involves r e a c t i o n s b e t w e e n
two d i f f e r e n t
c o m p o u n d s . As s t a t e d above in Table 4-1, t h e r e are four (4) t y p e s of s o l i d state reactions. 4.3.1.-
T w e s of Solid S t a t e R e a c t i o n s I. D e c o m p o s i t i o n :
A~B+C
2. S y n t h e s i s :
A+B~C
4. S u b s t i t u t i o n a l :
A+B~C+D
4. C o n s e c u t i v e :
A~B~C
Rate p r o c e s s e s for t h e solid s t a t e are g e n e r a l l y d e f i n e d in t e r m s of a r a t e , r, a n d a v o l u m e , V, usually a m o l a r v o l u m e . T h u s , we have: 4.3.2.-
Homogeneous:
r = d n i / d t - 1/Vt
Heterogeneous:
r = d V t / d t 9 1/Vf
w h e r e ni is initial m o l e s , Vt is v o l u m e at time, t, a n d Vf is final v o l u m e . The
r e a s o n t h a t t h e s e e q u a t i o n s differ is t h a t a r e a c t i o n
between
two
s o l i d s m a y p r o p a g a t e a fim~ product h a v i n g a l a r g e r or s m a l l e r v o l u m e t h a n t h a t of t h e original r e a c t i n g species, w h i l e t h a t of a s i n g l e compound r e m a i n s ~ l b l e . If w e define t h e f r a c t i o n d e c o m p o s e d at a n y t i m e as: 4.3.4.-
x - Vt / Vf
We c a n e x p r e s s t h e s e v o l u m e s in t e r m s of x so as to get: 4.3.5.-
d x / d t = k l (T) 9f(x)
w h e r e k l is t h e r a t e c o n s t a n t for t h e e q u a t i o n in 4 . 3 . 4 . a n d f(x) r e l a t e s to
139
the definition given in 4.3.2. This e q u a t i o n , i.e.-4.3.5., t h e n h a s the s a m e general form as t h o s e u s e d in the s t u d y of k i n e t i c s of c h e m i c a l r e a c t i o n s . F r o m t h e Kinetic Theory, w h e n a g a s e o u s s y s t e m goes from an initial s t a t e to a fmal state, t h e r e a c t i n g species m u s t c o m e close e n o u g h to react. At the m o m e n t of "joining", we have the "activated complex". By u s i n g t h i s concept, we can o b t a i n s o m e g e n e r a l e q u a t i o n s useful to us. The c o n c e p t of the "activated complex" is i l l u s t r a t e d in t h e following diagram:
It is easy to see t h a t the free e n e r g y of the activated complex,
G*, is
h i g h e r t h a n t h a t of t h e initial state. K* is the e q u i l i b r i u m c o n s t a n t of t h e activated complex, a n d k is the B o l t z m a n n c o n s t a n t . Then, we c a n w r i t e e q u a t i o n s d e s c r i b i n g b o t h AG a n d the activated state as: 4.3.7.-
AG = R T I n K * k l = k T / h exp.(-AG*/RT)
where
= k T / h exp.(AS*/R) e x p . ( - A H * / R T )
the s t a r (*) refers to the activated species.
F r o m the Clausius-
Clapyeron equation, we have: 4.3.8.-
Eo - R T 2 d(In kl) / dt = AH* + R T
w h e r e Eo is an i n t e r n a l energy. By defining a f r e q u e n c y factor as:
140
4.3.9.-
Z
= k T / h exp ( - E o * I R T )
We c a n s i m p l y e x p r e s s t h i s r e s u l t s i m i l a r to t h a t of 4 . 3 . 7 . to obtain: 4.3.10.-
kl
= Z exp. ( - E o * / R T )
w h i c h is t h e A R R H E N I U S EQUATION for t h e r a t e c o n s t a n t , k l. We c a n
general
t r a n s f o r m t h e above e q u a t i o n s into
e q u a t i o n s as well,
and use
t h e m to define t h e v a r i o u s t y p e s of r e a c t i o n s given above, n a m e l y : 4.3.11.-
RATE EQUATIONS FOR SOLID STATE R E A C T I O N S Simple nth.0rder kI nA ~ B
.Rate E q u a t i o n -dXA / d t = k l xn A
Parallel R e a c t i o n s kl k2 { A ~ B} a n d { A
Rate Equation - d x A / d t = k l X A + k 2 XA
~C}
Consecutive kl k2 A ~B
Rate Equation -dxA/dt = klXA
~C
- k2xB
T h r e e t y p e s of r a t e e q u a t i o n s a r e s h o w n h e r e . T h e s e r a t e e q u a t i o n s c a n b e used
for
quite
measurement
complicated
approach
is
reactions,
needed.
How
but we
a
specific do
this
method is
critical
or to
d e t e r m i n i n g a c c u r a t e e s t i m a t i o n of t h e p r o g r e s s of a solid s t a t e r e a c t i o n . We will d i s c u s s s u i t a b l e m e t h o d s
in a n o t h e r c h a p t e r . We n o w r e t u r n to
t h e s u b j e c t of n u c l e a t i o n so t h a t we c a n a p p l y t h e r a t e e q u a t i o n s g i v e n above to specific c a s e s . First, we e x a m i n e h e t e r o g e n e o u s p r o c e s s e s . 4 . 4 . - DEFINING H E T E R O G E N E O I I S NUCLEATION P R O C E S S E S If we are i n t e r e s t e d in t h e n u c l e a t i o n of a p a r t i c l e p r i o r to c o m p l e t i n g t h e solid s t a t e r e a c t i o n , we n e e d to d i s t i n g u i s h b e t w e e n s u r f a c e a n d v o l u m e n u c l e a t i o n of t h e p a r t i c l e , s i n c e t h e s e a r e t h e m a j o r m e t h o d s of w h i c h w e c a n p e r c e i v e . S e v e r a l c a s e s a r e s h o w n in t h e following d i a g r a m .
141
In this diagram, we classify t h e various t y p e s of h e t e r o g e n e o u s solid s t a t e r e a c t i o n s t h a t c a n occur. Note t h a t b o t h t r a n s f o r m a t i o n to solid a n d fluid p r o d u c t s are diagramn-led. Also s h o w n are v a r i a t i o n s w h e r e surface a n d / o r v o l u m e n u c l e a t i o n is involved. W h e n solids r e a c t a n d n u c l e a t i o n is the n o r m , t h e y do so either by surface
142
or v o l u m e n u c l e a t i o n . Model B involves surface nucleation w h e r e i n surface b e c o m e s
n u c l e a t e d in one spot, i.e.- two r e a c t i n g
particles
the in
close proximity. This is s h o w n in 4.4.2. Here, two t o u c h i n g p a r t i c l e s have i n i t i a t e d g r o w t h of a n o t h e r p h a s e by n u c l e a t i n g at t h e point w h e r e e a c h particle t o u c h e s the o t h e r . 4.4.2.- Model B w h e r e R e a c t i o n Only T a k e s Place at the Point W h e r e Two Particles T o u c h
As s h o w n
in 4.4.1.,
two
stages
usually o c c u r
in
surface
nucleation,
n u c l e a t i o n a n d t h e n nuclei growth. If surface n u c l e a t i o n is fast (Model C) it is likely d u e to r e a c t i o n of a gas with the solid particle. The r e a c t i o n of a liquid is the o t h e r possibility, i.e.4.4.3.-
AS + BG ~ (AB)s AS + BL ~ (AB)s
If it slow, t h e n n u c l e a t i o n is likely to be due solely to proximity. Model D is an e x a m p l e of volume nucleation w h e r e d e c o m p o s i t i o n
of a solid is
involved w h e r e a s Model E is t h a t involving gas or liquid n u c l e a t i o n of t h e solid. Note t h a t if n u c l e a t i o n does not occur, the solid r e a c t s u n i f o r m l y t h r o u g h o u t its whole v o l u m e (Model F). However, this m o d e is r a r e a n d the n u c l e a t i o n stages are m o r e likely to occur. We will not dwell u p o n h o w t h e s e n u c l e a t i o n m o d e l s w e r e derived a n d will only p r e s e n t the r e s u l t s here.
One is r e f e r r e d
to A p p e n d i x
I
wherein
one
m a t h e m a t i c s u s e d to obtain t h e n e t - r e s u l t . The factors t h a t we m u s t c o n s i d e r i n c l u d e the following: I) The f o r m a t i o n of an i n c i p i e n t embryo, E 2) N u m b e r s of e m b r y o s w h i c h f o r m 3) The g r o w t h of the e m b r y o into a n u c l e u s , N
can
study the
143
4) G r o w t h of n u c l e i 5) Grow~h a n d t r a n s f o r m a t i o n of nuclei into t h e final p r o d u c t of t h e solid s t a t e r e a c t i o n by f o r m a t i o n of p h a s e b o u n d a r i e s . W h a t we m e a n by an e m b r y o is s h o w n in the following d i a g r a m w h e r e i n the d i m e n s i o n s are d i s t o r t e d from the actual case in o r d e r to i l l u s t r a t e our point.
In this case, we m u s t differentiate
between
the
walls of the
rapidly
forming e m b r y o a n d t h o s e of t h e i n c i p i e n t n u c l e u s . T h i s d r a w i n g s h o w s the f o r m a t i o n of an e m b r y o E , w h i c h t h e n grows into a n u c l e u s , N, w i t h i n the crystallite volume, A (none are d r a w n to scale). T h e c h a n g e in f r e e e n e r g y in going from B to A win be a function of b o t h v o l u m e a n d surface a r e a (shape). We m u s t d i s c r i m i n a t e b e t w e e n t h e interfacial surface e n e r g y between
B a n d A, a n d t h e i n t e r n a l e n e r g y of C. T h e n u c l e u s , N, t h e n
grows by e x p a n d i n g its walls to form a n e w s t r u c t u r e ( c o m p o u n d ) .
We
note t h a t the g r o w t h of nuclei is a s s o c i a t e d with the m o t i o n of a p h a s e b o u n d a r y , as d e s c r i b e d above. We will n o t give the m a t h e m a t i c s involved h e r e b u t r e s e r v e t h e m for A p p e n d i x II at t h e e n d of this c h a p t e r . However, we n e e d to point o u t t h a t the r a t e of n u c l e a t i o n , I, is defined as:
144
4.4.5.-
I - N u m b e r of n u c l e i / U n i t t i m e / U n i t v o l u m e
a n d x d t is t h e g r o w t h
r a t e of t h e nuclei, as in 4 . 4 . 4 . T h e
final r e s u l t
involves: 4.4.6.which
rcrit is
required
the
= - 2 Y / AGv equation
G~bs-Thompson
defining
the
critical
radius
for a n e m b r y o to form. We also c a n r e l a t e t h e s e e q u a t i o n s to
n u m b e r s of n u c l e i b e i n g f o r m e d a n d t h e i r g r o w t h . T h i s is i l l u s t r a t e d as follows in 4 . 4 . 7 . , given o n t h e n e x t p a g e . In t h e s i m p l e case, B g r o w s at t h e e x p e n s e of A. However, in t h e s e c o n d c a s e involving p a r a l l e l r e a c t i o n s , t w o e m h r y c m f o r m f r o m A. I n t h e t h i r d case, at l e a s t two s t e p s are involved in t h e
two c o n s e c u t i v e
reactions
w h e r e "A" t r a n s f o r m s to "B" w h i c h t r a n s f o r m s to "C". In T a b l e 4-2, we controlled
show both phase-boundary controlled
a n d diffusion-
n u c l e a t i o n r e a c t i o n s as a f u n c t i o n of b o t h c o n s t a n t a n d z e r o
rate of nucleation.
TABLE 4 - 2 NUCLEATION AS A FUNCTION OF T H E SHAP_E FACqY)R, 0 DIFFUSION CONTROLLED [ ~ {t) = D I t ]
PHASE BOUNDARY CON'I~OLLED [ ~ {t) = k2 t r ] 0
r
Constant Rate spheres
E
r
E
4
3 E2 + E1
2.5
3 / 2 ED + E1
3
2 E2 + E1
2.0
E2 + ED
2
E2 + E l
4
3 E2
1.5
3
2 E2
1.0
of N u c l e a t i o n ,,
plates needles i
Zero
Rate
ii
of s p h e r e s
1.5
1.5 ED + E1 i
1.5 ED
Nucleation plates needles i
2 jl
i
E2 iii
i
0.5
ED 0.5 ED
i
145
R e f e r r i n g to 4.4.4. a n d Table 4-2, we see t h a t the s h a p e factor, 0, h a s a m a j o r effect u p o n r a n d t h e e x p o n e n t of time, activation energies. E1 is the activation e n e r g y w h e r e a s E2 is t h a t for n u c l e i g r o w t h . ED
t, as well as on t h e for nuclei f o r m a t i o n ,
is t h e activation e n e r g y for
d i t I u ~ o n g r o w t h . Note t h a t w e have n o w directly a s s o c i a t e d diffusion as a m e c h a n i s m in nuclei f o r m a t i o n a n d t h a t we h a v e a l r e a d y given e x a m p l e s
146
above c o n c e r n i n g solid state r e a c t i o n m e c h a n i s m s c o n c e r n i n g
diffusion
(see 4.2.2 for e x a m p l e ) . Actually, t h e r e
are t h r e e
in
(3) m a j o r classifications for nuclei g r o w t h
h e t e r o g e n e o u s solid state reactions. Restating, t h e s e are: 4.4.8.-
Phase-boundary Controlled Random Growth Diffusion C o n t r o l l e d
We have already dealt with two of these. Section 2 dealt with f o r m a t i o n of a p h a s e b o u n d a r y while we have j u s t c o m p l e t e d
Section 4 c o n c e r n i n g
nuclei g r o w t h as r e l a t e d to a p h a s e b o u n d a r y . We will c o n s i d e r diffusion m e c h a n i s m s in nuclei a n d d i f f u s i o n - c o n t r o l l e d solid state r e a c t i o n s at a later p a r t of this c h a p t e r . T h e s e are areas of solid state c h e m i s t r y w h e r e c o n s i d e r a b l e e x p e r i m e n t a l w o r k h a s already b e e n a c c o m p l i s h e d , p a r t i c u l a r l y in the a r e a of t a r n i s h i n g b e c a u s e of t h e obvious c o m m e r c i a l i n t e r e s t in s u c h r e a c t i o n s . We are n o w r e a d y to c o n s i d e r s o m e solid state r e a c t i o n s t h a t relate m o r e directly to the real world.
These
include the t a r n i s h i n g r e a c t i o n
and
Fick's Laws of Diffusion. Both of t h e s e scientific areas have b e e n r i g o r o u s l y studied
because
of
their
importance
in
revealing
how
diffusion
m e c h a n i s m s are r e l a t e d to everyday solid state r e a c t i o n s w h i c h o c c u r on a daily basis. 4 . 5 , THE TARNISHING REACTION In 1902, W a g n e r p u b l i s h e d an analysis, b a s e d on diffusion r e a c t i o n s , of t h e oxidation of the surface of a metal. His i n t e r p r e t a t i o n
has remained
a
classic in solid state diffusion analysis. The surface of a m e t a l c o n s i s t s of m e t a l a t o m s b o u n d to the i n n e r s t r u c t u r e by a series of h y b r i d - b o n d s . If oxygen gas is p r e s e n t (air), the m e t a l can form an oxide coating: 4.5.1.-
M + 1/202
~
MO
147
In s o m e cases, the o x i d e - c o a t i n g p r o t e c t s the surface from f u r t h e r o x i d e buildup. One e x a m p l e is t h a t of a l u m i n u m w h e r e an oxide coating a p p e a r s a l m o s t i n s t a n t a n e o u s l y once the p r i s t i n e
surface is e x p o s e d to air. Yet,
t h e r e are m a n y c a s e s w h e r e the oxide layer c o n t i n u e s to b u i l d u p until t h e m e t a l is totally c o n s u m e d (One e x a m p l e is t h a t of iron a n d "rust"). How is this possible?
Wagner hypothesized
that both
metal
and
oxide
ions
d i f f u s e d Lhrough the m e t a l oxide layer so as to build u p the layer t h i c k n e s s f r o m b o t h s i d e s . The following d i a g r a m is one r e p r e s e n t a t i o n of s u c h a
mechanism:
In this case, the partial p r e s s u r e , p, of oxygen gas is a limiting factor in the overall r e a c t i o n to form the oxide film, MO, w h o s e t h i c k n e s s , x, is shown. It s h o u l d be a p p a r e n t , from the above diagram, t h a t t h e m o r e x i n c r e a s e s , the slower will be the c h a n g e in the x - d i m e n s i o n (since it t a k e s longer for the ions to diffuse), i.e.4.5.3.-
dx/dt
~ 1/x
or: d x / d t = K - 1 / x
The i n t e g r a t e d form is: x 2 = Kt + C , or: x = D AFt, w h e r e D is t h e Diffusion Coefficient. DiI~on.
Equation
4.5.3.
is called
the
Pal~lic
Law of
If the g r o w t h of a p h a s e can be fitted to this equation, t h e n it is
likely t h a t the p r i m a r y r e a c t i o n m e c h a n i s m involves simple diffusion.
148
Diffusion m e c h a n i s m s involve the following defect reactions: 4.5.4. -
I n t e r c h a n g e of A t o m s Vacancy Hopping Interstitial M o v e m e n t Dissociative E x c h a n g e
We have already d i s c u s s e d m o s t of t h e s e m e c h a n i s m s . In the first, Mx a n d XM i n t e r c h a n g e m a y be involved, w h e r e a s the last involves a m e c h a n i s m similar to t h a t given in 4.2.2. Note t h a t the s e c o n d type will only a p p e a r only if the individual ions involved are
small e n o u g h to fit into
the
i n t e r s t i c e s of the lattice. 4 . 6 . - FICK'S LAWS OF DIFFUSION About 1942, Fick f o r m u l a t e d laws w h i c h d e s c r i b e d diffusion p r o c e s s e s in solids, similar to t h a t already p r e s e n t e d for the t a r n i s h i n g reaction.
To do
this, Fick h y p o t h e s i z e d t h a t a t o m s (ions) w o u l d "hop" f r o m site to site in the m a n n e r we have already d e s c r i b e d in 4.2.2. a n d 4 . 2 . 4 . C o n s i d e r a lattice having a t h r e e - d i m e n s i o n a l set of planes. If we have t h i s t h r e e - d i m e n s i o n a l lattice, it is easy to see t h a t t h e r e are six (6) ways for an a t o m (ion) in the x - p l a n e to move to the y-plane. T h i s is s h o w n in t h e following illustration, given as 4.6.1. on the next page. By defining nA as the n u m b e r of A a t o m s p r e s e n t per u n i t volume, z as t h e time of stay at any given site, 1/~ as the f r e q u e n c y of j u m p s a n d J x ~ y
as
the n u m b e r of j u m p s per u n i t time, Fick w a s able to derive two laws r e g a r d i n g diffusion in solids. To do this, he also defined: I - N u m b e r of n u c l e i / U n i t t i m e / U n i t volume. Using his definitions, we c a n derive a series of e q u a t i o n s w h i c h r e s u l t s in Fick's First Law of D i i ~ s i o n .
149
T h e d i a g r a m given above d e f i n e s t h e p a r a m e t e r s
n e c e s s a r y to define t h e
e q u a t i o n s . How t h i s is d o n e is s h o w n in T a b l e 4-4, given o n t h e n e x t p a g e , w h e r e t h e i n d i v i d u a l s t e p s n e c e s s a r y are s e t f o r t h . T h e r e s u l t is: 4.6.2.-
FICK'S F I R S T LAW:
J = - D dc/dx
w h e r e J is t h e as t h e total n u m b e r diffusion coefficient
for
the
process.
of j u m p s If s u c h
that occur, exists,
a n d D is t h e
then
dc/dx
,
a
c o n s t a n t , a n d we m u s t t h e n s u b t r a c t two d i f f e r e n t j u m p r a t e s , i.e.4.6.3.-
J1 -J2
=-AxdJ/dx=-~x{dc/dt)
If t h e l a s t t e r m is t a k e n o n l y
in r e s p e c t
to t h e x d i m e n s i o n ,
then we
arrive at t h e s e c o n d law, viz4 . 6 . 4 . - FICK'S SECOND LAW: [0c/0tlx = 0 {D 0c/0x} or ( 0 c / 0 t } x = D ( 0 2 c / 0 x 2)
150
Table 4-4 H o w F i c k ' s F i r s t L a w of D i f f u s i o n Is D e r i v e d Ste: 1.
Here
we
terms
have defined
of
the
E q u a t i o n s l e a d i n g to F i c k ' s L a w s in Jx~y = 1 / 6 - 1 / T ( n A R . a ) possible
Jx
number
--
of
y
" j u m p s " , i.e.- 1 o u t of 6 w a y s , T - t h e time
that
numbers
it
takes
to
do
of a t o m s p r e s e n t
cross-sectional
so,
the
and
the
a r e a of t h e l a t t i c e i n
question. .
We then define the concentration
o f nAty)
= nA + a d n A / d x
A - a t o m s in t h e y - p l a n e to b e : .
.
C o m b i n i n g t h e s e t w o e q u a t i o n s g i v e s J x ~ y = {nA + a dnA I d x ) ( a R l 6T) us: If
we
assume
that
the
J
opposite
=
Jx~
y
-
Jy~
x
d i r e c t i o n of h o p p i n g is also valid, i.e.- J y__, x , t h e n w e h a v e : .
U s i n g J as t h e t o t a l n u m b e r
of j u m p s
J = aR/6~(nAnA+adnA/dx-aR/6)
t h a t o c c u r , w e c o m e to: .
We now define a diffusion coefficient "D"
.
=-a
D-
2 R / 6~ 9 d n A / d X
a2/6T
as:
If w e h a v e t h e i n t e r s t i t i a l 4.6.3.)., which
then is
we
must
the number
c a s e ( s e e D ------ a a 2 / "I: ( i n t e r s t i t i a l ) (z,
include
of i n t e r s t i c e s
in t h e l a t t i c e : I
.
9.
+ 10.
J
T h i s g i v e s us:
=-DRdnA
/dx
If w e n o w d e f i n e c o n c e n t r a t i o n in dc/dx = R dnA/dX t e r m s of n A , i.e.- c ---- RnA , so t h a t : then
we get FICK~
F i r s t Law:.
J
= - D dc/dx
................... i ......................................................................................................................... ; ........................................................................................................
(Note t h a t p a r t i a l d i f f e r e n t i a l s a r e u s e d in t h e 2 n d L a w (see 4 . 6 . 4 . above) s i n c e t h e y r e l a t e o n l y to t h e "x" d i m e n s i o n -
given
similar equations may
151
be derived for t h e "y" a n d "z" d i m e n s i o n s ) . Both of t h e s e Laws are u s e d e x t e n s i v e l y in solid s t a t e c h e m i s t r y . We c a n also s h o w t h a t t h e diffusion coefficient, D, u s e d in t h e s e Laws is t e m p e r a t u r e d e p e n d e n t , a n d c a n fit it to an A r r h e n i u s e q u a t i o n : 4.6.5.-
D = Do exp - E / k T
S o m e t i m e s , a m o r e useful t e r m is: 4.6.6.-
ED = - k l d(InD) / d ( 1 / T )
w h e r e ED is t h e diffusion e n e r g y involved in t h e p r o c e s s . However, t h e s e e q u a t i o n s are only u s e d w h e n t h e Fick E q u a t i o n s fail to fit t h e diffusion d a t a o b t a i n e d . It is possible to also s h o w t h a t t h e diffusion p r e s e n t in any c o m p o u n d is d i r e c t l y r e l a t e d to t h e f u n d a m e n t a l (zero p h o n o n line) of t h e lattice. The derivation is given in A p p e n d i x III. at t h e e n d of t h i s c h a p t e r . 4 . 7 . - DIFFUSION M E C H A N I S M S To this point, vce have e x a m i n e d diffusion g r o w t h in t e r m s of n u c l e a t i o n a n d e m b r y o f o r m a t i o n . Let u s n o w explore t h e actual s p e c i e s w h i c h diffuse in t h e l a t t i c e . WE WILL FIND THAT .aLL DIFFUSION MOTION OCCURS BY D E F E C T MOVEMENT
IN THE LATTICE .
C o n s i d e r t h e following d i a g r a m , given as 4.7.1. on t h e n e x t page, s h o w i n g two t y p e s of self-diffusion. mechanisms,
Self diffusion
vacancy and interstitial.
can occur
by at least
Both are "hopping"
two
motions,
as
is t h a t one site is e x c h a n g e d
for
d e s c r i b e d above. W h a t we see is in b o t h m e c h a n i s m s
a n o t h e r b y t h e defect u n d e r g o i n g a "jump" in t h e lattice n e t w o r k .
152
4.7.1.-
IMECHANISMS OF SELF-DIFFUSION
[INTERSTITIAL]
[VACANCY J
XXXX X X X X X X-if] X XXXX
XXXX XXXX
XX~X XX_ ~ x~xXX XX
XXXX
X X X X
X X X X
B E FO RE
AFTE R
xI-IX x
B E FO RE
I
X
AFTE R
Actually, we m u s t a c c o u n t for all t y p e s of defects,
X
including
charged
s p e c i e s (see 2.2.1.). To do this, let u s r e c o n s i d e r t h e t a r n i s h i n g r e a c t i o n (Section 4 , 5 , given above), u s i n g t h e g e n e r a l e q u a t i o n : 4.7.2.-
M + 1 / 2 X 2 =,, MX
S u c h a r e a c t i o n w o u l d o c c u r if we e x p o s e d
a m e t a l s u r f a c e to e i t h e r
oxygen or chlorine. A MX film w o u l d b u i l d u p on t h e m e t a l s u r f a c e a n d g r o w t h of a trim w o u l d o c c u r by diffusion. In t h e initial d e s c r i p t i o n , w e i g n o r e d v a c a n c y a n d i n t e r s t i t i a l diffusion a n d p r e s e n t e d only t h e c h a r g e d p a r t i c l e s , M 2+ a n d O = as t h e diffusing s p e c i e s (see s e c t i o n 4.5.). In actuality, t h e m e t a l diffuses as t h e i n t e r s t i t i a l , Mi 2+, a n d t h e a n i o n as Oi = . One w o u l d e x p e c t
that r
a m o u n t s of e a c h s p e c i e
w o u l d diffuse in
opposite directions, thus preserving electroneutrality. While t h i s m a y be t r u e for t h e r e a c t i o n in 4.7.2., i.e. - Mi 2+ r
Xi =, w h a t of
t h e c a s e for BaSiO3 w h e r e diffusion w a s l i m i t e d to one d i r e c t i o n ? It is n o t r e a s o n a b l e to a s s u m e t h a t t h e solid w o u l d build u p a c h a r g e as t h e Mi 2+ ions are diffusing (and t h e SiO4 = ions are not) a n d we m u s t s e a r c h for compensating species elsewhere. o c c u r s by diffusion of c h a r g e d ~ d r
It t u r n s o u t t h a t c h a r g e c o m p e n s a t i o n in t h e l a t t i c e .
To i l l u s t r a t e this, let us u s e t h e r e a c t i o n diagram:
in 4.7.2.
a n d t h e following
153
In this
diagram,
we
have s h o w n
both
charged
ions involved
in t h e
m i g r a t i o n a l d i f f u s i o n p r o c e s s as well as c h a r g e d v a c a n c i e s w h i c h also a d d to
the
overall
diffusion
process.
We m u s t
have
electroneutrality
in
diffusion, i.e.- p a i r s of d e f e c t s , a n d u s i n g the above example, we c a n w r i t e
nine e q u a t i o n s , of w h i c h the following is j u s t o n e case: 4.7.4.-
Mi + ~
Xi-
Here, two i n t e r s t i t i a l s are in equilibrium. We c a n also write
equations
involving c h a r g e only, or v a c a n c y plus c h a r g e d species. However, we have not c o n s i d e r e d r a t e s of diffusion in o u r model. In the BaSi04 case, t h e Ba2+will be very fast while the silicate ion will diffuse very slow (if at all). B e c a u s e of t h e vast differences in t h e t y p e s of diffusing species, t h e r e is no r e a s o n to e x p e c t all of t h e m to diffuse at t h e s a m e rate, p a r t i c u l a r l y w h e n we c o m p a r e e l e c t r o n s a n d vacancies. Actually, this a s p e c t of solid s t a t e r e a c t i o n h a s b e e n s t u d i e d in g r e a t detail a n d t h e K i r c h e n d a l l Effect deals w i t h this a s p e c t . To u n d e r s t a n d this effect, c o n s i d e r the following.
S u p p o s e we have a
s i t u a t i o n w h e r e A r e a c t s w i t h B to form a solid solution, AB. Let u s f u r t h e r s u p p o s e t h a t the diffusion r e a c t i o n is: 4.7.5.-
Ai + V A
~=> Bi + V B
T h u s , the v a c a n c i e s m i g r a t e along w i t h t h e i n t e r s t i t i a l a t o m s {ions)
154
in b o t h directions. In o u r case, we will ignore c h a r g e d species to simplify o u r explanation. Let us also s u p p o s e t h a t the v a c a n c i e s m i g r a t e
much
faster t h a n the interstitials a n d that: 4.7.6.-
DVA >> DVB
so that:
d c v A / d t >> dCvB/dt
Given t h e s e r e s t r a i n t s , we obtain a r a t h e r q u e e r result. This is i l l u s t r a t e d in the following diagram:
What we find is t h a t the difference in diffusion m e c h a n i s m s gives rise to the c r e a t i o n of n e w aite~ a c r o s s the diffusion zone a n d actually c a u s e s a d e f o r m a t i o n in the solid b e c a u s e the VA defects pile u p a n d finally b e c o m e a n n i h i l a t e d b e c a u s e of clustering. Acttml h o l e s a p p e a r in the solid due to vacancy diffusion. Note t h a t in this case, we are not f o r m i n g a newcompound
through
solid state
reaction,
b u t are
forming
a solid
solution of A a n d B. The K i r c h e n d a l l Effect h a s b e e n o b s e r v e d m a n y t i m e s , b u t o c c u r s m o s t often in r e a c t i o n s b e t w e e n m e t a l s w h i c h form alloys. T h e r e are t h r e e
(4) types of d i f f u s i o n - c o n t r o l l e d r e a c t i o n s possible for
h e t e r o g e n e o u s solid state r e a c t i o n s , viz4.7.8.-
TYPES OF DIFFUSION REACTIONS Simple Diffusion:
~l = k l
(t) 1/2
P h a s e - B o u n d a r y Controlled
~=k2
t
Material T r a n s p o r t
155
For s i m p l e
diffusion-controlled
reactions,
we
can
show
the
following
holds: 4.7.9.where
x 2 = 2 D Co t V M + (a) I/2 Co
= concentration
of c o n s t i t u e n t s at i n t e r f a c e ;
V = v o l u m e of
p r o d u c t AB p e r m o l e of r e a c t a n t s ; a = s u r f a c e layer t h i c k n e s s at i n t e r f a c e w h e n t = 0. It is also well to n o t e t h a t t h e final v o l u m e of t h e p r o d u c t , AB, m a y n o t be t h e s a m e as t h a t of t h e r e a c t a n t s vis.-
For p h a s e - b o u n d a r y c o n t r o l l e d r e a c t i o n s , t h e s i t u a t i o n differs s o m e w h a t . Diffusion of s p e c i e s is fast b u t t h e r e a c t i o n is slow so t h a t t h e diffusing s p e c i e s pile up. T h a t is, t h e r e a c t i o n to r e a r r a n g e t h e s t r u c t u r e is slow i n relation
to t h e
arrival of t h e
diffusing i o n s or a t o m s . T h u s ,
a phase-
b o u n d a r y (difference in s t r u c t u r e ) focus exists w h i c h c o n t r o l s t h e overall r a t e of solid s t a t e r e a c t i o n . T h i s r a t e m a y be d e s c r i b e d by: 4.7.10.-
d x / d t = k l ( s t / V o ) - ( I - ( l - x ) n ) = k i t /to
w h e r e st = i n s t a n t a n e o u s s u r f a c e area; Vo = original v o l u m e of p a r t i c l e s r e a c t i n g ; ro = original r a d i u s of p a r t i c l e s ; a n d n = 1, 1 !2, 1 / 3 for a 1d i m e n s i o n a l , 2 - d i m e n s i o n a l , or 3 - d i m e n s i o n a l r e a c t i o n . Material t r a n s p o r t f r e q u e n t l y involves a n e x t e r n a l g a s e o u s p h a s e , a n d a g e n e r a l f o r m u l a h a s n o t evolved. T h e above e q u a t i o n s , i . e . - 4 . 7 . 9 , diffusion m e c h a n i s m s ,
a n d 4 . 7 . 1 0 . s u m m a r i z e two of t h e t h r e e
o n e of w h i c h usually p r e d o m i n a t e s
in a n y g i v e n
c a s e {see 4.7.8.). But t h e s e e q u a t i o n s c o n t a i n q u a n t i t i e s t h a t are h a r d to m e a s u r e , or even e s t i m a t e . A m u c h b e t t e r w a y is to follow t h e m e t h o d
of H a n c o c k a n d S h a r p ( ~
1948). If o n e c a n m e a s u r e x, t h e a m o u n t f o r m e d in time, t, t h e n t h e
156
following e q u a t i o n applies: -Iogfin[l-xl]
4.7.1 I- H a n c o c k & S h a r p EquationType of diffus.ion
r a n g e of m
s i m p l e diffusion
0.57 - 0 . 6 2
nuclei g r o w t h
1.00-
phase boundary
1.25
=minT
+Ink
1.15 - 4.00
Here, we fund it n e c e s s a r y to be able to m e a s u r e t h e p r o g r e s s of a solid state reaction.
If we c a n do so, t h e n we c a n d e t e r m i n e
diffusion involved. I f - log (In(I-x)) value for t h e slope, m,
the
type
of
is p l o t t e d a g a i n s t In t, one o b t a i n s a
of t h e line w h i c h allows classification of t h e m o s t
likely diffusion p r o c e s s . Of c o u r s e , one m u s t be s u r e t h a t t h e solid s t a t e r e a c t i o n is p r i m a r i l y diffusion-limited.
Otherwise,
t h e analysis does n o t
hold. 4 . 8 , - ANALYSIS OF DIFFUSION REACTIONS Let u s n o w t u r n to diffusion in t h e g e n e r a l case, w i t h o u t w o r r y i n g about t h e e x a c t m e c h a n i s m or t h e r a t e s of diffusion of t h e various species. As an e x a m p l e to i l l u s t r a t e h o w we w o u l d analyze a d i f f u s i o n - l i m i t e d solid s t a t e r e a c t i o n , we u s e t h e g e n e r a l e q u a t i o n d e s c r i b i n g f o r m a t i o n of a c o m p o u n d w i t h s p i n e l (cubic) s t r u c t u r e a n d s t o i c h i o m e t r y : 4.8.1.-
AO + B203 ~ AB204
w h e r e A a n d B are two different m e t a l l i c ions a n d O is t h e oxygen a t o m (as t h e oxide). T h e r e are two (2) different c a s e s t h a t we c a n d i s t i n g u i s h , b o t h of w h i c h r e p r e s e n t p o s s i b l e diffusion m e c h a n i s m s in spinel. T h e s e involve e i t h e r a g a s e o u s or an ion diffusion m e c h a n i s m . Let us c o n s i d e r
the
ion-diffusion
mechanism
first.
As s h o w n
in t h e
following d i a g r a m , given as 4.8.2. on t h e n e x t page, b o t h A a n d B diffuse
157
t h r o u g h AB204 at the
s a m e rate. We c a n s h o w the p r o b a b l e diffusion
c o n d i t i o n s as specific solid s t a t e r e a c t i o n s , -r
Notice t h a t the partial r e a c t i o n s given in 4.8.3. are b a l a n c e d b o t h as to m a t e r i a l a n d charge. T h e s e are the r e a c t i o n s w h i c h o c c u r at the i n t e r f a c e (or p h a s e b o u n d a r y ) b e t w e e n reacting components,
the diffusing ions
a n d the
b u l k of t h e
as we have a l r e a d y i l l u s t r a t e d above. T h e r e
are at
least two o t h e r possible m e c h a n i s m s , as s h o w n in t h e following d i a g r a m :
158
In o n e case, t h e diffusion of A 2+ is m u c h f a s t e r t h a n B 3+ a n d in t h e o t h e r t h e o p p o s i t e is t r u e . Note t h a t c h a r g e - c o m p e n s a t i o n of m i g r a t i n g s p e c i e s is m a i n t a i n e d in all c a s e s . We c a n also i l l u s t r a t e a g a s e o u s t r a n s p o r t r e a c t i o n m e c h a n i s m in t h e s a m e m a n n e r , as s h o w n in t h e following d i a g r a m :
The r e a c t i o n s for t h i s c a s e (CASE III) are: 4.8.6.-
O= ~
1/202
+ 2e-
A 2+ + 2 e- + i / 2 0 2 + B203
~ AB204
In t h i s m e c h a n i s m w h e r e DA 2+ >> DB3+, t r a n s p o r t of e x t e r n a l o x y g e n gas is involved in t h e overall solid s t a t e r e a c t i o n , a c c o m p a n i e d b y e l e c t r o n i c c h a r g e diffusion. There
are
still
two
more
mechanisms
to
consider,
that
where
the
diffusion r a t e of B3+ is m u c h g r e a t e r t h a n t h a t of A2+: DB3+ >> DA2+ DA2+ >> DB3+ a n d t h e o p p o s i t e case, as s h o w n . In b o t h of t h e s e cases, t r a n s p o r t of 0 2 is
159
j u s t o p p o s i t e t h a t s h o w n in 4 . 8 . 6 . , a n d t h e r e a c t i o n s a r e : 4 . 8 . 7 . - CASE IV:
30 =
~
3/202
AO + 3 / 2 0 2 or:
20 =
~
02
+6e-
+ 6 e- + 2 B3+ +4e-
2 A 2+ + 0 2 + 4 e- + 2 B203 ~
This mechanism
AB204
2 AB204
is s h o w n i n t h e f o l l o w i n g :
We h a v e n o w p r e s e n t e d
all o f t h e 1 ~ ~ I r
diffusion reactions
in s p i n e l
s y n t h e s i s . T h e s e a r e s u m m a r i z e d a s follows: 4 . 8 . 9 . - Possible Diffusion M e c h a n i s m s in S p i n e l Ion D i f f u s i o n R e a c t i o n s : 3 A 2+ + 3 B203 ~ 3 AB204 + 2 B 3+ 2 B 3+ + 4 AO
~
AB204 + 3 A 2+
Conceivable Cases 1. DA2+ = DB3+ 2. DA 2+ >> DB 3+ (A 2+ + O = - for c h a r g e c o m p e n s a t i o n } 3.
DB4+ >> DA 2+ (B 3+ + O = - for c h a r g e c o m p e n s a t i o n }
160
4 . 8 . 9 . - Possible Diffusion M e c h a n i s m s in Spinel { c o n t i n u e d ) Gaseous T r a n s p o r t R e a c t i o n s : O= ~ 1 / 2 0 2 + 2 e A 2+ + 2 e ~ + 1 1 2 0 2 + B 2 0 3
~ AB204
Possible Cases 1. DB2+ >> DA 3+ ( t r a n s p o r t of c h a r g e only) 2. DA 3+ >> DB2+ ( t r a n s p o r t of c h a r g e only) It s h o u l d be clear, possibilities
by e x a m i n i n g
4.8.9.
carefully, t h a t
exist for the diffusion of r e a c t i n g
species
a number through
of
spinel
d u r i n g the solid state r e a c t i o n u s e d to form it. Which of t h e s e is m o r e likely will d e p e n d u p o n the exact n a t u r e of "A" as well as t h a t of "B". It w o u l d be too m u c h to expect t h a t the s a m e diffusing m e c h a n i s m w o u l d exist for all types of spinels (yes, t h e r e are m a n y t y p e s of spinels, s i n c e "spinel" is a p a r t i c u l a r c o m p o s i t i o n , i.e.- AB204, having a cubic s t r u c t u r e . What we n e e d to do is to
d e t e r m i n e w h i c h of t h e s e c a s e s is the m o s t
relevant. To do this, we n e e d to g e n e r a t e s o m e e x p e r i m e n t a l data. T h u s , we m e a s u r e f o r m a t i o n rate in air, p u r e oxygen gas a n d t h e n in an i n e r t gas. If the r a t e s do not differ significantly, t h e n we c a n rule out gaseous transport mechanisms. including
electrical
There
conductivity,
are o t h e r
transference
t e s t s we
numbers
can
and
apply,
thermal
e x p a n s i o n . Although t h e s e s u b j e c t s have b e e n i n v e s t i g a t e d in detail, w e shall not p r e s e n t t h e m h e r e . It s h o u l d be clear t h a t a n u m b e r of m e c h a n i s m s exist. Which of t h e s e d o m i n a t e s will, as we s t a t e d before, will d e p e n d u p o n the n a t u r e of b o t h "A"
and
"B".
However,
it
has
been
observed
throughout
many
investigations t h a t one m e c h a n i s m s e e m s to d o m i n a t e . We will not delve through these works. It suffices to say that: "For the most part, in oxygen-domlnnted
hosts, dlf~-~on by small cations prevails and that d l f f ~ o n of chargecompensated pairs predominates".
161
It is for this r e a s o n t h a t we write t h e solid s t a t e diffusion r e a c t i o n for t h e m a g n e s i u m a l u m i n a t e spinel as follows: 4.8.10.-
3 M g 2+ + 4 A1203 =,, 3 MgAI204 + 2 AI 3+ 2 AI 3+ + 4 MgO 4MgO
~
+ 4 AJ203
MgA1204
+ 3 M g 2+
~ 4 MgAI204
Note t h a t t h e ions given in 4 . 8 . 1 0 . c a n c e l o u t in t h e equations, a n d t h a t only the
overall solid
state reaction
remains.
However,
it
has been
d e t e r m i n e d t h a t diffusion is limited by: 4 . 8 . 1 1 . - Diffusion M e c h a n i s m : lh~x~kel Pair:. AIAI + ooVi ~
VAI + Ali 3+
In this case, the F r e n k e l p a i r diffusion, i.e.- VAI + Ali 3+, p r e d o m i n a t e s a n d is f ~ t ~ r t h a n a n y o t h e r possible m e c h a n i s m . 4.9.-
DIFFUSION IN SILICATES
We have p r e s e n t e d spinel s y n t h e s i s b e c a u s e t h e s e s y s t e m s w e r e s t u d i e d first a n d c a n be u n d e r s t o o d in a s i m p l e m a m i e r . Various silicate s y s t e m s have also b e e n s t u d i e d a n d it h a s b e e n d e t e r m i n e d
t h a t t h e y are m o r e
r e p r e s e n t a t i v e of t h e g e n e r a l c a s e involving solid s t a t e s y n t h e s i s r e a c t i o n s t h a n spinel. Let u s e x a m i n e t h e following s i m p l e silicate r e a c t i o n : 4.9.1.-
2 CaO + SiO2 ~
Ca2SiO4
Calcium oxide, in p r o p e r p r o p o r t i o n , r e a c t s w i t h silica to form c a l c i u m orthosflicate. In t e r m s of t h e spinel case, we w o u l d e x p e c t to see t h e following diffusing s p e c i e s : 4.9.2.-
Ca2+ , S i 4 + , O
,e- ,p+
Using o u r model, we w o u l d illust a t e t h e diffusion r e a c t i o n s w i t h t h e
162
following diffusion c o n d i t i o n s : 4.9.3.- M e c h a n i s m s of Diffusion a n d R e a c t i o n B e t w e e n CaO a n d Si02
In t h i s case, we have two c o n c o m i t a n t m a t e r i a l s , CaO a n d Si02, r e a c t i n g t o g e t h e r to form t h e c o m p o u n d , c a l c i u m o r t h o s i l i c a t e , w h i c h exists as a p h a s e b o u n d a r y b e t w e e n t h e five diffusing species. We c a n h y p o t h e s i z e at least t h r e e c a s e s involving diffusion. In t h e first case, b o t h Ca 2+ a n d 0 = diffuse t o g e t h e r in t h e s a m e d i r e c t i o n . In t h e s e c o n d case, Ca 2+ a n d Si 4+ diffuse in o p p o s i t e d i r e c t i o n s while t h e t h i r d c a s e involves 02 t r a n s p o r t along w i t h t h e diffusion of Ca 2+ w h i c h t h e n r e a c t s w i t h t h e Si02. T h e s e t h r e e m e c h a n i s m s m i g h t s e e m to be valid b u t f u r t h e r i n v e s t i g a t i o n reveals t h a t actual diffusion is c o n t r o l l e d
by t h e n a t u r e of t h e l a t t i c e
s t r u c t u r e w h i c h involves t h e silicate t e t r a h e d r o n .
Additionally, we find
163
t h a t the actual diffusion r e a c t i o n w h i c h o c c u r s is quite different t h a n t h a t of the spinel case. This is s h o w n in the following d i a g r a m : 4.9.5.-
T h u s , the r a t e of diffusion h a s b e e n a s c e r t a i n e d to be: RATES OF DIFFUSION FOR SILICATE-BASED COMPOUNDS Rate of species diffusion: Ca 2+ ~- 0 = >> Si 4+ This is c a u s e d by the fact t h a t the Si 4+ is tied u p in the f o r m of silica tetrahedra
where
some
of the
oxygen
atoms
are
shared
within
the
s t r u c t u r e a n d are not free to move. A r e p r e s e n t a t i o n of this is given as follows: 4.9.6.Diffusion Reaction 2 Ca 2+ 20
These
tetrahedra
=
2Ca2++
are tied t o g e t h e r
20
at the
= + S i O 2 --r Ca2 SiO 4
corners
so t h a t
a silicate
"backbone" f o r m s the s t r u c t u r e . The m e t a l c a t i o n s form "bridges" b e t w e e n b a c k b o n e - l a y e r s a n d are m u c h m o r e free to move. However, it is well to note t h a t a small a m o u n t of silicate d o e s move, b u t the exact n a t u r e of t h e diffusing specie c a n n o t be quantitatively defined (It m a y d e p e n d u p o n t h e n a t u r e of the c o m p o u n d s b e i n g formed. Most probably, the diffusing specie is actually SiOn b u t the c h a r g e of e a c h actual specie m a y vary). In
164
o r d e r to avoid confusion, we will c o n t i n u e to use Si 4+ to indicate silicate diffusion.
T h u s , w e find that t h e predominating diffusion m e c h a n i s m for ion di~ion in C a 2 ~ 0 4 s y n t h e s i s is that of Ca 2+ and t h e o x i d e ion, 0 •. We now c o m e to the m o s t i m p o r t a n t p o i n t of this Section. Up to now, w e have a s s u m e d t h a t the p h a s e w i t h i n the p h a s e b o u n d a r y , as given in t h e d i a g r a m s , is iaviolable a n d not s u b j e c t to change. T h a t is, once t h e Ca2Si04 h a s formed, no f u r t h e r r e a c t i o n can occur. While this m a y be t r u e for s o m e solids, it certainly is n o t t r u e for Ca2Si04, a n d i n d e e d for m o s t of the o t h e r s y s t e m s t h a t we m i g h t study. The way we d e t e r m i n e
ff f u r t h e r r e a c t i o n is possible is to c o n s u l t t h e
p h a s e d i a g r a m of the s y s t e m . If a c o m p o u n d is stable, t h e n it h a s a finite probability of forming d u r i n g t h e solid state reaction. Let u s n o w s u p p o s e t h a t f u r t h e r r e a c t i o n d o e s take p l a c e at the p h a s e b o u n d a r y of CaO a n d Ca2Si04, a n d also at Ca2Si04 a n d Si02. We will call t h e s e n e w p h a s e s "X" a n d "Y". This gives u s the s i t u a t i o n s h o w n in the following:
Here, we have r e a c t e d o u r diffusing species, Ca 2+ a n d O = , w i t h the initial p r o d u c t of o u r reaction, Ca2SiO4 in one direction, a n d Si 4+ a n d O = in t h e o t h e r to derive two entirely new r e a c t i o n species. It w o u l d t h u s a p p e a r t h a t "X" s h o u l d be Ca2Si05 a n d "Y" s h o u l d a p p e a r as Ca3Si207. A f u r t h e r look at the p h a s e d i a g r a m s h o w s t h a t the former s t o i c h i o m e t r y d o e s n o t exist, b u t the latter does. Because t h e
diffusing species,
Ca 2+ a n d O=,
165
c a n n o t r e a c t a c c o r d i n g the above-given reaction, they continue to d 1 ~ until they reach the vicinity of the pyrosllicate, Ca3Si207. There, t h e r e a c t i o n at this p h a s e - b o u n d a r y is: 4.9.8.-
Ca2+ + O = +
Ca3Si207 ~
2 C~2Si04
But t h e r e is n o t h i n g to stop f u r t h e r diffusion of t h e s e species a n d t h e y c o n t i n u e to diffuse to the vicinity of the SiO2 p h a s e b o u n d a r y , w h e r e t h e r e a c t i o n is: 4.9.9.-
Ca 2+ + O= + SiO2 ~
CaSiO3
T h u s , the finR! possible r e a c t i o n is t h a t vchich f o r m s the m e t a s i l i c a t e s t o i c h i o m e t r y . In the o p p o s i t e direction, we also have the diffusing species, Si 4+ a n d O=. T h e s e r e a c t w i t h the n e a r e s t p h a s e to give CaSiO4, as s h o w n in the following d i a g r a m :
Note t h a t we have t w o dlfr~,~on r e a c t i o n s one p r o c e e d i n g
w h i c h f o r m the m e t a s i l i c a t e ,
from the cationic species a n d the o t h e r f r o m anionic
species. T h i s h a s an a m a z i n g effect on the overall reaction, as s h o w n in the following diagram, given as 4.9.11. on the n e x t page. Note carefully the s e q u e n c e of i n t e r m e d i a t e r e a c t i o n s t h a t have o c c u r r e d , as d e p i c t e d involves
in this diagram. We see t h a t the first solid s t a t e r e a c t i o n
formation
of
the
orthosilicate.
But
this
is
very
quickly
t r a n s f o r m e d into m e t a - a n d pyro-silicates. However, it is the m e t a s i l i c a t e which
predominates
as the solid state
reaction
reaches
its m a t u r i t y .
Finally, it p r e d o m i n a t e s over all o t h e r forms of silicate p r e s e n t .
166
But, we still have small a m o u n t s of t h e o t h e r s p r e s e n t . Let us now r e c a l l the prevailing diffusion c o n d i t i o n s , as given in 4.9.4., i.e.4.9.12.-
Ca2+ =_ 0 = >> Si4+
Because of this diffusion m e c h a n i s m , we observe the above s e q u e n c e
of
diffusion r e a c t i o n s w h i c h o c c u r with time, as given in 4.9.12. It is actually possible to observe t h e s e r e a c t i o n s by the use of a polarizing m i c r o s c o p e hot stage w h e r e i n
the r e a c t i o n s are c a u s e d to o c c u r by h e a t i n g w h i l e
o b s e r v i n g the final s t r u c t u r e s f o r m e d via the x-ray diffraction p a t t e r n s . The above d i a g r a m is s o m e w h a t c u m b e r s o m e a n d it is m u c h easier to illustrate t h e s e r e a c t i o n s by a graph.
This is s h o w n in the following
diagram, given as 4 . 9 . 1 3 . on the n e x t page. In the s e q u e n c e of diffusion r e a c t i o n s , we note t h a t Ca2SiO4 is f o r m e d imanediately, followed by Ca4Si207. Both ImgiIt to d i ~ p l ~ a r w h e n CaSiO3
167
b e g i n s to form. N e a r t h e end, CaSi03 b e c o m e s t h e m a j o r p h a s e p r e s e n t , b u t we n e v e r r e a c h t h e p o i n t w h e r e j u s t ONE COMPOUND r e m a i n s . We always o b t a i n a m i x t u r e . T h i s p o i n t c a n n o t be o v e r s t r e s s e d a n d is o n e of t h e m o s t i m p o r t a n t p o i n t s to b e m a d e in t h i s c h a p t e r . T h e overall r e a c t i o n m e c h a n i s m s
are d i f f u s i o n - c o n t r o l l e d ,
and the total
solid s t a t e r e a c t i o n c a n be s u m m a r i z e d as follows: 4.9.14.-
8 CaO + 4 S i 0 2
~
4 Ca2SiO4
Ca2Si04 + S i 0 2
~
2 CaSiO3
3 Ca2SiO4 + SiO2
~ 2 Ca3Si207
2 Ca3~t207 + 2 SiO2 ~ 8CaO + 8SIO2 Although
these
reactions
~
6 CaSiO3 8CaSiO3
are w r i t t e n
to
show
the
formation
of t h e
m e t a s i l i c a t e , w e a l r e a d y k n o w t h a t n o n e of t h e s e r e a c t i o n s ever c o m e s to completion.
There
are c o m p e t i n g
side-reactions. We s t a r t w i t h a 2:1
168
s t o i c h i o m e t r y of CaO a n d SiO2, b u t e n d u p w i t h a s t o i c h i o m e t r y w h i c h is m o s t l y 1:1, t h a t of t h e m e t a s i l i c a t e . A n o t h e r w a y to look at t h i s p h e n o m e n o n
is t h a t t h e diffusion c o n d i t i o n s
favor t h e f o r m a t i o n of t h e m e ~ e ,
a t e , a n d t h a t t h e "excess Ca" is t a k e n
u p in t h e f o r m a t i o n of c o m p o u n d s
having a "calcium-rich" stoichiometry
(in c o m p a r i s o n to t h a t of t h e m e t a s i l i c a t e ) . However, if we s t a r t w i t h a s t o i c h i o m e t r y of 1:1 CaO to SIO2, we d i s c o v e r t h a t t h e s a m e c o m p o u n d s f o r m as before, a n d a m i x t u r e of c o m p o u n d s is still o b t a i a e d . T h e o n l y d i f f e r e n c e is t h a t t h e r e are s m a l l e r a m o u n t s of Ca2SiO4 a n d Ca3Si207 present! The only
c o n c l u s i o n t h a t we c a n d r a w is t h a t d i f f u s i o n - c o n t r o U e d
solid
s t a t e r e a c t i o n s t e n d to p r o d u c e m i x t u r e s of c o m p o u n d s , t h e r e l a t i v e r a t i o of w h i c h
is r e l a t e d
to
their
thermodynamic
s t a b i l i t y a t t h e re.action
t e m p e r a t u r e . Obviously t h e n , if w e c h a n g e t h e t e m p e r a t u r e of r e a c t i o n , w e would
expect
to
see
somewhat
different
mixtures
of
compounds
produced. Let u s n o w look briefly at a n o t h e r s i m i l a r s y s t e m w h e r e we will s t a r t w i t h a s t o i c h i o m e t r y of : 1.00 BaO to 1.00 S i 0 2 (in m o l e s ) . T h i s m i x t u r e w o u l d b e e x p e c t e d to r e a c t as: 4.9.15.-
BaO + SiO2 ~
w i t h t h e diffusion c o n d i t i o n :
BaSi03
Ba 2+ , 0 = >> Si 4+ . We c a n s h o w t h e s o l i d
s t a t e r e a c t i o n b e h a v i o r again b y a c h a r t , given as 4 . 9 . 1 6 . on t h e n e x t p a g e . O n e m i g h t t h i n k t h a t s i n c e Ba 2+ is a m u c h l a r g e r ion t h a n Ca 2+ , it w o u l d diffuse slower. S u c h is n o t t h e c a s e as c a n b e s e e n b y c o m p a r i n g t h e xaxis of 4 . 9 . 1 4 . w i t h t h a t of 4 . 9 . 1 6 . in t e r m s of r e a c t i o n t i m e .
169
It is r e m a r k a b l e t h a t in t h i s c a s e , w e s t a r t e d w i t h a I : i s t o i c h i o m e t r y a n d e n d e d u p w i t h a c o m p o u n d t h a t h a s a 2:1 s t o i c h i o m e t r y ! It s h o u l d b e c l e a r b y c o m p a r i n g
t h e e x a m p l e s for c a l c i u m silicate a n d
b a r i u m silicate t h a t o n e c a n n o t p r e d i c t h o w t h e d i f f u s i o n - c o n t r o l l e d s o l i d s t a t e r e a c t i o n s will p r o c e e d
since they are p r e d i c a t e d
upon the relative
t h e r m o d y n a m i c s t a b i l i t y of t h e c o m p o u n d s f o r m e d in e a c h s e p a r a t e p h a s e . T h e s e r i e s of d i f f u s i o n - c o n t r o l l e d r e a c t i o n s are for t h e c a s e of t h e s o l i d s t a t e r e a c t i o n b e t w e e n BaO + S i 0 2 as given in 4 . 9 . 1 6 . above. T h e s e s o l i d s t a t e r e a c t i o n s c a n b e s u m m a r i z e d as: 4.9.17.-
(a) 2 13a2+ + 2 0 =
+ SiO2
~
Ba2SiO4
(b) Ba2SiO4 + Si 4+ + 2 0 =
~
BaSiO3
B e c a u s e t h e r a t e of R e a c t i o n (a) is so m u c h f a s t e r t h a n t h a t of (b), we e n d u p w i t h Ba2SiO4 a s t h e m a j o r p r o d u c t . Brat, w e always e n d up w i t h a m i x t u r e of b a r i u m silicate s t o i c h i o m e t r i e s .
170
THIS
BRINGS US TO A MAJOR AXIOM FOR C H A V r E R - 4
REGARDING
SOLID STATE REACTIONS, VIS"DIFFUSION-CONTROLLED REACTIONS BETWEEN REFRACTORY O X I D E S ALWAYS R F ~ U L T S IN M I X T U R E S O F C O M P O U N D S
WHAT
THIS
MEANS
IS
THAT
WE
CANNOT
"
PREPARE
PURE
C O M P O U N D S BY REACTING OXIDES T O G E T H E R ! By now, you are p r o b a b l y w o n d e r i n g
h o w to avoid s u c h a m e s s . T h e r e
o u g h t to b e a w a y to e v a d e t h i s s i t u a t i o n , a n d i n d e e d t h e r e is. We c a n f i n d at l e a s t four (4) m e t h o d s to do so. T h e y i n c l u d e : 4.9.18.-
1. U s i n g a g a s e o u s r e a c t a n t 2. U s i n g a flux 3. P r o m o t i n g a s u p e r - r e a c t i v e c o m p o n e n t 4. U s i n g a p r e c i p i t a t e d p r o d u c t to act as t h e r e a c t i o n b a s e
Note t h a t all of t h e s e m e t h o d s a t t e m p t to b y p a s s t h e d e p e n d e n c e
of t h e
solid s t a t e r e a c t i o n u p o n diffusion. But, u s i n g a g a s e o u s r e a c t a n t m a y n o t b e p r a c t i c a l in all c a s e s . And, s o m e t i m e s it is h a r d to f'md a flux w h i c h d o e s n o t i n t e r f e r e w i t h t h e r e a c t i o n . A flux is d e f i n e d as follows: 4.9.19.-
DEFINITION OF A FLUX
"A m a t e r i a l w h i c h m e l t s lower t h a n t h e solid s t a t e r e a c t i o n temperature, allows
d i s s o l v e s o n e or m o r e
material
entering
transport
to
the
of t h e c o m p o n e n t s reaction
into t h e solid s t a t e r e a c t i o n .
zone,
and
without
Preferably,
the
end-
p r o d u c t s h o u l d b e i n s o l u b l e in t h e flux". We c a n also e m p l o y a s u p e r - r e a c t i v e p r o d u c t so as to o b t a i n 1 0 0 % of t h e desired
product.
follows.
In
this
E x a m p l e s are given in 4 . 9 . 2 0 . case,
we
are
varying
the
on the
ratios
of
next
p a g e as
reacting
p r o p o r t i o n s in a d e l i b e r a t e m a n n e r to p r o d u c e s e p a r a t e c o m p o u n d s .
molar
171
4.9.20.2 BaCO 3
+ SiO2
~
Ba2SiO4 ( I 0 0 % yield)
BaCO3
+ SiO2
~
BaSiO3
3 BaCO3
+ SiO2
~
Ba3SiO5 ( I 0 0 % yield)
(100% yield)
T h e m e c h a n i s m involved is as we have a l r e a d y d e s c r i b e d in 4.2.8., i.e.-
The
very
fine
particles
of
nearly
atomic
i m m e d i a t e l y . B e c a u s e t h e BaO p r o d u c t area, t h e solid s t a t e r e a c t i o n is
not
proportions
react
almost
h a s an e x t r e m e l y large s u r f a c e
diffusion limited. In t h e last m e t h o d
(see 4.9.18.), we m i g h t u s e a p r e c i p i t a t e d p r o d u c t to u s e as t h e basis to form t h e d e s i r e d c o m p o u n d . We m i g h t p r e c i p i t a t e : 4.9.22.-
Ba 2+ + HPO4 =
~
Bat-IP04
w h i c h is t h e n r e a c t e d to form t h e o r t h o p h o s p h a t e as t h e d e s i r e d p r o d u c t , e.g. 4.9.23.If
2 BaHPO4 + BaO
~
Ba3(P04)2 + H 2 0
b a r i u m o r t h o p h o s p h a t e is f o r m e d in t h i s m a n n e r , we c a n g u a r a n t e e
t h a t t h e final solid s t a t e r e a c t i o n p r o d u c t will c o n s i s t of 100% of t h e desired product. 4 . 1 0 . - DIFFUSION MECHANISMS WHEN A . . _ . . CATION CHANGES VALENCE Before we leave t h e s u b j e c t of diffusion, let u s e x a m i n e t h e c a s e w h e r e a c h a n g e of v a l e n c e s t a t e of t h e c a t i o n o c c u r s . T h i s m e c h a n i s m
is q u i t e
172
c o m m o n for t h o s e solid s t a t e r e a c t i o n s involving t h e t r a n s i t i o n m e t a l s of the
Periodic
Table.
In s t u d i e s
of solid
state
reactions,
this
situation
c o n t i n u e s to be t h e s u b j e c t of m u c h i n v e s t i g a t i o n b e c a u s e of t h e u n u s u a l s i t u a t i o n s w h i c h are e n c o u n t e r e d . C o n s i d e r t h e r e a c t i o n : 4.10.1.-
NiO + A1203 =r NiA1204
T h i s w o u l d give u s t h e following ditKmion d i a g r a m :
In t h i s case, we have 4 p o s s i b l e diffusion m e c h a n i s m s all p r o d u c i n g NiA1204. We c a n n o t say w h i c h of t h e diffusion p r o c e s s e s is f a s t e r at t h i s point, or w h i c h m e c h a n i s m prevails. F r o m w h a t we have s t a t e d p r e v i o u s l y , it is likely to be t h a t of A13+ a n d Ni2+ diffusing in o p p o s i t e d i r e c t i o n s . But, s u p p o s e s o m e of t h e N i 2+ oxidizes to N i3+ , vis4.10.3.-
Ni 2+ = Ni 3+ + e-
T h i s is a c a s e w h e r e a t r i v a l e n t c a t i o n is p r e s e n t in a d i v a l e n t lattice ( s e e
173
C h a p t e r 3).The shown4.10.4.-
following defect
2 Ni2+Ni ~i
=
+e-
2 Ni2+ N i
= + e-
=
r e a c t i o n s w o u l d t h e n be operative as
Ni3+Ni
+ VNi + P+
VNiNi3+Ni
+ VNi
+ P+
This w o u l d give us the foUowing diffusion diagram:
Note t h a t N i 2+ does n o t m i g r a t e b u t gives rise to a trivalent species plus a vacancy. This
situation
gives
rise
to
a complicated
set
of diffusion
conditions: a. The c h a r g e d vacancy is one of the m i g r a t i n g s p e c i e s . b. The c h a r g e d vacancy c o m b i n e s with N i3+ to form
a defect
c o m p o u n d , NiV-N iA1204. c. The divalent ion, Ni 2+, is also p r o d u c e d in the diffusion r e a c t i o n s .
174
d. S i n c e DNi 3+ >> Dv N i ' Ni 3+ diffuses o p p o s i t e l y to AI 3+ in t h e above s e t of a c t u a l diffusion c o m p o u n d arises, i,e,- N i2/~204.
reactions,
as s h o w n
another
Note t h a t t h e c h a r g e d ~ac~axmy diffuses as o n e of t h e r e a c t i n g s p e c i e s f o r m t h e defect c o m p o u n d . T h i s s i t u a t i o n is q u i t e c o m m o n s t a t e c h e m i s t r y of c o m p o u n d s c o n t a i n i n g m u l t i v a l e n t t r i v a l e n t N i 3+ also g i v e s rise to a n e w c o m p o u n d , N i A I 0 4 .
new
to
in t h e solid cations. The Yet t h e s a m e
r e a c t i o n s given in 4 . 1 0 . 2 . are also OPERATIVE. Thus, the overall reaction a c t u a l l y tak/mg p l a c e is a c o m b i n a t i o n of 4 . 1 0 . 2 . a n d 4 . 1 0 . 5 . LET US NOW SUMMARIZE T H E AREAS W E HAVE COVERED SO FAR: a. T y p e s of Solid S t a t e R e a c t i o n s b. F o r m a t i o n of P h a s e B o u n d a r i e s b e t w e e n R e a c t i n g S o l i d s c. N u c l e a t i o n R a t e P r o c e s s e s d. T h e Critical R a d i u s a n d T r a n s f o r m a t i o n f r o m E m b r y o to N u c l e u s . e. Diffusion Laws a n d M e c h a n i s m s f. Analysis of D i f f u s i o n - L i m i t e d Solid S t a t e R e a c t i o n s T h e s e s u b j e c t s i n c l u d e t h e m a j o r i t y of t h e c a s e s we will e n c o u n t e r in o u r s t u d y of solid s t a t e r e a c t i o n s a n d t h e i r c o m p l e x i t y . Let u s n o w s u m m a r i z e t h e i n f o r m a t i o n we h a v e c o v e r e d : 1) We c a n define t h e e x a c t n a t u r e of a solid s t a t e r e a c t i o n . 2) Before a n y solid s t a t e p r o c e s s c a n o c c u r , n u c l e i m u s t f o r m so as to allow t h e r e a c t i o n to go to c o m p l e t i o n . 3)
In
some
cases,
an
embryo
must
form
before
the
nucleus
f o r m a t i o n is c o m p l e t e . 4)
Nucleation
nucleation)
can
occur
within
a n y given
or be i n d u c e d b y a n y o u t s i d e
i n c l u d i n g t h e p r e s e n c e of a foreign solid.
solid
factor
(homogeneous
(heterogeneous),
175
5) In a diffusion-limited reaction, m o v e m e n t of species occurs by a "hopping" motion. 6) If a solid state reaction is diffusion-lirrdted, if is unlikely that we can obtain 100% of any product, and will always obtain a mixture of compounds whose relative ratio will depend t h e r m o d y n a m i c stability at the firing t e m p e r a t u r e .
upon
their
7) Several different types of species, including various solid state defects, diffuse and form a phase boundary of reaction, which may further react to form specific compositions. Although we have covered m e c h a n i s m s relating to solid state reactions, the formation and growth of nuclei and the rate of their growth in both heterogeneous and homogeneous solids, and the diffusion p r o c e s s e s thereby associated, there exist still other processes after the particles have formed. These include sequences in particle growth, once t h e particles have formed. Such sequences include: I m p i n g e m e n t of nuclei Ostwald Ripening (coarsening) Sintering Formation of Grain Boundaries We will reserve a discussion of these subjects to the appendices of this chapter. Any s t u d e n t who has interest in these subjects amy brouse in t h e descriptions given. PROBLEMS FOR CI-L~J~I'ER 4 I. Write equations for all of the p h a s e s changes given in 4.1.1. Use A for heat added or subtracted, as n e e d e d . 2. Write equations for the four (4) primary types of heterogenous solid state reactions usually e n c o u n t e r e d . Do not use those already given in Table 4-1.
176
4. Given t h a t Gd203 r e a c t s with A1203 to form GdAIO3, d r a w a d i a g r a m s h o w i n g the r e a c t i o n
conditions,
the p h a s e b o u n d a r y f o r m e d
and the
diffusion c o n d i t i o n s likely to prevail in the solid state r e a c t i o n . 4. If iron m e t a l w o u l d oxidize to form a h o m o g e n o u s oxide layer w i t h o u t flaking off, d r a w a d i a g r a m s h o w i n g the r e a c t i o n conditions, the p h a s e b o u n d a r y formed a n d the diffusion c o n d i t i o n s likely to prevail in the solid state r e a c t i o n . 5. Given t h a t the d e c o m p o s i t i o n of SrCO 3 is a simple n th o r d e r r e a c t i o n a n d t h a t the rate c o n s t a n t is 4 x 10 -4 m o l / s e c , at 865 ~ a m o u n t of SrO f o r m e d
calculate t h e
in 10.0 m i n u t e s from the original
1.0 mol of
powder, if the r e a c t i o n is a f i r s t - o r d e r r e a c t i o n . E x p r e s s your r e s u l t in %. If the r e a c t i o n were s e c o n d - o r d e r
(which it is
not), w h a t w o u l d be the % r e a c t i o n ? 6. Write solid state r e a c t i o n s for the s y n t h e s i s of: a. b. c. d.
M g2SiO4 Ba0.95Pb0.05 Si205 (Sr, Mg)4(PO4) 2 MgWO4
e. CalOCI2(PO4) 6 f. Cd(BO2) 2 g. Homilite- Ca2(Fe,Mg,Mn)B2Si2OI0 h. N a t r o s i l i t e i. ZnS (specify c o n d i t i o n s ) j. S t e r n b e r g i t e - AgFe2S4 (specify c o n d i t i o n s ) k. SrHPO4 (state c o n d i t i o n s of s y n t h e s i s ) 7. Classify the types of solid state r e a c t i o n s c o m p o u n d s in the above p r o b l e m .
you u s e d
to
form
the
8. For t h e spinel, Hercyanite, d r a w a d i a g r a m illustrating the p r o b a b l e ion diffusion p r o c e s s e s , give the diffusion c o n d i t i o n s a n d t h e diffusion
177
r e a c t i o n s if the diffusion coefficents for t h e cation a n d anion are about equal. 9. For t h e spinel, H e r c y a n i t e , d r a w a d i a g r a m i l l u s t r a t i n g t h e p r o b a b l e ion diffusion
processes,
give
the
diffusion
conditions
and
the
diffusion
r e a c t i o n s if the diffusion coefficents for t h e cation a n d a n i o n are: a. DA2+ >> DB4+ b. DB3+ >> DA2+ I0. For the spinel, H e r c y a n i t e , a s s u m e t h a t t h e c a t i o n c h a n g e s in v a l e n c e state.
Then,
processes,
draw
give the
a diagram diffusion
illustrating conditions
the and
probable the
ion
diffusion
diffusion reactions,
i n c l u d i n g t h e effect of i n d u c e d c r y s t a l lattice d e f e c t s . Av~ndix
I
M a t h e m a t i c s Associated w i t h N u c l e a t i o n Models of 4.4. I. In o r d e r to s h o w h o w a t h e o r y for the n u m b e r of nuclei f o r m e d p e r u n i t time c a n be built up, we c o n s i d e r t h e following. First, we a s s u m e t h a t a n u c l e u s will be s p h e r i c a l (to m i n i m i z e surface energy). T h e v o l u m e will be: Ap.l.l.-
V = 4 / 3 7r r3
We u s e r d t as a p a r t i c l e r a d i u s involving time, t, to define a g r o w t h r a t e a n d also define N as the n u m b e r of nuclei f o r m e d in t = y. T h e n t h e volume, V(t), f o r m e d as a f u n c t i o n of t i m e will be: Ap. 1.2.-
V(t)
= f {4n 13 0 f { r d t l x * ( d N l dt)t = y} d y
This is t h e g e n e r a l form in t h e c a s e w h e r e we have s p h e r i c a l nuclei. If w e do n o t have s p h e r i c a l nuclei, t h e n the e q u a t i o n m u s t be modified to: Ap. 1.3.-
V(t)
= f { 0 f [ r d t l ~-- o ( d N / dt)t = y ldy
178
It is easily s e e n t h a t 0 is a g e o m e t r i c a l
or shape factor in A p . l . 2 .
and
Ap. 1.4. a n d we define k as a n e x p o n e n t for t h e r a d i u s of t h e nuclei, x d t (it is 4 in A p . l . 2 .
(for t h e s p h e r i c a l case) a n d 2 in A p . l . 4 . for t h e g e n e r a l
case. In e i t h e r case, we have b o t h t h e v o l u m e of t h e n u c l e u s a n d t h e n u m b e r of nuclei f o r m e d as variables. Let u s n o w r e c o n s i d e r o u r n u c l e a t i o n m o d e l s of 4.4.1., specifically M o d e l s B, D a n d E. T h e s e involving r a n d o m
are e x a m p l e s of p h a s e - b o u n d a r y c o n t r o l l e d nucleation.
We n o w
assume
an exponential
growth embryo
f o r m a t i o n law (see 4.4.7), w i t h isotopic g r o w t h of nuclei in t h r e e d i m e n s i o n s a n d k2 as t h e r a t e c o n s t a n t . By suitable m a n i p u l a t i o n of 4 . 4 . 6 . , we c a n get (by Taylor S e r i e s e x p a n s i o n ) : Ap. 1.4.- RANDOM NUCLEATION -- Vt/Voo = 87r N o k 2 3 / V o k l 3 exp. [(-klt) - ( - k l t ) 2 / 2 ! + ( - k i t ) 3 / 3 ! ] w h e r e we have only given t h e first t h r e e t e r m s of t h e series. If No is large, t h e n k I will be small. T h i s gives us:
Ap.l.5.-
= {n N o k 2 3 k l / 3 V o } t 3
w h e r e ~ is t h e f l ~ c t i o n r e a c t e d . T h i s is o n e of the c o n c e p t s given in 4 . 4 . 1 . If k l is large, t h e n t h e first t e r m p r e d o m i n a t e s , a n d we get:
Ap.l.6.-
--- { 4 n N o k 2 4 k l / 3 V o } d~ / d t =
t3 ,and,
{4n N o k 2 3 k 1 ! 3 V o }
t2
The effective interfacial a r e a for o u r n u c l e i w o u l d be (1- ~), so that:
Ap.l.7.But since: extended obtain:
= 1 - exp. {4n No k23 k l / 4 Vo} t 3 d~
- (I - ~)
d~ex
(where
d~ex
is d e f i n e d
nuclei f o r m a t i o n ) , we c a n r e a r r a n g e A p . l . 6 .
as t h e r a t e of
and integrate
to
179
Ap.l.8.-
f d[~ex = f d [ ~ / ( 1 - [ ~ )
= -In(l-~)
We n o t e t h a t the above e q u a t i o n s enable u s to calculate ~, the fraction of nuclei f o r m e d , in t e r m s of a r a t e c o n s t a n t a n d the time, t. Note again t h a t k l is the r a t e c o n s t a n t for a u c l e i f o r m a t i o a w h e r e a s k2 is the r a t e c o n s t a n t for nuclei g r o w t h . Although the above is c o m p l i c a t e d ,
it does aptly illustrate the various
m e c h a n i s m s involved w h e n a t o m s (ions) m i g r a t e by diffusion a n d s t a r t to form a n e w s t r u c t u r e by f o r m a t i o n of i n c i p i e n t e m b r y o s , t h e n nuclei a n d finally t h e g r o w t h of p h a s e b o u n d a ~ e s . T h e r e is a n o t h e r w a y to a p p r o a c h the s a m e p r o b l e m . We c a n define a v o l u m e of d o m a i n s (nuclei) r e a d y to grow at time, y. If we use: k2 3 (t- y), this m e a n s t h a t k l is large. Following t h e s a m e m e t h o d as given above, w e arrive at:
Ap.l.9.-
[~ex = 4 / 3 n k 2
3f(t
-y)3 Idy
w h e r e I = r a t e of n u c l e a t i o n for a u n i t v o l u m e so t h a t Idy is set equal to t h e total n u m b e r of nuclei p r e s e n t . All o t h e r t e r m s have b e e n p r e v i o u s l y defined. T h u s , ff k l is truly a c o n s t a n t , t h e n : Ap.l.10.-
( 1 - [~) - n /3 k2 3 k l t 3
But if nuclei are a l r e a d y p r e s e n t , t h e n : Ap.l.ll.-
-In(l-~)
=4/3nNo
k2 3 t 3 = k ' t r = Z e x p . (-E/RT) t r
w h e r e r is an e x p o n e n t w h i c h d e p e n d s u p o n the s h a p e factor, 0, of t h e r e a c t i o n (as s h o w n above) a n d k' is a r a t e c o n s t a n t i n c o r p o r a t i n g all of t h e r e l e v a n t c o n s t a n t s t o g e t h e r ( i n c a s e we do n o t have a s p h e r i c a l n u c l e u s ) . We c a n s h o w h o w various m e c h a n i s m s a n d s h a p e factors affect the t i m e factor a n d e n e r g i e s involved in nuclei f o r m a t i o n a n d g r o w t h .
180
We c a n d i s t i n g u i s h b e t w e e n the i n t e r f a c e s t r u c t u r e of t h e n u c l e u s , N, a n d the c r y s t a l b e i n g t r a n s f o r m e d ,
/k T h i s c a n be s e e n
in the
following
diagram:
Here, we s h o w t h r e e differences in the interface b e t w e e n the n u c l e u s , N, a n d the original crystal, /~ We find t h a t in the first case, the l a t t i c e s m a t c h fairly closely a n d are c o h e r e n t . In the s e c o n d case, t h e r e is s o m e c o r r e s p o n d e n c e b e t w e e n the lattices. But the i n c o h e r e n t c a s e s h o w s little m a t c h i n g of the two lattices. It is t h e r e f o r e n o t s u r p r i s i n g t h a t the interface sh--ucture h a s a large effect
181
on the interfacial energy, b u t also u p o n t h e t h e r m o d y n a m A c s of c h a n g e w h i c h i n f l u e n c e s t h e r a t e of f o r m a t i o n of e m b r y o s , E, w h i c h t h e n f o r m nuclei. T h e i n t e r n a l e n e r g y (AGmax) of t h e e m b r y o is found in t h e s a m e way: Ap.l.13.-
W-AGmax
= i/3(4n
rcrit ~') = 1 6 / 3 { n
73/AGv}
w h e r e Gv is the difference of free e n e r g y b e t w e e n t h e n u c l e u s w i t h i n t h e crystal; N is the n u m b e r of nuclei; k is t h e nuclei volume; [~ is a s h a p e factor; o is t h e interfacial t e n s i o n or surface energy; a n d V is t h e i n t e r f a c e e x c h a n g e energy. Using t h e r m o d y n a m i c s , we c a n also define: Ap.l.14.-
AGv = RT In P/Pequil " i / V c r i t ,
then:
AGv = HV { {T - T e q u i l ) / T e q u i l } w h e r e equil, refers to the e q u i l i b r i u m state, Vcrit is t h e critical v o l u m e of t h e embryo, a n d b o t h Gv a n d HV still refer to t h e difference b e t w e e n t h e ~.ates of B a n d C. Accordingly, it is easy to arrive at: Ap. I. 15.-
I = Z exp.(- Eo / RT) exp.(- W / RT)
w h e r e Eo is the e m b r y o m o t i o n energy. If No is t h e n u m b e r of original e m b r y o nuclei p r e s e n t , t h e n : Ap.l.16.-
I = d N n l d t = k l (No - N) a
w h e r e k l is a r a t e c o n s t a n t a n d 6 is equal to t h e n u m b e r of s t e p s involved in t h e i n t e r f a c e c h a n g e of str~Jcture. T h u s , we have: Ap.l.17.-
Nn = No [ 1 - exp. (-k! t)]
or:
I -- k l N o
exp. ( - k i t )
T h e s e e q u a t i o n s allow u s to calculate b o t h n u m b e r s of e m b r y o s b e i n g f o r m e d and t h e e n e r g y involved in t h e i r f o r m a t i o n . T h u s , t h e i n t e r f a c e s t r u c t u r e affects t h e r a t e of n u c l e i f o r m e d and the r a t e of t r a n s f o r m a t i o n
182
of A to N (which t h e n grows to form the "B"-phase). We can now c o r r e l a t e Ap. 1.12. a n d 5 of Ap. 1.16. with the c a s e s given in Ap. 1.12. Note t h a t w e have a s s u m e d t h a t N 2 / 3 / N ~ 1 in the calculation.
ADvenflix I! M a t h e m a t i c s A s s o c i a t e d with Incipient Nuclei G r o w t h C o n s i d e r the t r a n s f o r m a t i o n to form a n u c l e u s in t e r m s of the rate i n s t e a d of a volume. We define: Ap.2.1.- Rate of nucleation{I) ----the n u m b e r of nuclei f o r m e d p e r u n i t t i m e per u n i t volume. If the n u c l e a t i o n is r a n d o m , we will have the h o m o g e n e o u s case; if it is specific
(with
heterogeneous
foreign
or
phase
boundary
walls),
we
have
the
case, vis-
Ap.2.2.
The above d r a w i n g illustrates the f o r m a t i o n of an n u c l e u s N w i t h i n t h e crystallite, /k (not d r a w n to scale in the above diagram). The c h a n g e in free e n e r g y in going from A to N will be a function of b o t h v o l u m e a n d surface a r e a (shape). We m u s t d i s c r i m i n a t e b e t w e e n the interfacial surface e n e r g y b e t w e e n A a n d N, a n d the i n t e r n a l e n e r g y of N. T h u s , the c h a n g e in free e n e r g y will be:
Ap.2.3.-
AG =Nn(GV
+ or} ~ + 13N2/3 y
183
w h e r e Gv is t h e d i f f e r e n c e of free e n e r g y of N w i t h i n A; N n is t h e n u m b e r of nuclei; k is t h e n u c l e i v o l u m e ; ~ is a s h a p e factor; o is t h e i n t e r f a c i a l t e n s i o n or s u r f a c e energy; a n d u is t h e i n t e r f a c e
exclmuge energy. T h e
e q u a t i o n Ap. 1.3., given above is u s e d h e r e , i.e.-
Ap.2.4.-
V{t)
= f { 0 [ f x d t 12 ( d N / d t ) t = y } d y
T h i s is t h e g e n e r a l f o r m in c a s e we do n o t h a v e s p h e r i c a l nuclei. If we do:
Ap.2.5.-
V(t)
= y{ 0 f{
We will a s s u m e a s p h e r i c a l
4n/3 [j'xdt
13(dN/dt)t=y}dy
s h a p e factor a n d u s e t h e l a t t e r of t h e t w o
e q u a t i o n s . S i n c e t h e first p a r t of Ap.2.4. is t h e v o l u m e f a c t o r w h i l e t h e l a s t p a r t is t h e s u r f a c e factor, we c a n do t h i s w i t h s o m e j u s t i f i c a t i o n . For a s p h e r i c a l n u c l e u s , i.e.- A p . 2 . 5 . , we g e t :
Ap.2.6.-
AG
=Ni 4/3nr
3(GV
+ ~} + 4 n r 2 N 2/3 Y
We n o w d i f f e r e n t i a t e Ap. 2.6. so as to o b t a i n zero s u r f a c e e n e r g y , i.e.-
Ap.2.7.-
d(A G ) / d r = 0 = 4n Ni r2 (Gv + o)
- 8 n r N 2/3 Y
If we h a v e zero surface e n e r g y , t h e n d ( ~ G ) / d r = 0 a n d o = 0. T h u s w e have: Ap.2.8.-
4n r 2 ni Gv + 8 n r N 2/3 Y= 0
orwhich
is
r crit = - 2 Y / A G v the
Gibbs-Thompson
equation
defining
the
critical
radius
r e q u i r e d for a n e m b r y o to form. Note t h a t w e h a v e a s s u m e d t h a t N 2/3 /N 1 in t h e c a l c u l a t i o n . T h e i n t e r n a l e n e r g y { A Gmax = W) is f o u n d in t h e s a m e way:
Ap.2.9.-
W = 1 / 3 (4n rcrit Y) -- 1 6 / 3 { n ~' 3 /AGv}
184
w h e r e we have u s e d similar c r i t e r i a t o simplify t h e r e s u l t i n g e q u a t i o n . Since from t h e r m o d y n a m i c s : Ap.2.10.-
AGv = RT In P/Pequil " 1/Vcrit, t h e n : AGv = HV { {T -Tequil /Tequfl }
w h e r e equfl, refers to the e q u i l i b r i u m state, Vcrit is the critical volume, a n d b o t h Gv a n d Hv
still refer to the difference b e t w e e n t h e ~
of A
a n d B. Using e q u a t i o n s a l r e a d y developed, it is easy to arrive at: Ap.2.11.-
I = Z exp (- Eo / RT) exp ( - W / R T )
w h e r e Eo is the e m b r y o m o t i o n energy. If No is t h e n u m b e r of original e m b r y o nuclei p r e s e n t , t h e n : Ap.2.12.-
I = d N / d t = k l (No - N) ~
w h e r e k I is a r a t e c o n s t a n t a n d 8 is equal to the n u m b e r of s t e p s involved in the i n t e r f a c e c h a n g e of s t r u c t u r e . T h u s : Ap. 2 . 1 3 -
N --No [ 1 - e x p ( - k i t ) ] or: I --- k l N o
exp ( - k i t )
We n o t e t h a t the g r o w t h of nuclei is a s s o c i a t e d with the m o t i o n of a p h a s e boundary. This c o m p l e t e s o u r analysis of t h e g r o w t h of e m b r y o s . A a ~ n f l l x III
H O M O G E N E O U S NUCLEATION P R O C E S S E S In a
m a n n e r similar to t h a t u s e d for h e t e r o g e n e o u s
define diffusion a n d nuclei g r o w t h for a already
stated
that
homogeneous
r e a c t i o n s , we c a n
homogeneous
nucleation
can
be
solid. We have contrasted
to
h e t e r o g e n e o u s n u c l e a t i o n in t h a t the f o r m e r is r a n d o m w i t h i n a ~ e c o m p o u n d while t h e l a t t e r involves m o r e t h a n one p h a s e or c o m p o u n d .
185
H O m o g e n e o u s n u c l e a t i o n m i g h t apply to p r e c i p i t a t i o n p r o c e s s e s w h e r e homogeneous
nucleation
must
occur
~onta~eousIy
before
any
p r e c i p i t a t i o n p r o c e s s c a n occur. Since p r e c i p i t a t i o n of c o m p o u n d s f r o m solution is a c o m m o n i n d u s t r i a l p r o c e s s , we i n c l u d e it h e r e . To begin, we k n o w t h a t a c h a n g e in free e n e r g y m u s t o c c u r s i m u l t a n e o u s l y as a c h a n g e in p h a s e (nucleation) occurs. This will be r e l a t e d to the total volume, V, a n d t h e total surface a r e a of b o t h nuclei a n d particles, E, visAp.3.1.-
A G = Vag
+ Eo
w h e r e VAg is the tree e n e r g y p e r u n i t v o l u m e a n d o is the surface e n e r g y of e a c h nuclei. If we have s p h e r i c a l nuclei, t h e n :
Ap.3.2.-
AG=4/3nr
3 Ag + 4 n r 2 o
If t h e total free energy, AG, does not c h a n g e w i t h nuclei radius, i.e.d(AG) I dr
is defined as zero, t h e n :
Ap.3.3.where
r crit r*crit
= - 2 o / Ag
is the
critical
r a d i u s for n u c l e u s f o r m a t i o n
similarity of this e q u a t i o n to t h e
Gibbs-Thompson
d e s c r i b e s t h a t of the h e t e r o g e n e o u s solids).
radius
critical
of
nuclei
(Note
of Ap. 1.10. growth
the
which
between
In t h e following table, given on the n e x t page, we s u m m a r i z e t h e m e t h o d s u s e d to o b t a i n the n e c e s s a r y e q u a t i o n s d e s c r i b i n g nuclei g r o w t h a n d t h e k i n e t i c s of g r o w t h . In the last equation, I is still defined as: I = N u m b e r of nuclei p e r Unit time p e r Unit volume. We find t h a t t h e quantity, N S* fe, is a p p r o x i m a t e l y e q u a l to 1046 per second.
p e r cc.
186
Table 4 - 3 Derivation of F o r m u l a s D e s c r i b i n g H o m o g e n e o u s Nuclei F o r m a t i o n 1. Using the e q u a t i o n s in Ap.3.1. & Ap.3.2., i.e.- AG = Vag + Xo and ~G=4/3nr
AG*=
16n o 3 / 3 ( A g ) 2
(where AG* = c h a n g e in free e n e r g y at the critical r a d i u s , r*,
3 Ag + 4 n r 2 o
for n u c l e u s formation).
we c o m b i n e t h e m to obtain: 16 n o 3 To 2 / 3
2, We t h e n define: Ag - Ah(T-To)/To = tub(AT/To) to
AG*=
obtain:
individual nuclei)
3. The n u m b e r of nuclei c a n be
N* = N e x p .
(/kh) 2 A T 2
(ah is the e n t h a l p y of the AG*/kT
d e s c r i b e d by a B o l t z m a n n d i s t r i b u t i o n , i.e.4. By defining dN/ dt as a
d N l d t = S*fe exp. AG*/ k T
f r e q u e n c y {t is time), we get:
(G*= free e n e r g y of t h e n u c l e u s , S * = critical s u r f a c e interface fe = I n t ~ e i a l e n e r g y
5. C o m b i n i n g t h e s e two e q u a t i o n s finally gives us-
I -- d N * / d t = N S * fe exp.{- A G * / k T
We c a n solve this graphically, as follows-
+ AGD / k T )
187
In t h i s c a s e , we plot T vs: r * so as to d e t e r m i n e t h e value of T* a n d T vs: I = dN/dt,
i.e.-
the
change
in
numbers
of n u c l e i
with
time
so as to
d e t e r m i n e t h e t e m p e r a t u r e of m a x i m u m f o r m a t i o n of n u c l e i . It c a n be s e e n in A t h a t t h e value of r * is r e m a r k a b l y c o n s t a n t over a w i d e r a n g e of t e m p e r a t u r e s ,
b u t t h a t it s t a r t s to a p p r o a c h
infinity at s o m e
c r i t i c a l t e m p e r a t u r e , T*. In c o n t r a s t , t h e n u m b e r of n u c l e i p r o d u c e d in B is m a x i m u m at s o m e p a r t i c u l a r t e m p e r a t u r e . T h i s s h o w s u s t h a t a l t h o u g h the critical radius does not c h a n g e temperature,
the
numbers
s i g n i f i c a n t l y over
of h o m o g e n e o u s
nuclei
a wide
range
produced
is
of
very
dependent upon temperature. Let u s n o w e x a m i n e t r a n s f o r m a t i o n k i n e t i c s for t h e g e n e r a l c a s e , t h a t is, the
homogeneous
c a s e for n u c l e i g r o w t h
a fte r t h e y h a v e f o r m e d .
We
assume: a. T h e n u c l e a t i o n is r a n d o m . b. T h e n u c l e a t i o n a n d g r o w t h r a t e a r e i n d e p e n d e n t
of e a c h o t h e r .
c. T h e s p h e r e s g r o w u n t i l i m p i n g e m e n t . T h e g e n e r a l e q u a t i o n s w e will u s e are:
Ap.3.5.where
d x / d t = k l ( 1 -x) n
a n d : x = 1- exp. (- k l t )t
all t e r m s are t h e s a m e as a l r e a d y given in S e c t i o n 3 . 3 . We solve
t h e s e e q u a t i o n s b y a T a y l o r s e r i e s , i.e.-
Ap.3.6.-
-In(l-x)
= 1 +kt/2!
+kt2/3I
+kt 3/4!
If w e n o w d e f i n e T as a n i n s t a n t a n e o u s m o m e n t of t i m e , w e c a n g e t : Ap.3.7.-
( d x / dt)t = -c
T h i s c a n b e a r r a n g e d to:
= K n e -ki t
188
Ap.3.8.-
( dx/dt)t=l;
= nklt nl(1-
x)
If x is small, t h e n -
Ap.3.9.-
dx/dt = nklt nl
By d e f i n i n g s p h e r e s w h i c h are n u c l e a t e d at time, ~, t h e t i m e of g r o w t h b e c o m e s : (t - ~). If we n o w define Xext as t h e e . x ~ h m i e a m o u n t p e r n u c l e u s before g r o w t h s t a r t s (note t h a t it is n o t a r a d i u s ; in fact, it is t h e s a m e x given in Ap.3.5.), t h e n w e have: Ap.3.10.-
Xext = f
4 / 3 u U 3 {t - ~)I d~
w h e r e U - - v o l u m e of t h e nuclei. If we t h e n f u r t h e r define xf as t h e final a m o u n t of v o l u m e per sphere at i m p i n g e m e n t w h e r e g r o w t h s t o p s , i.e.- xf = 1- Xext, t h e n we get t h e J o h n s o n - M e h l e q u a t i o n for s l o w nu 9 Ap.3.11.-
xf = 1- exp. {( - 1 1 3 n I U
3 } t 4}
If t h e n u c l e a t i o n is fast, t h e A v r a m i e q u a t i o n is o p e r a t i v e : Ap.3.12.-
xf = 1- exp. {{ - 1 ! 3 n Nv U 3 } t 3}
w h e r e Nv is d e f i n e d as t h e n u m b e r of n u c l e i p e r u n i t v o l u m e . It is t h e s e two e q u a t i o n s w h i c h h a v e b e e n u s e d e x t e n s i v e l y to d e s c r i b e h o m o g e n e o u s n u c l e a t i o n , p a r t i c u l a r l y in p r e c i p i t a t i o n p r o c e s s e s . 9
A o o e n d i x IV _
_
Diffusion E q u a t i o n s R e l a t e d to F u n d a m e n t a l V i b r a t i o n s of t h e L a t t i c e R e f e r r i n g to t h e Fick E q u a t i o n s of diffusion, let u s n o w r e a x a m i n e
I/T ,
t h e j u m p f r e q u e n c y , so as to r e l a t e diffusion p r o c e s s e s to lattice v i b r a t i o n p r o c e s s e s . The reciprocal of t h e t i m e of s t a y is t h e j u m p f r e q u e n c y a n d is r e l a t e d to t h e dilh~sion coefficient by: AP.4.1.-
D = a 2 16"r, = a a 2 1 T
= a~a 2
189
where w = I/•
~ a n d I: is t h e j u m p f r e q u e n c y (The o t h e r f a c t o r s r e m a i n
t h e s a m e as a l r e a d y defined), w c a n b e r e l a t e d to t h e free e n e r g y of t h e l a t t i c e via a B o l t z m a n n d i s t r i b u t i o n , i.e.AP.4.2.-
- Wo a exp (-AGo / rt) = ~o r exp (-AS / R - AH / RT)
b y a s e r i e s of m a t h e m a t i c a l m a n i p u l a t i o n s . It t u r n s o u t t h a t Wo is the
atomic vflrational frequency or t h e zero phonon m o d e of t h e lattice, a n d that: AP.4.3.-
Wo = 112n ~ r ( K / m )
w h e r e K is t h e elastic c o n s t a n t of t h e l a t t i c e a n d m is t h e reduced m a s s of the
atoms composing
diffusion
the
lattice.
Note
t h a t we
have just related
the
coefficient, D, to t h e z e r o - p h o n o n m o d e of t h e lattice. T h i s is
r e a s o n a b l e s i n c e t h e j u m p f r e q u e n c y o u g h t to b e a f u n c t i o n of t h e p h o n o n v i b r a t i o n a l c o n s t a n t as w ell.
This Page Intentionally Left Blank
191
Chapter 5 Particles a n d Particle T e c h n o l o g y Solids ap p ear in one of two forms, either
as crystals or powders.
The
difference is one of size, since m a n y of the p o w d e r s we use are in reality very fine crystals. This, of course, d e p e n d s u p o n the m a n n e r in which the solid is prepared. Nevertheless, m o s t solids t h a t we e n c o u n t e r in the real world are in the form of powders. That is, they are in the form of discrete
small
particles of varying size. Each particle has its own u n i q u e d i a m e t e r and size. Additionally, their physical p r o p o r t i o n s can vary in s h a p e from s p h e r e s to needles.
For a given powder,
all grains will be the same shape, but t h e
particle s h a p e a n d size can be altered by the m e t h o d u s e d to create t h e m in the first place. Methods of particle formation include: Precipitation Solid state r e a c t i o n Condensation In this Chapter, we i n t e n d to investigate m e c h a n i s m s of particle growth. We wiU, in the next chapter, a d d r e s s the m e t h o d s u s e d to form (grow) single crystals an d how they have been utilized. Certain p r o p e r t i e s of particles, including m e a s u r e m e n t of size, will be d i s c u s s e d later in this chapter. But first, we need to define exactly w h a t we m e a n by a particle. In the previous chapter, we covered m e c h a n i s m s relating to solid state reactions, formation of nuclei a nd the rate of their growth in b o t h h e t e r o g e n e o u s a nd h o m o g e n e o u s solids. Still other p r o c e s s e s exist after particles have formed, including s e q u e n c e s in particle growth. We have already m e n t i o n e d p r e c i p i t a t i o a as one m e t h o d for obtaining d i s c r e t e particles. As indicated in the previous chapter, nucleation in p r e c i p i t a t i o n p r o c e s s e s can be h o m o g e n e o u s (no outside influences) or h e t e r o g e n e o u s (by specific outside coercion). In precipitation p r o c e s s e s to form a di st ri but i on of particle sizes, it is probably a c o m b i n a t i o n of b o t h m e c h a n i s m s .
192
5 . 1 . - SEQUENCES IN PARTICLE GROWTH We have already s h o w n t h a t embryo formation leads t o nucleation, and t h a t this n u cleatio n preceeds any solid state reaction or change of state. In a like m a n n e r , nuclei m u s t form in order for any precipitation process to p r o c e e d . Once formed, these nuclei t h e n grow until i m p i n g e m e n t of the g r o w i n g particles occurs. I m p i n g e m e n t implies t h a t all of the n u t r i e n t supplying t h e particle growth has been u s e d up. T hi s m e c h a n i s m applies to b o t h solid state reaction a n d precipitation p r o c e s s e s to form p r o d u c t particles. Then a process k n o w n as O ~ w a l d R i l ~ n l n g takes over. This process occurs even at ro o m t e m p e r a t u r e . The s e q u e n c e s in particle growth are: 5.1.1.-
Embryo f o r m a t i o n Nucleation Nuclei G r o w t h Impingement Ostwald Ripening (coarsening) Sintering For m at i on of Grain Boundaries
We have already covered the first three in some detail.
Impingement involves
the point where the growing particles actually t o u c h each other and have u s e d up all of the n u t r i e n t which h a d originally c a u s e d t h e m to s t a r t growing. Ostwald r i p e n i n g usually occurs bet w e e n particles, following i m p i n g e m e n t , wherein
larger particles grow at the expense
of the smaller ones.
One
example of this would be if one h a d a precipitate already formed in solution. In m a n y cases, the smaller particles redissolve and r e p r e c i p i t a t e on t h e larger ones, causing t h e m to grow larger. Interfacial tension b e t w e e n t h e particles is the driving force, a n d it is the surface area t h a t b e c o m e s minimized. Thus, larger particles, having a total lower surface area, i n c r e a s e at the expense of n u m e r o u s smaller particles which have a relatively high surface area.
193
Ostwald ripening differs from nuclei growth in t h a t the relative size and n u m b e r s of particles change, w h e r e a s in nuclei growth, the n u m b e r s of particles growing from nuclei do not change. Sintering, on the o t h e r hand, is an entirely different process, and usually occurs w h e n external heat is applied to the particles. 5.2. - SINTERING, SINTERING PROCESSES AND GRAIN GROWTH Sintering of particles occurs w h e n one h e a t s a s y s t e m of particles to an elevated t e m p e r a t u r e .
It is c a u s e d by an i nt eract i on of particle
surfaces
w h e r e b y the surfaces fuse t o g e t h e r and form a solid m a s s . It is related to a solid state reaction in t hat sintering is governed by diffusion processes, but no solid ~cat~ r e a c t i o n , or change of com p osi t i on or state, takes place. T h e best way to illustrate this p h e n o m e n o n is to use p o r e growth as an example. When a s y s t e m of particles, i.e.- a powder, is h e a t e d to high t e m p e r a t u r e , the particles do not u n d e r g o solid state reaction, u n l e s s there is m ore t h a n one c o m p o s i t i o n pr e s ent . Instead, the particles t h a t are t o u c h i n g each o t h e r will sinter, or fuse t o g e t h e r , to form o n e larger particle. S u c h a m e c h a n i s m is illustrated in the following diagram, given as 5.2.1. on the next page. As can be seen, voids arise w h e n the particles fuse together. The void space will d e p e n d u p o n the original s h a p e of the particles. In 5.2.1., we have shown spherical particles w hi c h p r o d u c e only a few voids. Additionally, an overall change in the total volume of the particles, a n d t hat of the fusion product, occurs. Mostly, the c ha nge is negative, but in a few cases, it is positive. Experimentally, this c h a n g e is a very difficult p r o b l e m to m e a s u r e . What has b e e n done is to form a long thin bar or rod by p u t t i n g the p o w d e r into a long thin mold a n d p r e s s i n g it in a hydraulic p r e s s at m a n y tons p e r square inch. One can t h e n
measure
the
change
of volume i n d u c e d
by
sintering, by m e a s u r i n g a change in length as related to the overall length of the rod.
194
It h a s b e e n found t h a t t h e s i n t e r i n g of m a n y m a t e r i a l s c a n be r e l a t e d to a p o w e r law, a n d t h a t t h e ~arlxflmge, AL, c a n be d e s c r i b e d 5.2.2.-
AL / L o
by:
= kt m
w h e r e k is a c o n s t a n t , Lo is t h e original l e n g t h , t is t h e t i m e of s i n t e r i n g , a n d t h e e x p o n e n t , m , is d e p e n d e n t u p o n the m a t e r i a l b e i n g i n v e s t i g a t e d . It h a s also b e e n f u r t h e r d e m o n s t r a t e d t h a t a c o n s i d e r a b l e difference e x i s t s b e t w e e n t h e s i n t e r i n g of Rne a n d c o a r s e p a r t i c l e s , as s h o w n in t h e following d i a g r a m , given as 5.2.3. on t h e n e x t page. In t h i s case, t h e "fine" p a r t i c l e s a n d t h e "coarse" p a r t i c l e s w e r e s e p a r a t e d so t h a t t h e difference in size b e t w e e n individual p a r t i c l e s w a s m i n i m i z e d . T h a t is, m o s t of t h e individual p a r t i c l e s in e a c h fraction w e r e
almost the same
size. Both t h e fine a n d c o a r s e p a r t i c l e s have a s i n t e r i n g slope of 1 / 2 b u t it is t h e c o a r s e p a r t i c l e s w h i c h s i n t e r to form a solid having a d e n s i t y c l o s e s t to
195
theoretical density. This is an excellent exaumple of the effect of pore volume, or void formation, and its effect u p o n the final density of a solid formed by powder c o m p a c t i o n and sintering techniques. Quite obviously, the fine particles give rise to m a n y m or e voids t h a n the coarser particles so t h a t t h e attained density of the final s i nt er ed solid is m u c h less t h a n for the solid p r e p a r e d using coarser particles. It is also clear t hat ff one wishes to obtain a s i n t e r e d p r o d u c t with a density close to the theoretical density, one needs to start with a particle size distribution having particles of varied d i a m e t e r s so t h a t void volume is m i n i m i z e d . The next illustrate aggregate s h o wn in
subject we will discuss is t hat of grain growth. The si m pl est way to this factor is t h r o u g h the s i nt eri ng behavior of aggregates. An is defined a large particle, c o m p o s e d of m a n y small particles, as the following diagram, given as 5.2.4. on the next page.
In this diagram, two steps are implicit. It is t h e aggregates, c o m p o s e d of very fine specks, w h i c h sinter to form larger grains (particles).
196
But, since m a n y particles are growing at the same time, growth occurs until i m p i n g e m e n t . The formation of b o u n d a r i e s b e t w e e n the particles (grains) growing t h u s results. It is these grains which form the final sintered whole. Note that the crystallographic orientation of each grain differs from that of its neighbors, as illustrated in the above diagram. When a system of very fine particles is formed, the interfacial tension is high due to the very high surface area present. Agglomerates (weak surface e n e r g y interchange) will form, or a 4 j [ ~ ~ a t e s (strong surface energy i n t e r c h a n g e ) can result, especially ff the Ostwald ripening m e c h a n i s m is slow, or is inhibited. I m m e d i a t e removal of a precipitate from its "mother liquor" is one example w h e r e the likelihood of aggregate formation is e n h a n c e d . S i n t e r i n g t h e n p r o d u c e s both pore growth a n d grain growth. This m e c h a n i s m also applies to powder compaction p r o c e s s e s w h e r e aggregates m a y be p r e s e n t in the powder. Sintering t h e n leads to grain growth as well. It should be clear, then, that the precipitation process n e e d s to be controlled carefully in order to p r o d u c e a material c o m p o s e d of particles of a desired configuration. Both Ostwald riping a n d sintering can be utilized to obtain a particle of desired size, d i m e n s i o n s and particle habit. Industrial technologists have t a k e n advantage of these particle forming a n d altering
197
m e c h a n i s m s . One example of this type of particle growth is described as follows. In fluorescent lamps, a layer of p h o s p h o r s is applied to the inside of a glass tube by m e a n s of a s u s p e n s i o n of particles, i.e.- the h a l o p h o s p h a t e p h o s p h o r having a composition of: (MsF, CI(PO4)s: Sb ~+ Mn 2+ (plus m i n o r a m o u n t s of other p h o s p h o r s to achieve certain "colors"). It has b e e n d e t e r m i n e d that the lamp b r i g h t n e s s and duration of light o u t p u t (maintenance) is highly d e p e n d a n t u p o n how well the the internal surface of the glass is covered by the particles. By m a i n t a i n i n g precipitation conditions so t h a t small t h i n s q u a r e s of CaHP04 result from the precipitating solution, a m a x i m u m coverage of the glass is achieved. Precipitation occurs by adding a solution of (NH4)2HP04 to a solution of CaCI~. The resulting precipitate is consists of very fine particles a n d is not very crystalline. As a m a t t e r of fact, the p a r t i c l e s were usually ill-defined a n d b o r d e r e d u p o n a m o r p h o u s . The solution t e m p e r a t u r e is t h e n raised so t h a t Ostwald ripening can occur. As the larger crystaUites begin to grow, the smaller ill-defined crystallites, having a m u c h larger surface area, dissolve a n d r e p r e c i p i t a t e u p o n the larger ones. T h e resulting single-crystal squares, i.e.- El, have an average size of about 25~m. The solid state reaction to form the h a l o p h o s p h a t e p h o s p h o r is: 5.2.5.-
6 CaHPO 4 + 3 CaCY)~ + ~ 2
~
2 C ~ F (P04) a
w h e r e we have not shown the Sb20~ a n d MnCOs a d d e d as "activators". T h e h a l o p h o s p h a t e t h u s p r o d u c e d follows the crystal habit of the m a j o r ingredient, in this case that of CaHP04 habit. When applied, the thin s q u a r e s lie fiat a n d overlap on the glass surface. During sintering at about 1200 ~ the CaHP04 does not disintegrate b u t u n d e r g o e s an internal r e a r r a n g e m e n t to form (M~207 while m a i n t a i n i n g the s a m e crystal habit. The CaCX)3 disintegrates into small particles (like BaCOn) while CaF2 exhibits a sublimation p r e s s u r e at the firing t e m p e r a t u r e . The resulting solid state reaction to form the h a l o p h o s p h a t e p r o d u c t thus d e p e n d s u p o n the crystal habit of the major ingredient, CaHPO4.
198
The same type of m e c h a n i s m s apply to other materials. Even where a m e t a l is melted an d t h e n cast, nucleation leads to formation of m a n y fine p a r t i c l e s in the sub-solidus (partially solidified) state. This leads to grain growth in t h e solid metal, thereby lowering its strength. Sometimes, special additives are added to the melt to slow nucleation during cooling, t hereby increasing t h e s t r e n g t h of the metal p r o d u c t . Another example is our old friend, BaC03. If we fire this solid c o m p o u n d in air at a very high t e m p e r a t u r e for a long time, we get several changes. First, it d e c o m p o s e s to very free particles of BaO. These fine particles have a large surface area, and with c o n t i n u e d ruing sinters to form larger particles. Eventually, the particles get big enough, a n d the porosity decreases to t h e point wh er e grain b o u n d a r i e s begin to form between particles. The grains sinter together to form a large particle with m a n y grain boundaries. It should be again be e m p h a s i z e d t h a t each grain in the large particle is essentially a small single crystal with its lattice oriented in a slightly different d i r e c t i o n from th at of it neighbors (see 5.2.4.). Let us now consider the t h e r m o d y n a m i c s of sintering. There are two types of sintering which are d i s t i n g u i s h e d by the change in volume which occurs. These are: 5.2.6.-
NO SHRINKAGE :
dV/dt = 0
WITH SHRINKAGE :
d V / d t = f(V)
As we have already said, the c ha nge in volume, from initial state to final state, can be positive or negative, but is usually negative. The driving force is a d e c r e a s e in Gibbs free energy, AG. It is related to both the interfacial t e n s i o n (surface energy), V, a n d the surface energy of the particles (which is r e l a t e d to their size), viz5.2.7.-
d G = y dA
199
C o n s i d e r a m o r e f a m i l i a r e x a m p l e , t h a t of a d r o p l e t s i t t i n g u p o n t h e s u r f a c e of a l i q u i d . T h e d r o p l e t h a s a r a d i u s , r, a n d t h e r e a r e n - m o l e s of liquid w i t h i n it w i t h a m o l a l v o l u m e , V. To f o r m t h e d r o p l e t r e q u i r e s a n a m o u n t , nV, of t h e liquid, w h e r e V is t h e f r a c t i o n a l m o l a r v o l u m e of t h e d r o p l e t . T h i s gives us: 5.2.8.-
nV = 4 / 3 n r 3
a n d t h e c h a n g e in free e n e r g y to f o r m t h e d r o p l e t is: 5.2.9.-
dG = A G d n
= y dA
If w e n o w d i f f e r e n t i a t e t h e s e e q u a t i o n s , i.e.5.2.10.-
V o l u m e of Droplet: n = 4n r 3 / 3 V
so t h a t : (In = 4n /V r 2 d r
and: S u r f a c e A r e a of Droplet:
A = 4n r 2 so t h a t :
dA = 8n r d r
we c a n p u t all of t h e e q u a t i o n s t o g e t h e r so as to yield t h e Kelvin e q u a t i o n for c h a n g e in free e n e r g y as a f u n c t i o n of t h e r a d i u s of t h e s p h e r i c a l p a r t i c l e : 5.2.11.-
AG = 2 y
V/r
O n e c a n do t h e s a m e for a c u b i c p a r t i c l e , in fact for a n y s h a p e factor. S i n c e t h e c h e m i c a l p o t e n t i a l , p , is r e l a t e d to AG, w e u s e t h e following e q u a t i o n s : 5.2.12.-
-Po 2y
=AG=RTlnp/po
V /r
or: p = p o
=
RTInp/po exp (2 y V / r R T )
If w e n o w define ~p = p - Po , t h e n :
200
5.2.13.-
P/Po
=
1 + Ap/po
M a t h e m a t i c a l l y , In (I + Ap / Po ) -= AP / Po (within 5% ff ~ p / Po
>_ 0 . I ) . T h u s
we get t h e a p p r o x i m a t e e q u a t i o n : 5.2.14.-
Ap/po
=
2yV
/r-I/RT
It is t h i s e q u a t i o n w h i c h h a s b e e n u s e d m o r e t h a n any o t h e r t o
s i n t e r i n g . To e v a l u a t e its use, c o n s i d e r t h e following e x a m p l e . A l u m i n a , A1203, is a v e r y r e f r a c t o r y c o m p o u n d . It m e l t s above 1 9 5 0 ~
and
is n o t v e r y r e a c t i v e w h e n h e a t e d . If we a t t e m p t to s i n t e r it at 1730~
we
f'md t h e following v a l u e s to apply: 5.2.15.-
~P/Po y
=- 0. I
-= 2 0 0 0 d y n e / c m .
V = M/d = 25.4 cc./mol R
= 8.3 x 10 -7 e r g / m o l
r
= 6x
10 - 6 c m
=0.06micron
W h a t t h i s m e a n s is t h a t ff t h e a l u m i n a p a r t i c l e s are s m a l l e r t h a n a b o u t 0 . 0 6 m i c r o n , t h e y will n o t s i n t e r .
E v e n t h o u g h t h e above is a n a p p r o x i m a t i o n , t h e
specific c a s e for a l u m i n a h a s b e e n c o n f i r m e d e x p e r i m e n t a l l y . THUS, WE HAVE SHOWN THAT IF T H E PARTICLES ARE TOO SMALL, T H E Y WILL NOT
SINTER.
NORMAL NUCLEI
GROW22-1 T H R O U G H
DIFFUSION
P R O C E S S E S REMAINS T H E NORM UNTIL T H E PARTICLES G E T LARGE ENOUGH TO S I N T E R . Let u s n o w e x a m i n e w h y t h i s m e c h a n i s m
might
be t r u e .
In t h e
c a s e of
s i n t e r i n g of s p h e r e s , w e c a n define two c a s e s as before, t h a t of no s h r i n k a g e a n d t h a t of s h r i n k a g e , b o t h as a f u n c t i o n of v o l u m e . If we h a v e two s p h e r e s in
201
direct c o n t a c t , we c a n define c e r t a i n p a r a m e t e r s , as s h o w n in t h e following diagram:
We s t a r t w i t h s p h e r e s of radius, r, in direct contact. The two c a s e s s h o w n are: 1) n o ~ll-lnkage
2} w i t h s h r i n k a g e , Actual s i n t e r i n g o c c u r s by flow of m a s s from e a c h s p h e r e to the m u t u a l p o i n t of contact, w h i c h gradually t h i c k e n s . We cmn e s t i m a t e t h e v o l u m e of m a s s , V, at the c o n t a c t area, A, in t e r m s of the foUov~mg p a r a m e t e r s : r, t h e r a d i u s of the s p h e r e s ; p , the t h i c k n e s s of the layer buildup; a n d x, the r a d i u s of c o n t a c t of the b u i l t - u p layer. If we have s h r i n k a g e , t h e n we m u s t also evaluate h, the a m o u n t of s h r i n k a g e , s h o w n above as t h e h e i g h t of i n t e r l i n k i n g layer. This m o d e l b r i n g s u s to an i m p o r t a n t point, vis: If t h e s p h e r e s are too small, t h e r e c a n be little m a s s flow to t h e a r e a of joining (sintering) of t h e s p h e r e s . Actually, it is the r a t e of flow of m a s s to t h e joining a r e a t h a t is i m p o r t a n t a n d the a r e a of t o u c h i n g of t h e s p h e r e s vail d e t e r m i n e this.
202
It is therefore logical that a size l i m i ~ should apply to the case of s i n t e r i n g a n d its m e c h a n i s m s . If the s p h e r e s are too small, t h e n t h e r e is n o t e n o u g h t o u c h i n g area a n d v o l u m e for the s i n t e r i n g m e c h a n i s m to o c c u r . The actual values of the s i n t e r i n g p a r a m e t e r s have b e e n found to be: 5.2.17.VALUES OF SINTERING PARAMETERS V h A No S h r i n k a g e
nx21 2 r
0
n2x21r
x2/2r
n2x3 / 2r
x 2 / 4r
,
With Shrinkage
nx 2 / 2r
x2 / 2r
M o s t s y s t e m s exhibit s h r i n k a g e in s i n t e r i n g a n d it h a s b e e n f o u n d t h a t t h e
following e q u a t i o n applies: AL / L o = h / r
5.2.18.-
andx=ct
m
w h e r e t is the time of sintering, h is a c h a r a c t e r i s t i c s i n t e r i n g c o n s t a n t for shrinkage,
and m
is an e x p o n e n t
dependent
upon
the
mechanism
of
sintering. We have i n d i c a t e d t h a t flow of m a s s is i m p o r t a n t in sintering. T h e r e are several operative m e c h a n i s m s w h i c h are d e t e r m i n e d by the type of m a t e r i a l involved. Actually, the s t u d y of s i n t e r i n g d e s e r v e s a s e p a r a t e c h a p t e r , b u t w e will only s u m m a r i z e the m a j o r m e c h a n i s m s t h a t have b e e n o b s e r v e d for t h e c o n s t a n t s of 5.2.18. T h e s e are given in 5.2.19. on the next page. Note t h a t the values of h d e p e n d s u p o n the m a t e r i a l a n d the m e c h a n i s m of sintering. Also, t h e s e values d e p e n d u p o n r a n d x, the radii of t h e p a r t i c l e s a n d the r a d i u s of joining. T h e s e
e q u a t i o n s apply only to s p h e r o i d s a n d a
s h a p e factor m u s t be c o n s i d e r e d as well.
203
5.2.19.-
SINTERING MECHANISMS Mechanism Viscous flow .
.
.
.
.
.
Evaporation-Condensation Grain b o u n d a r y diffusion Vacancy F o r m a t i o n Volume diffusion
1
1/ 3
~./~
by ~/4
Grain b o u n d a r y diffusion by 1 / 6 .
.
.
.
Glass
1/2
1/ 5
Intersitial F o r m a t i o n
Material
h
m
o
= .
.
.
.
.
NaCI
1/ 2
.
.
2/5 .
.
.
Cu, Ag
1/ 3
.
Surface diffusion
1/7
5L/Lo = 0
Ice
The derivation b e c o m e s m u c h m o r e difficult a n d is beyond the scope of this chapter. The reader is referred to specific references on sintering and sintering m e c h a n i s m s . 5.3.-
PARTICLE SIZE
Most solids t h a t we actually deal with are powders. The powder is c o m p o s e d of discrete particles, a n d each particle m a y be single crystal or contain grain boundaries. The size of the particles are of i n t e r e s t to us because m a n y of their chemical a n d physical p r o p e r t i e s are d e p e n d e n t u p o n particle size. For example, the "hiding power" of p i g m e n t s is d e p e n d e n t u p o n the size of t h e p i g m e n t particles, a n d in particular the distributions of sizes of the particles. There is an o p t i m u m particle size distribution to obtain m a x i m u m h i d i n g power, d e p e n d i n g u p o n the specific application. P h a r m a c e u t i c a l s are a n o t h e r p r o d u c t w he r e particle size (PS) a n d particle size distribution (PSD) are i m p o r t a n t . The effectiveness of dosage and ingestion d e p e n d s u p o n t h e p r o p e r PSD. Particles are usually defined by their d i a m e t e r since m o s t are spheroid. We use the m i c r o n as a base, i.e.5.3.1.-
1 ~ (micron) = 10 -6 m e t e r
= 10 "4 c e n t i m e t e r .
The following defines particle r a n g e s t h a t we usually e n c o u n t e r in solid state chemistry:
204
5.3.2.PARTICLE RANGES Range
.Centime.ter .s
~
Description
Macro
1.0 - 0 . 0 5
104 - 5 0 0
Gravel
Micro
0.01- 0.0001
I 0 0 - 1.0
"Normal"
Sub-micro
0.0001-
1.0 - 0 . 0 0 1
Colloidal
It is e a s i e r to d e s c r i b e
10 -7
PS in t e r m s
of m i c r o n s
rather
than meters
or
centimeters. In t h e r e a l world, we e n c o u n t e r p a r t i c l e s in a v a r i e t y of forms, a l t h o u g h w e m a y n o t r e c o g n i z e t h e m as s u c h . In t h e following d i a g r a m , given as 5.3.3. o n t h e n e x t p a g e , are s u m m a r i z e d m a n y of t h e p a r t i c l e s of i n t e r e s t . At t h e top of t h e d i a g r a m , t h e p a r t i c l e d i a m e t e r s in m i c r o n s is s h o w n . I m m e d i a t e l y b e l o w are s t a n d a r d s c r e e n sizes, i n c l u d i n g b o t h U. S. a n d Tyler s t a n d a r d m e s h . S c r e e n s are m a d e b y t a k i n g a m e t a l w i r e of specific
diameter
and cross-
w e a v i n g it to f o r m a s c r e e n w i t h specific h o l e sizes in it. T h u s , a 4 0 0 m e s h s c r e e n will p a s s 37~ p a r t i c l e s or s m a l l e r , b u t h o l d u p all t h o s e w h i c h
are
larger. A 6 0 m e s h s c r e e n will p a s s u p to 250~ p a r t i c l e s , etc. (U. S. S c r e e n Mesh). T h i s d i a g r a m p l a c e s a n d d e f i n e s t h e size of m o s t of t h e p a r t i c l e s t h a t we a r e likely to e n c o u n t e r
in t h e
real world.
On the
left
a n g s t r o m s (/~) a n d m i c r o n s u p to 1 ~ = 10, 0 0 0 A .
is a c o m p a r i s o n In t h e m i d d l e
of
of t h e
s e c t i o n , " E q u i v a l e n t S i z e s " , is a c o m p a r i s o n of sizes a n d " t h e o r e t i c a l m e s h " . W h y t h e l a t t e r t e r m is s o m e t i m e s u s e d will b e d i s c u s s e d later. In " T e c h n i c a l Definitions", size r a n g e s a r e given for v a r i o u s t y p e s of solids in g a s e s , l i q u i d s in g a s e s , a n d t h o s e for soft. In a d d i t i o n , we h a v e a s e p a r a t e c l a s s i f i c a t i o n for w a t e r in air (fog). Finally, t h e r e products
and
by-products
we
is a c l a s s i f i c a t i o n for v a r i o u s c o m m e r c i a l might
encounter,
including
viruses
and
b a c t e r i a . Note t h e v a r i e d sizes of p a r t i c l e s t h a t we n o r m a l l y e n c o u n t e r . T h i s l i s t i n g is n o t m e a n t to b e all- i n c l u s i v e b u t o u t l i n e s m a n y a r e a s of t e c h n i c a l i n t e r e s t w h e r e t h e sizes of p a r t i c l e s are i m p o r t a n t .
205
206
Now let u s b e g i n to m o r e clearly define t h e a g g r e g a t e p r o p e r t i e s of p a r t i c l e s . Let u s t a k e a 1.00 cm. c u b e a n d c u t it into f o u r t h s , viz5.3.4.-
NUMBERS
mmmmele
mUll(),
SURFACE
- 43
_ 64
= ( 6 4 ) ( 6 )( I/4 )2 = 0 . 0 0 9 6 sq. m .
mmmm
Now we t a k e t h e s a m e c u b e a n d divide it into 1.0 ~ c u b e s , w i t h t h e f o l l o w i n g result: 5.3.5.-
I~ c u b e s = 10 4 c u t s in 3 - d i m e n s i o n s D i a m e t e r = 1.0 x i 0 -6 m 3 for e a c h p a r t i c l e Number
= ( 104) 3 = 1.0 x 1012 p a r t i c l e s
Surface
= (6) (1.0 x 1012) (1.0 x 10-6) 2 - 6 . 0 sq. m e t e r s
We h a v e d i s c o v e r e d two facts a b o u t p a r t i c l e s : a) T h e r e
are large n u m b e r s p r e s e n t
in a relatively s m a l l a m o u n t of
m a t e r i a l (we s t a r t e d w i t h a 1-cm. cube). And: b) T h e total s u r f a c e a r e a c a n be q u i t e large a n d d e p e n d s u p o n t h e size of t h e p a r t i c l e s . S i n c e t h e r a t e of solid s t a t e r e a c t i o n d e p e n d s u p o n s u r f a c e area, we c a n s e e t h a t very s m a l l p a r t i c l e s o u g h t to r e a c t m u c h f a s t e r t h a n large p a r t i c l e s .
207
A n o t h e r o b s e r v a t i o n is t h a t solid s t a t e r e a c t i o n s involving very fine p a r t i c l e s o u g h t to be very fast in t h e b e g i n n i n g , b u t t h e n will slow down as the p r o d u c t p a r t i c l e s b e c o m e larger. T h e r e are o t h e r p r o p e r t i e s
of p a r t i c l e s w h i c h w e
c a n t h i n k of, as follows: 5.3.6.-
PROPERTIES OF PARTICLES
Size
Surface a r e a
Porosity
Aggregates
Agglomerates
Shape
Density
Pore size
Numbers
Size d i s t r i b u t i o n
At this point, we are m o s t i n t e r e s t e d in t h e size of p a r t i c l e s a n d how t h e o t h e r factors r e l a t e to the q u e s t i o n of size. T h e n e x t m o s t i m p o r t a n t factor is s h a p e . Most of the p a r t i c l e s t h a t we will e n c o u n t e r are s p h e r o i d a l or o b l o n g in s h a p e , b u t ff we discover t h a t we have n e e d l e - l i k e (acicular) particles, h o w do we define t h e i r average d i a m e t e r ? Is it a n average of the s u m of l e n g t h plus c r o s s - s e c t i o n , or w h a t ? 5.4.-
PAR~CLE DISTRIBUTIONS
F u n d a m e n t a l to p a r t i c l e t e c h n o l o g y is t h e f a c t o r , s / z e distribution. By this, w e m e a n t h e n u m b e r of e a c h size in a given collection of particles. F r o m a close e x a m i n a t i o n of 5.3.3., it is evident t h a t we m u s t deal w i t h large n u m b e r s of particles, even w h e n we have a small s t a r t i n g s a m p l e weight. This p r o b l e m b e c o m e s c l e a r e r ff we c o r r e l a t e n u m b e r s of p a r t i c l e s w i t h size, s t a r t i n g w i t h a cube, one (1) c m in size, as in 5.3.4. , a n d m a k e the c u t s i n d i c a t e d in 5.4.1, given on the n e x t page. Having done so, we m i x t h e seven (7) s e p a r a t e p r o d u c t s . We could t h e n p l o t the p a r t i c l e d i s t r i b u t i o n as s h o w n in 5.4.2.,
also given on the n e x t page,
w h e r e we have p l o t t e d the log of t h e size of p a r t i c l e s in m i c r o n s vs: the log of the n u m b e r of p a r t i c l e s c r e a t e d . Obviously, t h e r e is a linear r e l a t i o n s h i p b e t w e e n t h e two variables. T h e o t h e r factor to n o t e is t h a t this d i s t r i b u t i o n c o n s i s t s of specific (discrete) sizes of p a r t i c l e s .
208
5 . 4 . 1 . - V a r i o u s Sized C u t s of a O n e C e n t i m e t e r Cube
5.4.2.-
Size 1 ~
Number / cm 3 1.0 x 1012
I0 ~
1.0 x 109
50/J
8.3 x 106
100 ~
1.0 x 106
2 5 0 la
6.4 x 104
500 ~
8.3 x 103
1000 ~
1.0 x 103
A D I S C R E T E P O P U I ~ T I O N OF PARTICLES to
L.
12
E c
13
0
~ 0
4
0
1
2
log p
3
In N a t u r e , h o w e v e r , w e always h a v e a c o n t i n u o u s d i s t r i b u t i o n of p a r t i c l e s . T h i s m e a n s t h a t we h a v e all sizes, even t h o s e of f r a c t i o n a l p a r e n t a g e , 18.56V,
18.57V,
differences). formation,
The i.e.-
18.58
~, etc.
reason
(supposing
for t h i s
precipitation,
is
embryo
that and
that we the
can measure
mechanisms
nucleation
for
growth,
i.e.-
0.01 particle Ostwald
r i p e n i n g , a n d s i n t e r i n g , are rm~_d_c~n p r o c e s s e s . T h u s , w h i l e we m a y s p e a k of t h e " s t a t i s t i c a l v a r i a t i o n of d i a m e t e r s " , a n d w h i l e we u s e w h o l e
n u m b e r s for
t h e p a r t i c l e d i a m e t e r s , t h e a c t u a l i t y is t h a t t h e d i a m e t e r s a r e f r a c t i o n a l in n a t u r e . Very few * p a r t i c l e - s i z e " s p e c i a l i s t s s e e m to r e c o g n i z e t h i s fact. S i n c e the processes
are r a n d o m in n a t u r e , we c a n u s e s t a t i s t i c s to d e s c r i b e
the
209
properties
of a p o p u l a t i o n of p a r t i c l e s ,
and the particle
size d i s t r i b u t i o n .
S t a t i s t i c a l c a l c u l a t i o n is well s u i t e d for t h i s p u r p o s e s i n c e it w a s o r i g i n a l l y d e s i g n e d to h a n d l e large n u m b e r s in a p o p u l a t i o n . It s h o u l d b e c l e a r t h a t w e do h a v e a p o p u l a t i o n of p a r t i c l e s in a n y given p a r t i c l e d i s t r i b u t i o n . 5.5,-
PARTICLE D I S T R I B U T I O N S AND T H E BINOMIAL T H E O R E M
To d e s c r i b e p a r t i c l e d i s t r i b u t i o n s , we will u s e o u r o w n n o m e n c l a t u r e ,
but
will s o o n find t h a t it is r e l a t e d to t h e s c i e n c e of s t a t i s t i c s a s well. We b e g i n b y t h e u s e of t h e P r o b a b i l i t y Law. If we are given n - t h i n g s w h e r e w e c h o o s e x v a r i a b l e s , t a k e n r at a t i m e , t h e i n d i v i d u a l p r o b a b i l i t y of c h o o s i n g (1 + x) will be: 5.5.1.-
Pi = (I + x ) n
T h i s is t h e BINOMIAL T H E O R E M . U s i n g a T a y l o r E x p a n s i o n , w e c a n find t h e t o t a l p r o b a b i l i t y for i t e m s t a k e n r a t a t i m e as: 5.5.2.-
P(r) =
In}
pr (I - p ) n - r
----
nCr = n ! / r ! ( n - r ) !
where5.5.3.
{ n~
{ r} If we n o w let n a p p r o a c h infinity, t h e n w e get5.5.4.-
P(r)
= E Pi = I / [ 2n n p ( I -p)] I/2 . exp (- x 2 / 2 n p ( I -p)
One will i m m e d i a t e l y r e c o g n i z e t h i s as a f o r m of t h e BOLTZMANN e q u a t i o n , or t h e GAUSSIAN LAW. We c a n m o d i f y t h i s e q u a t i o n a n d p u t it into a f o r m m o r e s u i t a b l e for o u r u s e b y m a k i n g t h e following d e f i n i t i o n s .
210
m
First, w e d e f i n e a m e a n (average) size of p a r t i c l e s in t h e d i s t r i b u t i o n as d , a n d t h e n d e f i n e w h a t w e call a " s t a n d a r d d e v i a t i o n " as o, for t h e d i s t r i b u t i o n of p a r t i c l e s .
From
statistics,
we
know
that this means
that
68%
of t h e
p a r t i c l e s a r e b e i n g c o u n t e d (34% o n e i t h e r s i d e of t h e m e a n , d), i.e. m
5.5.5.where
Z(d
+do)
=0.68
do is t h e d i a m e t e r
measured
to give + 3 4 % of t h e t o t a l n u m b e r
of
p a r t i c l e s . In a l i k e m a n n e r : m
5.5.6.-
Note
that
2o
----
0.954
=
Z(d • d2o)
3o
----_
0.999
=
Z(d +d3o)
these
standard
deviations
only
apply
if w e
have
a Gaussian
d i s t r i b u t i o n . In t h i s w a y , w e c a n s p e c i f y w h a t f r a c t i o n w e h a v e of t h e t o t a l d i s t r i b u t i o n , or l o c a t e p o i n t s in t h e d i s t r i b u t i o n . By f u r t h e r d e f i n i n g : m
5.5.7.-
npi
~-
o
---- ( n p ( 1 - p ) 1/2 = s t d . dev.
fl
r
~
np+x
= d
+x
=
(d-d)
w e c a n o b t a i n e x p r e s s i o n s to d e s c r i b e a p a r t i c l e d i s t r i b u t i o n w h e r e w e h a v e u s e d x as a d e v i a t i o n f r o m t h e m e a n . T h i s t h e n b r i n g s u s to t h e e x p r e s s i o n
for t h e GAUSSIAN PARTICLE S I Z E
D I S T R I B U T I O N , as s h o w n in t h e f o l l o w i n g : m
5.5.8.-
Pr =
1
exp ( - [ d -
(2n) II2 o
2 02
d ]2)
if: { _ o o < d < + o o } Let u s n o w e x a m i n e a G a u s s i a n d i s t r i b u t i o n . A p l o t is s h o w n as follows:
211
W h a t we have is the familiar "Bell-Shaped" curve. T h i s d i s t r i b u t i o n h a s b e e n variously called: 5.5.10.Gaussian Log N o r m a l Boltzmann Maxwell - B o l t z m a n n We shall u s e the t e r m "Log Normal" for r e a s o n s w h i c h will clear later. It s h o u l d be now a p p a r e n t t h a t we u s e t e r m s b o r r o w e d from statistics a n d a statistical
approach
to
describe
a
distribution
of
particles.
The
two
disciplines are well s u i t e d to e a c h o t h e r since s t a t i s t i c s is easily capable of h a n d l i n g large a s s e m b l a g e s , a n d the solid s t a t e p r o c e s s with vchich we deal are r a n d o m g r o w t h p r o c e s s e s w h i c h p r o d u c e large n u m b e r s of p a r t i c l e s . Let
us
now
give
some
examples
of
the
log-normal
distribution.
A
r e p r e s e n t a t i o n of several t y p e s of t h e s e d i s t r i b u t i o n s is given on the n e x t page as 5 . 5 . 1 1 . In this diagram, the p a r a m e t e r s of the various log n o r m a l d i s t r i b u t i o n s are
212
c o mp ar ed . Here, d is the average particle size, is the s p r e a d of the p a r t i c l e size distribution and A is the area, i.e.- the total n u m b e r of particles p r e s e n t in the particle distribution. Note t hat each distribution can look quite different from the others, d e p e n d i n g u p o n the values of the p a r a m e t e r s involved. Thus, in Case A, the three distributions differ in n u m b e r s only, t h e average d i a m e t e r s of the distribution being equal as well as the s p r e a d of t h e distribution, i.e.- o. But in Case B, the two distributions have the s a m e n u m b e r s of particles b u t not the s a m e s p r e a d of particles. Yet, in all of t h e s e cases, each particle distribution r e m a i n s a log-normal distribution and conforms to the definition of a Gaussian distribution. Thus, it s h o u l d be clear t h a t one c a n n o t d e t e r m i n e if a particle distribution is truly log-normal j u s t by the a p p e a r a n c e of plotted data. That is only decided by plotting the p a r t i c l e data on a log-normal plot and d e t e r m i n i n g if the distribution c o n f o r m s .
213
5 . 6 , - MEASURING PARTICLE D I S T R I B U T I O N S O u r n e x t t a s k is to d e t e r m i n e h o w to m e a s u r e a PSD. We k n o w t h a t we c a n specify a m e a n d i a m e t e r , b u t h o w do we o b t a i n it? T h e following is a s i m p l e e x a m p l e i l l u s t r a t i n g o n e m e t h o d of d o i n g so. S u p p o s e w e o b t a i n a s a m p l e of b e a c h s a n d . F r o m 5 . 3 . 3 . , we c a n see t h a t t h e p a r t i c l e s are liable to r a n g e f r o m a b o u t 8la to 2 4 0 0 ~. In o r d e r to g e n e r a t e a PSD, we m u s t s e p a r a t e t h e p a r t i c l e s . One w a y we c a n s e p a r a t e s u c h p a r t i c l e s is b y seiving t h e m . But w e find t h a t seives are only available in c e r t a i n sizes, as s h o w n in t h e following: 5 . 6 . 1 . - COMPLETE LISTING OF ALL SEIVE SIZES AVAILABLE- (U.S. STD.) Seive No.
Microns
Permissible Variati0n{%}
Seive N0.
Microns
.........................
Permissible Variationf%)
3.5
5660
• 3
40
420
• 5
4
4760
• 3
45
350
• 5
5
4000
+ 3
50
297
• 5
6
3360
• 3
60
250
• 5
7
2830
• 3
70
210
• 5
8
2380
+_ 3
80
177
• 6
10
2000
+ 3
100
149
•
,,,
,
,,
.
.
.
.
12
1680
• 3
170
88
+
14
1410
• 3
200
74
•
16
1190
• 3
230
62
•
18
I000
• 5
270
53
•
20
840
• 5
325
44
+ 7
25
710
• 5
400
37
• 7
30
590
+_ 5
35
600
+ 5
214
There
a r e two t y p e s of s t a n d a r d s c r e e n s , t h e U.S. a n d t h e Tyle r s t a n d a r d
s c r e e n s . We h a v e given t h e U.S. s c r e e n values. T h o s e of t h e Tyle r a r e v e r y s i m i l a r , e.g. - #5 Tyler = 3 9 6 2 ~ , # 20 = 8 3 3 ~, a n d # 4 0 0 = 38 p. To s c r e e n o u r s a n d s a m p l e , w e c h o o s e to e m p l o y t h e following seives: #10, # 18, # 2 0 , #30, # 4 0 , #50, #80, # 1 0 0 , #170, #200, #270, #325 & #400. Now ff w e s c r e e n t h e s a n d w i t h t h e # I 0
screen,
all p a r t i c l e s l a r g e r t h a n
2 0 0 0 + 6 0 p will b e r e t a i a e d u p o n t h e s c r e e n . T h e n e x t s t e p is to r e s c r e e n t h e p a r t t h a t I m a ~ d t h r o u g h t h e # 10 s c r e e n , u s i n g t h e # 18 s c r e e n , to o b t a i n a f r a c t i o n w h i c h is > 1 0 0 0 ~ + 50p. We t h e n r e p e a t t h i s p r o c e d u r e to o b t a i n a s e r i e s of f r a c t i o n s . T h e r e s u l t s a r e given in t h e following: m
5.6.2.-
Fractions Obtained fo > 2 0 0 0 p
Mean diameter d do
l O001a < fl < 2 0 0 0 la
1500
dl
8401a < f2 < 1 0 0 0
920
d2
590ja
< f3 < 8 4 0
715
d3
4 2 0 p < f4 < 5 9 0 p
505
d4
2 9 7 p < f5 < 4 2 0 p
358
d5
177ja < f6 < 2 9 7 la
237
d6
1491a < f7 < 177
163
d7
88
Ja
< 1491a
118
d8
77 la < f9 < 88
83
d9
53 ~ < flO < 77
68
dlO
44ja
< 53
49
dll
37 p < f12 < 4 4
41
d12
f13 < 37 lu
do
215
We n o w h a v e 12 f r a c t i o n s t h a t we c a n use. T h e m e a n d i a m e t e r is a p p a r e n t f r o m t h e s c r e e n s u s e d to s e p a r a t e t h e fractions. In t h e last c a s e t h a t we c a n use, d'-12 = 4 1 + 2 . 8 ~ . We c a n n o w w e i g h e a c h f r a c t i o n a n d c a l c u l a t e the % w e i g h t in e a c h fraction, p r o v i d i n g we u s e t h e total w e i g h t of all 14 f r a c t i o n s . K n o w i n g t h e d e n s i t y of the s a n d , a n d a s s u m i n g t h e p a r t i c l e s to be s p h e r e s , we c a n t h e n o b t a i n t h e
n u m b e r of p a r t i c l e s in e a c h fraction. (Note t h a t w e
have a s s u m e d t h a t all p a r t i c l e s s m a l l e n o u g h to p a s s t h r o u g h a given s c r e e n have d o n e so. In m a n y cases, t h i s is n o t true, a n d we h a v e to be c o g n i z a n t of this e~or,
i.e.- t h i s factor is t h e m a i n s o u r c e of
error
in t h e
SIEVE
METHOD of p a r t i c l e size analysis). We n o w find t h a t t h e r e are two g e n e r a l m e t h o d s for d a t a - r e p o r t i n g , n a m e l y : 5.6.3.-
METHOD I = % of total w e i g h t METHOD II = C u m u l a t i v e w e i g h t - %
E a c h h a s its a d v a n t a g e s . In t h e first m e t h o d , we c a l c u l a t e the total w e i g h t a n d a s s i g n e a c h f r a c t i o n a %-value. M e a n d i a m e t e r s , d', a r e e a s y to o b t a i n in the first m e t h o d b e c a u s e we k n o w t h e s c r e e n d i a m e t e r s u s e d to s e p a r a t e t h e fractions. In the s e c o n d , we a d d f2 to f l , t h e n f3 to f2 + f l , t h e n f4 to f3 + f2 + fl, etc. To o b t a i n d', w e t a k e t h e a v e r a g e of t h e a d d e d fractions, s h o w n as follows: m
5.6.4.-
d
fl
1 5 0 0 ~I
f2 + fl
1210
f3+f2
+ fl
f4 + f 3 + f 2 + f l
963 734
We c o n t i n u e w i t h all t h e f r a c t i o n s we have. If we n o w plot t h e data, we g e t t h e d i a g r a m , given as 5.6.5. o n t h e n e x t page.
216
We c a n see the s p r e a d of p a r t i c l e s in M e t h o d I, b u t c a n n o t d e t e r m i n e
the
m e a n accurately, since d" is a guess. M e t h o d II allows u s to o b t a i n the m e a n from t h e 50% point, t h a t is, t h e point w h e r e
50%
of t h e p a r t i c l e s
are
s m a l l e r t h a n , a n d 50% are larger t h a n . Actually, the d a t a of M e t h o d I are b e t t e r p l o t t e d as s h o w n in t h e following diagram:
217
M e t h o d III
is called a "Histogram Plot" while M e t h o d s I & II are called
" F r e q u e n c y Plot" a n d "Cumulative F r e q u e n c y Plot", respectively. T h e r e is o n e i m p o r t a n t p o i n t w h i c h n e e d s to be e m p h a s i z e d . T h a t is: "ALL METHODS FOR PRESENTING DATA FROM T H E MEASUREMENT OF PARTICLE SIZE DISTRIBUTIONS, W H E T H E R INSTRUMENTAL, SEDIMENTATION, OF
THE
TOTAL
SENSITIVE,
THE
SEIVING,
OR PHOTOMETRIC METHODS, MEASURE FRACTIONS PARTICLE
DISTRIBUTION.
FRACTION-SEGMEN~
IF
CAN BE
THE
METHOD
SMALL,
AND
IS THE
MEASURED PARTICLE DISTRIBUTION WILL BE CLOSE TO THE ACTUAL ONE.
IF THE
MEASUREMENT
IS LESS SENSITIVE,
THERE
MAY BE
SIGNIFICANT DEVIATIONS FROM THE CORRECT PSD. The d a t a for the f r a c t i o n - s t e p s c a n be in t e r m s of n u m b e r s of p a r t i c l e s , weight,
%-weight
or even
a packed
volume.
We shall n e x t
investigate
p a r a m e t e r s of d i s t r i b u t i o n s as a function of m e t h o d of r e p o r t i n g data. 5.7, -
AN/~YSIS OF PARTICLE DISTRIBUTION PARAMETERS
E a c h of the m e t h o d s of d a t a p r e s e n t a t i o n h a s its own special p r o b l e m s in t e r m s of the a m o u n t of e x t r a c t a b l e i n f o r m a t i o n one c a n obtain. We will a d d r e s s e a c h of t h e s e in t u r n , s t a r t i n g vcith t h e least c o m p l i c a t e d one, w h i c h is the " H i s t o g r a m " . A. THE HISTOGRAM A typical h i s t o g r a m is s h o w n in t h e following diagram, given as 5.7.1. on t h e n e x t y page, along w i t h an analysis of the p a r a m e t e r s w h i c h c a n be calculated. The first step is to calculate the individual a r e a s of t h e steps, Ai. T h e s e are s u m m e d a n d t h e n divided by the n u m b e r of individual areas, a n d t h e n m u l t i p l i e d by the s u m of (d2 - d l ) ! ni to find the m e a n , d. Admittedly, t h e m e t h o d is c u m b e r s o m e , b u t s o m e t i m e s this is all the d a t a we have.
218
5.7.1.-
Ai
!00
- ~;l:d2_ d I )
d = IAiln.
% of
9I ( d 2 - d
t )/ni
m
d
Total 5 0 Weight
B. FREQUENCY PLOTS Many p a r t i c l e - m e a s u r i n g m e t h o d s u s e STOKE'S LAW to d e t e r m i n e
particle
d i s t r i b u t i o n s . By suitable m a n i p u l a t i o n { s e e below), we o b t a i n a n e q u a t i o n r e l a t i n g the S t o k e s d i a m e t e r , M, w i t h the particle density, P I ' a n d t h e liquid density, P2' n a m e l y : 5.7.2.-
M = 18 vl h / c~ t (p~ - P2 )g
w h e r e ~ is t h e liquid viscosity, h the d i s t a n c e settles, a is a s h a p e factor (a = 1 for
a spherical
particle),
and
g
is
the
gravitational
constant.
p h o t o m e t r i c m e t h o d (which we shall d i s c u s s in m o r e detail below) at a specific
particle
diameter
and
hence
can
be
directly
The
gives %
plotted
as
frequency, as given in the following d i a g r a m w h i c h is labelled 5 . 7 . 3 . on t h e n e x t page. As s h o w n in the d i a g r a m , do c a n be c a l c u l a t e d from the m e a n d i a m e t e r if the d i s t r i b u t i o n is s y m m e t r i c a l , b u t th~-~r r a r e l y are. Note also t h a t o, w h i c h is defined as the d i a m e t e r limits e q u a l to 68% of the total particle p o p u l a t i o n , c a n n o t be obtained, only d o .
219
C. CUMULATIVE FREQUENCY The
most
popular
method
of d a t a
presentation
is
that
of
cumulative
f r e q u e n c y . An e x a m p l e of t h i s is s h o w n as follows:
m
Note t h a t b o t h d a n d o are easily o b t a i n e d . But no o t h e r i n f o r m a t i o n c a n b e derived. W h a t w e n e e d is a m o r e v e r s a t i l e m e t h o d . T h i s c a n b e a c c o m p l i s h e d
220
by c o n s i d e r i n g a m e t h o d r e l a t e d to the statistical n a t u r e of n e a r l y all p a r t i c l e distributions. The
most
versatile
method
for
d i s t r i b u t i o n s is by plotting t h e m
displaying
and
analyzing
particle
size
as a log n o r m a l d i s t r i b u t i o n . W h a t t h i s
m e a n s is t h a t we u s e log n o r m a l probability p a p e r to plot the data. It is t h i s m e t h o d t h a t we shall investigate in detail since it p r o d u c e s i n f o r m a t i o n about the
distribution
distinguish
not
between
obtainable by any o t h e r natural
and
artificial
method.
PSD's
and
In fact, one make
can
inferences
c o n c e r n i n g the origin of t h e PSD. Also, we c a n easily d i s t i n g u i s h the b i m o d a l c a s e , i.e.- two PSD's p r e s e n t at the s a m e time. T h i s is i m p o s s i b l e o t h e r m e t h o d s of d a t a p r e s e n t a t i o n . D. I.J3G NORMAL PROBABILITY METHOD C o n s i d e r t h e log n o r m a l (Gaussian) distribution, of w h i c h an e x a m p l e is given as follows:
Our a p p r o a c h is to a s s u m e t h a t all PSD's have a n origin in g r o w t h t h a t t e n d s to p r o d u c e a log n o r m a l population. This is r e a s o n a b l e since n e a r l y all, if n o t all, particle g r o w t h m e c h a n i s m s are r a n d o m in n a t u r e . Hence, we e x p e c t to
221
see a log n o r m a l PSD as the usual case. W h a t we t h e n do is to l o o k for d e v i a t i o n s f r o m log n o r m a l i t y . It is t h e s e a b e r r a t i o n s w h i c h s u p p l y a d d i t i o n a l i n f o r m a t i o n about the PSD. To plot a distribution, we u s e log probability paper. ,an s a m p l e is given in t h e following diagram:
A log n o r m a l d i s t r i b u t i o n will give a s t r a i g h t line w h e n p l o t t e d on this type of paper. This m e a n s t h a t the PSD is not l i m i t e d , i.e.- all sizes of particles are p r e s e n t from - ~o to +~o. However, ff the PSD is g r o w t h - l i m i t e d , it will r e a d i l y apparent
from
the
graph.
Ostwald ripening,
a mechanism
where
large
222
p a r t i c l e s grow at the e x p e n s e of small ones, is one m e c h a n i s m t h a t c a n give rise to g r o w t h limits. G r o w t h limits are d e n o t e d by: 5.7.7.-
LL
._..~
"""T
I
Xo
Upper Growth
Limit
Lower
Limit
Growth
- U p p e r D i s c o n t i n u o u s Limit - L o w e r D i s c o n t i n u o u s Limit
The d i s c o n t i n u o u s limit is t h a t in w h i c h all particles b e y o n d a specific size have b e e n removed, or do not exist. The d i a m e t e r of the p a r t i c l e s is f o u n d on the y-axis a n d p l o t t e d at the p r o p e r p o i n t on the x- axis as "% less than" (see M e t h o d II of 5.6.3.
a n d 5.7.4., given above).
5.8 - TYPES OF LOG NORMAL PARTICLE DISTRIBUTIONS We shall p r e s e n t
some
examples
of particle
distributions
and
how
to
i n t e r p r e t t h e m in o r d e r to s h o w the versatility of the m e t h o d . As you will see, the m e t h o d of plotting particle d i s t r i b u t i o n s via a l o g - n o r m a l m e t h o d allows one to i n t e r p r e t
particle
size in a m a n n e r
not feasible by o t h e r
m e t h o d s . Yet you will find t h a t m o s t particle size specialists do not t a k e advantage of the m e t h o d . A. UNLIMITED PARTICLE D I S T R I B U T I O N S The following d i a g r a m , given as 5.8. I. on the next page, s h o w s a typical PSD w h e r e the d i s t r i b u t i o n does not have limits.
223
Following t h i s e x a m p l e are d i s t r i b u t i o n s t h a t do h a v e l i m i t s to t h e " n o r m a l " d i s t r i b u t i o n . W h a t t h i s m e a n s is t h a t t h e d i s t r i b u t i o n s c o n f o r m to t h e l i m i t s d e f i n e d in 5 . 7 . 6 . Note t h a t in 5 . 8 . 1 . , a s t r a i g h t line is evident. T h i s is t h e t y p e of d i s t r i b u t i o n usually f o u n d as a r e s u l t of m o s t p r e c i p i t a t i o n p r o c e s s e s . But as we
s h a l l see,
t h i s is n o t t r u e for t h e
other
t y p e s of l o g - n o r m a l
distributions. B. LIMITED PARTICLE D I S T R I B U T I O N S If a p r e c i p i t a t e is allowed to u n d e r g o O s t w a l d r i p e n i n g , or is s i n t e r e d , or is c a u s e d to e n t e r i n t o a solid s t a t e r e a c t i o n of s o m e k i n d , it will often d e v e l o p into a d i s t r i b u t i o n w h i c h h a s a size limit to its g r o w t h . T h a t is, t h e r e is a maximum, distribution
or m i n i m u m approaches.
limit The
(and s o m e t i m e s distribution
both)which
remains
the
continuous
particle as
it
a p p r o a c h e s t h a t limit. T h e l o g - p r o b a b i l i t y plot t h e n h a s t h e f o r m s h o w n in 5.8.2. o n t h e n e x t p a g e . In t h i s c a s e , b o t h u p p e r a n d l o w e r l i m i t s are s h o w n . However, o n e m a y h a v e o n e or t h e o t h e r , or b o t h , in t h e
general c a s e . O s t w a l d r i p e n i n g t e n d s to u s e
224
u p all of t h e s m a l l p a r t i c l e s , w i t h o u t l i m i t i n g t h e u p p e r size. T h e n w e w o u l d h a v e t h e l o w e r limit b u t n o t t h e u p p e r . C. PARTICLE D I S T R I B U T I O N S WITH D I S C O N T I N U O U S L I M I T S Suppose we
u s e a 2 0 0 - m e s h s c r e e n to r e m o v e p a r t i c l e s l a r g e r t h a n 74~ a n d
a 4 0 0 - m e s h s c r e e n to r e m o v e t h o s e s m a l l e r t h a n 37V. T h e PSD is t h e n :
225
Note t h a t the d i s t r i b u t i o n is linear b e t w e e n 37 a n d 74 ~ b u t t h a t it abruptly shifts to + oo at t h e s e points. This is a particle d i s t r i b u t i o n for w h i c h it is i m p o s s i b l e to obtain an a c c u r a t e p i c t u r e by any o t h e r m e a n s . A
frequency plot
of the s a n e d a t a w o u l d look like t h e n look like this:
If we w e r e u s i n g the f r e q u e n c y plot m e t h o d to p r e s e n t this data, we w o u l d t h i n k t h a t the curve w a s j u s t a s s y m m e t r i c a l a n d t h a t the d i s t r i b u t i o n w a s n o t log-normal. Yet, it is obvious from 5.8.3. t h a t it is l o g - n o r m a l . D. MULTIPLE PARTICLE D I S T R I B U T I O N S Log probability plots are p a r t i c u l a r l y useful w h e n the d i s t r i b u t i o n is bimodal, t h a t is, w h e n two s e p a r a t e d i s t r i b u t i o n s are p r e s e n t .
S u p p o s e we have a
d i s t r i b u t i o n of very small particles, say in s u s p e n s i o n in its m o t h e r liquor. By an
Ostwald
ripening
mechanism,
the
small
particles
redissolve
and
r e p r e c i p i t a t e to form a d i s t r i b u t i o n of l a r g e r particles. T h i s w o u l d give u s t h e d i s t r i b u t i o n s h o w n in 5.8.5. on the next page.
226
In this illustration, the size distribution p a r a m e t e r s of b o t h distributions are readily apparent. A similar d e t e r m i n a t i o n is almost impossible with o t h e r types of data p r e s e n t a t i o n m e t h o d s .
Although a large d i ~ o a t i a u o u s
gap
b e t w e e n the two distributions is s how n in 5.8.5., it is rarely the case. As examples
of the
usefulness
of particle
distributions,
consi der
the
following. Two actual cases e n c o u n t e r e d in I n d u s t r y are described in t h e following examples: CASE I - FLUORESCENT LAMP PHOSPHOR PARTICLES Fluorescent la mps are m a n u f a c t u r e d by squirting a s u s p e n s i o n of p h o s p h o r particles in an ethyl cellulose lacquer u p o n the inner surface of a vertical glass tube. Once the lacquer drains off, a film of particles is formed. T h e lacquer is t h e n b u r n e d off, leaving a layer of p h o s p h o r particles. E l e c t r o d e s are sealed on; the tube is evacuated; Hg a n d inert gas is added; a n d the l am p e n ds are added to finish the lamp. Lamp b r i g h t n e s s and lifetime are d e p e n d e n t u p o n the particle size distribution of the p h o s p h o r particles. T h e n u m b e r of small particles is critical since they are low in b r i g h t n e s s o u t p u t
227
b u t high in light s c a t t e r i n g a n d a b s o r p t i o n . A l a m p b r i g h t n e s s i m p r o v e m e n t of 10% is easily achieved by r e m o v a l of t h e s e particles. In 5.8.6. is s h o w n t h e PSD t h a t r e s u l t e d w h e n a c e r t a i n m e c h a n i c a l m e t h o d w a s u s e d to r e m o v e the "fines", viz-
In this application of the l o g - n o r m a l plot, note t h a t the " m e c h a n i c a l " s e p a r a t i o n of "fines" h a s c r e a t e d a new p a r t i c l e d i s t r i b u t i o n w i t h d 2 = 2 p. Even the value of 02 differs from t h a t of the m a j o r p a r t i c l e distribution. In the "fines" fraction, it a p p e a r s t h a t the l a r g e s t particle does not e x c e e d about 5 p. N e e d l e s s to say, l a m p s p r e p a r e d from this p h o s p h o r w e r e inferior in b r i g h t n e s s . A r m e d w i t h this i n f o r m a t i o n , one could t h e n r e c o m m e n d
that
t h e m e t h o d of "fines" r e m o v a l be c h a n g e d . A n o t h e r c a s e is p r e s e n t e d on t h e n e x t page. CASE II. - T U N G S T E N METAL POWDER The lifetime of a t u n g s t e n filament in a n i n c a n d e s c e n t light bulb d e p e n d s a g r e a t deal on t h e g r a i n size of the wire u s e d to m a k e the filament. W - m e t a l p o w d e r is p r e s s e d into a b a r at p r e s s u r e s w h i c h e n s u r e t h a t the d e n s i t y is as
228
close as possible to the theoretical density. The bar is si nt ered in an i n e r t a t m o s p h e r e a n d t h e n "swaged" , i.e.- "hammered" into a long rod. This rod is t h e n d r awn into a fine wire (~ 2-5 mil) w hi ch is w o u n d into the filament form. Metal powder particle size has a major effect u p o n wire quality since fine particles form small grs.hm in the wire while large particles will f o r m
ulrge grains. When the filament is o p e r a t e d at 3 2 5 0 ~
to p r o d u c e light, the wire is h o t
e n o u g h t h a t vacancy migration will occur in the wire. Simultaneously, grain growth plus an increase in grain size also occurs. The grain b o u n d a r i e s b e t ween large grains will "pin" vacancies, b u t grain b o u n d a r i e s bet w een small grains do not appear to do so. If they do, the effect is at least an order of m a g n i t u d e smaller. As the vacancy c o n c e n t r a t i o n builds up at the large grain b o u n d a r i e s (see the Kirchendall effect given in Chapt er 4), local r e s i s t a n c e to electron flow increases. Eventually, a "hot spot" develops and the t u n g s t e n wire melts at that point, with c o n s e q u e n t failure of the filament a n d t h e lamp. If only small metal particles are us ed to m a k e the wire, t h e n the small grains p r o d u c e d m u s t grow into large grains before "hot spots" cause its eventual f a i l u r e . Therefore, i n c a n d e s c e n t lamp m a n u f a c t u r e r s exercise very close control of the t u n g s t e n - m e t a l powder PSD and the sintering p r o c e s s e s u s ed to p r o d u c e the wire to eliminate, as m u c h as possible, pores and control actual density. The di agr a m s how n as 5.8.7. on the next page illustrates a typical PSD for a t u n g s t e n metal powder where the large particles have been removed. In this case, the PSD is suitable a n d p a r t i c l e s larger t h a n about 5 ~ appear to have successfully r e m o v e d . This c o m p l e t e s the types of particle distributions t h a t we m i ght e n c o u n t e r . It is now time to show how particle size c o u n t i n g - d a t a are used. To do this, we m u s t select an i n s t r u m e n t t h a t p r o d u c e s c o u n t s of size of p a r t i c l e s correlated with n u m b e r s of particles in each size range. There are several types of s u c h i n s t r u m e n t s w hos e n a t u r e will be delineated below. But, first, we m u s t show how this is done. Let us now examine a m e t h o d of calculating a particel size distribution.
229
5 . 9 - : A TYPICAL PSD CALCULATION
Let us s u p p o s e t h a t we have a particle c o u n t i n g i n s t r u m e n t w h i c h s o r t s a n d c o u n t s the n u m b e r of p a r t i c l e s at a given particle size. The e x p e r i m e n t a l d a t a t h a t we collect are:
Having o b t a i n e d the d a t a as given in 5.9.1., o u r n e x t step is to calculate t h e a ~ e
size in e a c h particle intea-wal. For p a r t i c l e s less t h a n 2.2 ~, we have 2
230
p a r t i c l e s . At 3 . 0 la, w e h a v e 4 p a r t i c l e s . T h e r e f o r e ,
i n t h e r a n g e 2 . 2 - 3 . 0 ~,
w e h a v e t w o (2} p a r t i c l e s w h o s e a v e r a g e size is 2 . 6 p. In t h e r a n g e 3 . 0 - 5 . 0 tJ, w e h a v e f o u r (4} p a r t i c l e s w h o s e a v e r a g e size is 4 . 0 ~. We t h e r e f o r e c o n t i n u e to c a l c u l a t e An, as s h o w n in T a b l e 5 - I . for e a c h size r a n g e t h a t w e h a v e m e a s u r e d : TABLE 5 - 1 A TYPICAL PARTICLE SIZE D I S T R I B U T I O N C A I ~ U I A T I O N Diameter
n-Counts
2 . 2 ~1
0
4
5.0
7.0
9.0
10
15
An
d
o%
z%
2
2 . 6 tl
0. I
0. I
24
4.0
1.2
204
6.0
10.2
11.5
370
8.0
18.5
30.0
300
9.5
15.0
45.0
500
12.5
25.0
70.0
500
20.0
25.0
95.0
80
27.5
4.0
99.0
18
35.0
0.9
2 1.3
28
232
602
902
1402 ,,
25
30
4O
1902
1982
20OO
99.9
231
We have a total of 2 0 0 0 p a r t i c l e s t h a t we have m e a s u r e d a n d we c a n calculate the p e r c e n t (%) of total c o u n t s for e a c h size range. T h i s gives the following l o g - n o r m a l PSD plot, viz-
Here, the p a r a m e t e r s of t h e d i s t r i b u t i o n are given. T h i s m a t e r i a l a p p e a r s to have b e e n p r e c i p i t a t e d , or it m a y have b e e n o b t a i n e d by a g r i n d i n g p r o c e s s , since t h e p a r a m e t e r s i n d i c a t e a Gaussian u n l i m i t e d distribution. P a r t i c l e s g r o w n by solid s t a t e reaction, i n c l u d i n g Ostwald ripening, g e n e r a l l y have PSD c h a r a c t e r i s t i c s of the original PSD from w h i c h t h e y w e r e formed. T h a t is, t h e r e will be Emits a c c o r d i n g to the original d i s t r i b u t i o n from w h i c h it h a s arisen. If the original PSD h a d limits, t h e n the p r o g e n y PSD ,;viii also have s u c h limits. T h e basis for this b e h a v i o r lies in the fact t h a t ff one s t a r t s w i t h a c e r t a i n size r a n g e of p a r t i c l e s as t h e basis of particle r e a c t i o n a n d g r o w t h , one will e n d with t h e s a m e size r a n g e of p a r t i c l e s in the PSD of t h e p a r t i c l e s p r o d u c e d by the solid s t a t e r e a c t i o n . S u c h a case is s h o w n in the following d i a g r a m , given as 5.9.3. on the n e x t page. Here, the oxalate w a s p r e p a r e d by addition of oxalic acid to Gd(NO3)3 solution to form a p r e c i p i t a t e .
232
T h e r e is a n u p p e r limit of about 23 m i c r o n s in size. T h i s m a y be d u e to t h e fact t h a t the p r e c i p i t a t i o n w a s a c c o m p l i s h e d at 90 ~
or from the fact t h a t
r a r e e a r t h oxalates t e n d to form very small p a r t i c l e s d u r i n g p r e c i p i t a t i o n w h i c h t h e n grow via Ostwald r i p e n i n g ones. N e v e r t h e l e s s ,
and agglomeration
to form l a r g e r
it is clearly evident t h a t w h e n the oxalate is h e a t e d at
elevated t e m p e r a t u r e (~ 9 0 0 ~
the oxide p r o d u c e d rctaln-q the s a m e PSD
c h a r a c t e r i s t i c s of the original p r e c i p i t a t e . 5.10.-
METHODS OF MEASURING PARTICLE D I S T R I B U T I O N S
Having defined p a r t i c l e s a n d p a r t i c a l d i s t r i b u t i o n s , we now e x a m i n e m e t h o d s by w h i c h we c a n m e a s u r e p a r t i c l e s a n d p r o p e r t i e s four (4) p r i m a r y m e t h o d s
used
to obtain
of p o w d e r s .
data concerning
distributions. These include: OPTICAL
ELECTRICAL
SEDIMENTATION
ABSORPTION
PERMEATION
There
particle
are size
233
A..The M i c r o s c o p e - Visual C o u n t i n g of Partic,!es At the p r o p e r m a g n i f i c a t i o n a n d with a special eye piece, one c a n d i r e c t l y m e a s u r e particle
diameters.
The
eye-piece
m u s t have i n t e r n a l l y - m a r k e d
c o n c e n t r i c circles so t h a t a given particle will fall w i t h i n one or m o r e of t h e circles. The d i a m e t e r t h e n c a n t h e n be r e a d a n d / o r e s t i m a t e d directly as s h o w n in the following:
In this case, t h r e e p a r t i c l e s are shown, a 40 ~, 20 ~ a n d a 10 ~ particle. T h e m o s t i m p o r t a n t step is s a m p l e p r e p a r a t i o n on the m i c r o s c o p e slide, s i n c e only a p i n c h of m a t e r i a l is u s e d , one m u s t be s u r e t h a t the s a m p l e is u n i f o r m and
representative of the material. Also, since m o s t m a t e r i a l s t e n d to
a g g l o m e r a t e d u e to a c c u m u l a t e d surface c h a r g e in a dry state, one a d d s a few d r o p s of alcohol a n d w o r k s it with a spatula, s p r e a d i n g it o u t into a t h i n layer which
dries.
Too
much
working
breaks
down
the
original
particles,
234
p a r t i c u l a r l y the larger ones, a n d too little w o r k i n g leaves a g g l o m e r a t e s . With a little practice, the p r e p a r a t i o n of a p r o p e r slide of p a r t i c l e s b e c o m e s easy. One t h e n p r o c e e d s to c o u n t particles. It h a s b e e n f o u n d t h a t ff one w i s h e s to d e t e r m i n e an a c c u r a t e value of the m e a n d i a m e t e r , one m u s t c o u n t at least 4 5 0 particles, as the n u m b e r of c o u n t s i n c r e a s e s , the m e a n c o m e s closer a n d closer to the t r u e value, as s h o w n in the following:
To calculate the m e a n d i a m e t e r , we c o u n t the n u m b e r of p a r t i c l e s at d I, t h e n t h o s e at d2, etc., s u m t h e s e a n d average the value, i.e.m
5.10.3.-
I! = X n i d i
/Xni
A n o t h e r m e t h o d is to c o u n t p a r t i c l e s b e t w e e n a given r a n g e a n d t h e n s u m the c o u n t s as in 5.9.1. Alternately, one c a n p u r c h a s e an a u t o m a t i c p a r t i c l e c o u n t i n g i n s t r u m e n t for about $ 5 0 - 6 0 , 0 0 0 . microscope,
The i n s t r u m e n t c o n s i s t s of a
a s c a n n i n g device (usually a flying-spot s c a n n e r ) ,
a television
display a n d a p r e - p r o g r a m m e d m i c r o p r o c e s s o r . All of the p a r t i c l e s w i t h i n a
235
given frame can be c o u n t e d a n d g r o u p e d automatically. Thus, several fram es per m i n u t e can be c o u n t e d by an operator, or the i n s t r u m e n t can be set to operate automatically according to a p r e s e t program. Since the i n s t r u m e n t scans imagca of the particles, a p r o b l e m of orientation arises. This is s h o w n in the following diagram:
The m i c r o p r o c e s s o r is p r o g r a m m e d to recognize length and width, b u t t h e question
of the
correct
diameter
of irregular
particles
has
remained
controversial. For example, Martin's d i a m e t e r is defined as the s h o r t e s t line which divides the area of the image in half. A depiction of ~.is is shown as follows:
Yet, it is obvious t h a t this is not the correct d i a m e t e r for the t hese particles. Another school of t h o u g h t would use the a ~ e of the length and width, but for the above particles, the actual value of the length t h a t ought to be u s e d
236
r e m a i n s questionable. This p r o b l e m has r e m a i n e d the m o s t serious b a r r i e r to obtaining PSD by optical microscopy until recently. With the advent of c o m p u t e r s which can process data at the rate of 7 0 0 billion bits per second, this p r o b l e m has been solved satisfactorily. This PSD i n s t r u m e n t {Malvern I n s t r u m e n t s , 10 Southville Road, Southborough, Ma. 0 1 7 7 2 - Sysmex FPIA-2100) is a fully a u t o m a t e d particle size mad ~hape analyzer. It uses CCD, i.e.- "charge-coupled device", technology (the optical basis of a digital video camera) to c a p t u r e a series of images of p a r t i c l e s s u s p e n d e d in a liquid m e d i u m . Particles are s a m p l e d from a dilute s u s p e n s i o n which is forced t h r o u g h a "sheath-flow" cell. This i n s u r e s that the largest area of the particle is oriented toward the video c a m e r a a n d that all of the particles are in focus. The cell is illuminated via a stroboscopic light source and images are c a p t u r e d at 30 Hz. per second. A c o m p u t e r p r o g r a m t h e n p r o c e s s e s the images in real time by the following steps: digitization, edge highlighting, binarization, edge extraction, edge t r a c i n g a n d finally storage. The following diagram shows how this is a c c o m p l i s h e d :
All this requires a high speed c o m p u t e r with large m e m o r y storage capacity and RAM (something not possible until recently). Image analysis software
237
t h e n calculates the area and p e r i m e t e r of each of the c a p t u r e d Lnaages and t h e n calculates the particle d i a m e t e r a n d circularity. The particle shape is easily recognized in this diagram. The area of the circle is equal to t hat of the digitized particle so t h a t the particle circularity (shape) can be classified. Circularity, C, is d e t e r m i n e d by: 5.10.7.-
C = p e r i m e t e r of circle / p e r i m e t e r of p a r t i c l e
Once the m e a s u r e m e n t is complete, the particle size a n d circularity can be displayed in b o th graphical a nd table form. A typical r e p o r t includes: p a r t i c l e size distribution, circularity distribution and a s c a t t e r g r a m of particle size vs: circularity. All t h e s e can be displayed and p r i n t e d in h a r d copy. Individual particle images can be displayed including uni-particle, hi-particle,
and t h e n classified into cat egori es a n d agglomerate, This r a t h e r n e w
i n s t r u m e n t has solved the p r o b l e m of particle shape and c o r r e s p o n d i n g size t h r o u g h optical digitization m e t h o d s . B. SEDIMENTATION METHODS There are several particle sizing m e t h o d s , all b a s e d u p o n s e d i m e n t a t i o n and Stokes Law. If a particle is s u s p e n d e d in a fluid (which m a y be gas, or any liquid),
the
force
of r e s i s t a n c e
to m o v e m e n t
by the
particle
will
be
proportional to the particle's velocity, v, a n d its radius, r, vis5.10.8where
f = 6n r ~ v ~ is the viscosity of the fluid, providing the particle is spherical. If
the particle settles u n d e r the influence of gravity, t h e n we can write: 5.10.9.-
f = 4/3/nr3
(Ps - P l ) g
= 6nr~iv
where ps
and pl are the densities of the solid particle
respectively. Since the distance settled is: h = v t, t h e n :
and the liquid,
238
5.10.10-
d={
18~l h / a t ( p s
-Pl)g}l/2
This is S t o k e s Law for s e d i m e n t a t i o n w h e r e we have a d d e d a , a s h a p e factor, j u s t in case we do not have s p h e r i c a l particles.
For s p h e r e s ,
r = 1. It is
fractional o t h e r w i s e . One way to m e a s u r e p a r t i c l e s is to weigh
them
as t h e y settle
s u s p e n s i o n , s u c h an a p p a r a t u s is called a " s e d i m e n t a t i o n
out from
balance" a n d is
d e s i g n e d as s h o w n in the following diagram:
The weight of the p a r t i c l e s builds u p with time a n d is p r o p o r t i o n a l to I / d . If we a s s u m e s p h e r i c a l p a r t i c l e s , t h e n we c a n c o n v e r t
the above curve to
particle d i a m e t e r from S t o k e s Law. Although we have a d d e d the p a r t i c l e s u s p e n s i o n to a "water cushion" as s h o w n above, it m i g h t not s e e m t h a t t h e settling of the particles w o u l d strictly a d h e r e to S t o k e s Law, w h i c h a s s u m e s the t e r m i n a l velocity to be c o n s t a n t . But, as s h o w n in the following Table, the a p p r o x i m a t e d i s t a n c e a p a r t i c l e n e e d s to travel to r e a c h t e r m i n a l velocity in a given liquid is v e r y s h o r t .
239
Table 5- 1
Rate of Fall i n W a t e r at 25 ~
Size ( m i c r o n s l
for Particles Having a Specific Gra,~ity of 2 . 0
A p p r o x i m a t e D i s t a n c e in c m .
Approximate
T r a v e l e d prior to R e a c h i n g
Terminal
T e r m i n a l Velocity
Velocity_ ( c m / s e c l
2000
1.2 x 102
240
200 20
1.2 x 10 -2 1.2 x 10 -6
2.4 2.4 x 10 -2
2
1.2 x 10 -I0
2.4 x 10 -4
0.2
1.2 x 10 -14
2.4 x 10 .6
0.02
1.2 x 10 -16
2.4 x 10 -8
T h e s e d a t a s h o w t h a t t h e p a r t i c l e s s e p a r a t e very fast d u e pri_mm-ily to t h e i r differing t e r m i n a l velocities. T h u s , in t h e g r a p h s h o w n in 5.10.9., t h e initial w e i g h t is d u e to t h e large particles, while the u p p e r p a r t of t h e curve is d u e to the s m a l l e r sizes. For p a r t i c l e s less t h a n about 2.0 m i c r o n s , settling t i m e s u n d e r gravity b e c o m e s e x t r e m e l y long a n d this size r e m a i n s a lower limit for s e d i m e n t a t i o n m e t h o d s of d e t e r m i n i n g particle size. 2 0 0 0 ~ is p r o b a b l y t h e u p p e r limit since one c a n n o t a d j u s t the b a l a n c e to o p e r a t e quickly e n o u g h before t h e s e large p a r t i c l e s are lost. Major p r o b l e m s e n c o u n t e r e d with t h e sedimentation m e t h o d include: P r o p e r Design of the A p p a r a t u s Using the C o r r e c t Liquid with the Specific P o w d e r P r o p e r d i s p e r s i o n of the P a r t i c l e s Operator Technique The
latest
commercial
apparatus
incorporates
a
microprocessor
to
a u t o m a t i c a l l y plot the size d i s t r i b u t i o n as a f r e q u e n c y or c u m u l a t i v e plot. A n o t h e r s e d i m e n t a t i o n m e t h o d u s e d involves the ANDREASEN PIPETTE. A typical design is s h o w n in the following d i a g r a m :
240
This glass a p p a r a t u s is i n e x p e n s i v e a n d c o n s i s t s of a bottle having a n i n t e r n a l s a m p l i n g t u b e a n d c a l i b r a t e d s a m p l i n g v o l u m e (5 ml). One d r a w s a s a m p l e a n d t h e n expels it into an e x t e r n a l 5 ml b e a k e r . Using the t i m e s c a l c u l a t e d for s u c c e s s i v e d i a m e t e r s to settle p a s t the orifice, one w i t h d r a w s s a m p l e s c o r r e s p o n d i n g to t h a t d i a m e t e r . A series of s a m p l e s are o b t a i n e d at t 1 t 2 , etc., w h i c h are dried a n d weighed. The actual s a m p l e ,
o b t a i n e d is a n a r r o w particle d i s t r i b u t i o n r a t h e r t h a n one Sl~cUlc size. T h u s , the d i a m e t e r m e a s u r e d (by calculation) does not exactly c o r r e s p o n d to t h e true Stoke's diameter, Andreasen
Pipette
sedimentation
b u t to the p e a k of a n a r r o w distribution.Yet,
method
method
since
continues
to
be
the
it involves i n e x p e n s i v e
most
widely
equipment,
the used
and
is
r e a s o n a b l y a c c u r a t e if one will t a k e the time to develop a c o r r e c t e x p e r i m e n t a l t e c h n i q u e . The r e p r o d u c i b i l i t y c a n be excellent, t h e a c c u r a c y less so.
241
Another sedimentation method
u s e d is the so-called MSA-analyzer. If t h e
value of "g" in 5.10.8. is i n c r e a s e d (such as the u s e of a centrifuge) one c a n analyze the very small p a r t i c l e s in tony given d i s t r i b u t i o n in a s h o r t time. T h e p r o b l e m of c o u r s e lies in a c c u r a t e d e t e r m i n a t i o n of the w e i g h t a c c u m u l a t e d at a given time u n d e r a specific c e n t r i p e t a l force. T h i s p r o b l e m h a s b e e n n e a t l y solved by careful design of the s e d i m e n t a t i o n tube, as s h o w n in t h e following d i a g r a m : 5.10.13.A S E D IM E N T A T TUBE
IO N
Calibraled Stem
The p a r t i c l e s build u p b y l a y e ~ b e c a u s e it h a s b e e n f o u n d t h a t all m o n o s i z e d p a r t i c l e s c a n be r e m o v e d from s u s p e n s i o n by r o t a t i n g at a specific
speed.
T h u s , one r u n s the i n s t r u m e n t at a series of r o t a t i o n a l s p e e d s , m e a s u r i n g t h e w e i g h t of t h e b u i l d - u p layers in b e t w e e n e a c h r u n . T h e overall analysis is r u n at
specified
rpm's
which
correspond
to
selected
particle
diameters,
r e s u l t i n g in d a t a sufficient to c h a r a c t e r i z e the p a r t i c l e d i s t r i b u t i o n . C. ELECTRICAL RESISTIVITY - THE COULTER C O U N T E R P e r h a p s t h e m o s t useful m e t h o d for d e t e r m i n i n g p a r t i c l e d i s t r i b u t i o n s is t h a t of electrical
conductivity,
the m o s t widely u s e d i n s t r u m e n t
is t h e
Coulter C o u n t e r ( n a m e d after t h e Inventors), a l t h o u g h t h e r e are now o t h e r similar i n s t r u m e n t s on the m a r k e t . Originally, this i n s t r u m e n t w a s d e s i g n e d to m e a s u r e blood c o r p u s c l e s w h i c h are 2-8 p in size. It h a s p r o v e n to be v e r y
242
suited to m e a s u r e m i c r o n and s u b m i c r o n particles easily, accurately, and reproducibly. Consider a conductive solution consisting of water with a soluble salt, i.e.1% NaCI, an d a dispersing agent u s e d to prevent agglomeration of p a r t i c l e s in s u s p en s io n . Two electrodes are placed in solution with a n o n - c o n d u c t i n g orifice b e t w e e n them, as s h o w n in 5 . 1 0 . 1 4 , given on the next page:
A ceramic block s u c h as alumina is generally u s e d because of its c h e m i c a l i n e r t n e s s a n d the orifice is bor ed or drilled to precise
di m ensi ons. T h e
block is placed so t h a t two (2) c h a m b e r s result. T h e n ff a DC voltage is applied across the electrodes, a c u r r e n t will flow r t h r o u g h the orifice, a n d an effective resistance arises w hi ch d e p e n d s u p o n the voltage applied a n d the size (volume of the c o n d u c t i n g solution) of the orifice. Particles are added to one side of the two c h a m b e r s created by the ceramic block, and the s u s p e n s i o n is p u m p e d t h r o u g h to the other side. There
will be an
electrical pulse as each particle p a s s e s t h r o u g h the orifice. A depiction of the pulses obtained is shown in the following diagram, given as 5.10.15. on the next page. Each pulse will be proportional to the
size of
the particle because the particle volume displaces part of the c o n d u c t i n g solution d u r in g its passage t h r o u g h the orifice. If we have p r o p e r l y established steady state c o n d i t i o n s ,
243
5.10.15.-
IDisplayed Pulses - COulter CounterJ Counting
l
TMOv ab ie hreshold
Non-counting
we
will
obtain
a drop
in
current
as
each
particle
passes
through.
Electronically, this c a n be c o n v e r t e d to a positive p u l s e w h o s e i n t e n s i t y is p r o p o r t i o n a l to e a c h particle volume. We a s m i m e s p h e r i c i t y of t h e p a r t i c l e s , If V is c o n s t a n t , t h e n : 5.10.16.-
I = V /AR
and:AR=roVp
/A 2 -
1/ {1/1- (ro/re)} - a / A
w h e r e ro is the actual particle radius, re is t h e effective r a d i u s (incase t h e particle is not spheroid}, Vp is the v o l u m e of t h e particle, A is the c r o s s sectional a r e a of the orifice, a n d a is a c o n s t a n t w h i c h d e p e n d s
upon the
solvent a n d solute u s e d to m a k e the c o n d u c t i n g solution. The size of the orifice m u s t be fitted to the r a n g e of p a r t i c l e s p r e s e n t . If t h e p a r t i c l e s are too large, t h e y will n o t p a s s t h r o u g h t h e orifice. Too small a n d the p u l s e is not easily d e t e c t e d , present,
the
powder
content
Since large n u m b e r s of p a r t i c l e s c a n be m u s t be controlled.
c o n c e n t r a t i o n - d e n s i t y will r e s u l t in "coincidence
Too
high
counting".
a particle
T h a t is, two
small p a r t i c l e s c a n be c o u n t e d as one larger one. T h i s p h e n o m e n a h a s b e e n
244
a d d r e s s e d a n d tables are p r o v i d e d to c o r r e c t electronic
for i n c i d e n c e
p a r t of the Coulter C o u n t e r h a s several h u n d r e d
counting. T h e "channels" to
a c c e p t pulses. The "threshold" is electrical, a n d mowable, so t h a t one c o u n t s the large p a r t i c l e s ffrrst (large pulses) a n d t h e n m o v e s the t h r e s h o l d lower to c o u n t the s m a l l e r particles. The t h r e s h o l d is actually a p u l s e h e i g h t analyzer w h i c h c o n v e r t s h e i g h t s to n u m b e r s . The d a t a o b t a i n e d are easily c o n v e r t e d to a f r e q u e n c y plot or a c u m u l a t i v e plot. Since fur r e s p o n s e is linear, one c a n readily calibrate the i n s t r u m e n t at one point, u s i n g m o n o s i z e d p a r t i c l e s s u c h as pollen or specially p r e p a r e d
plastic particles. The only r e q u i r e m e n t
is
t h a t the calibrating p a r t i c l e s o u g h t to be in the r a n g e of the p a r t i c l e s to be measured. The Coulter C o u n t e r is p a r t i c u l a r l y useful a n d u n i q u e in t h a t s t e p s as small as 1.0
micron
m a y be
used
if so
desired.
Results
by
this
author
have
d e m o n s t r a t e d t h a t s o m e d i s t r i b u t i o n s w h i c h a p p e a r to Gaussian m a y actually c o n s i s t of m o r e t h a n one subdivision w h e r e the p e a k s are s e p a r a t e d by only a few m i c r o n s , an e x a m p l e is given as follows: 5. I 0 . 1 7 . - A PARTICLE DISTRIBUTION WITH S U B - D I S T R I B U T I O N S
This
result
was
achieved
with
a
selected
particle
distribution
which
originally a p p e a r e d to be a single Gaussian distribution. W h e n the p a r t i c l e
245
m e a s u r i n g steps were c h a n g e d so t h a t a range of about 1-2 m i c r o n s was covered, the above result was obtained. Even so, the m e a s u r e m e n t m u s t be done carefully to reveal the s u b s t r u c t u r e . To the aut hor's knowledge, no other m e t h o d has the capability of s u c h precision in particle d i a m e t e r m e a s u r e m e n t . The latest Coulter C o u n t e r instanm~ents i n c o r p o r a t e a m i c r o p r o c e s s o r and the oper a t or can specify the form of the o u t p u t data to be obtained. The i n s t r u m e n t converts c o u n t - d a t a to practically any form at desired, with the exception of log-probability plots. D. OTHER METHODS OF MEASURING PARTICLE SIZE P e rmeab ility is a n o t h e r m e t h o d
for obtaining i nform at i on about p a r t i c l e
diameters. If one p a c k s a tube with a weight of pow der exactly equal to its density, a n d applies a calibrated gas p r e s s u r e t h r o u g h the tube, the p r e s s u r e drop can be eq u a t e d to an average particle size. The i n s t r u m e n t based on this principle is called the "Fisher Sub-Sieve Sizer TM'. Only one value can be obtained b u t the m e t h o d is fast a nd reproducible. The i n s t r u m e n t itself is not expensive a n d the m e t h o d can be applied to quality control p r o b l e m s of powders. P e r m e a m e t r y is useful in t h e particle range of 0.5 to 50 p. Gas a d s o r p t i o n is one ot he r m e t h o d s o m e t i m e s u s e d for d e t e r m i n i n g average particle size. In this case, one is usually i n t e r e s t e d in the surface area of a powder a n d calculates the average size of the particles
secondarily. T h e
m e t h o d is called the B E T - m e t h o d after its developers, Brunauer, E m m e t t and Teller. The p r o c e d u r e is t i m e - c o n s u m i n g a n d is a c c o m p l i s h e d as follows. A gas analysis train is u s e d in which gas volumes can be recycled and m e a s u r e d very accurately. A w e i g h e d sample is placed in the sam pl e tube and allowed to come to equilibrium. Since all solid materials have a m o n o lay er of water on the surface of the particles (we live in a wet world), the sample is h e a t e d to 300 ~ to expel the water, in a nitrogen gas flow. Next, it is cooled to liquid nitrogen t e m p e r a t u r e . At this point, the s a m p l e will adsorb a m o n o l a y e r of N2-gas molecules on the surface of each particle. By allowing the t e m p e r a t u r e of the s a m pl e to r e t u r n to r o o m t e m p e r a t u r e ,
246
w h i l e m e a s u r i n g t h e v o l u m e of n i t r o g e n
gas released,
o n e o b t a i n s a value
w h i c h c a n b e c o n v e r t e d to a s u r f a c e a r e a of t h e p a r t i c l e s b e i n g m e a s u r e d . I n practice, one recycles the s y s t e m several times, m e a s u r i n g adsorption and d e s o r p t i o n v o l u m e s s u c c e s s i v e l y so as to o b t a i n a n a v e r a g e value. It is f o u n d that the
unoccupied f r a c t i o n
of t h e s u r f a c e ( l - y) a p p r o a c h e s a c o n s t a n t value
w h e r e it is a s s u m e d t h a t y = 0. N i t r o g e n g a s is e s s e n t i a l s i n c e it is t h e only g a s w h i c h f o r m s m o n o l a y e r s easily w i t h o u t t h e t e n d e n c y to f o r m m o r e t h a n o n e l a y e r of g a s m o l e c u l e s on t h e s u r f a c e . If t h e gas p r e s s u r e is k e p t b e t w e e n s t r i c t limits, t h e B E T e q u a t i o n is: 5.10.18.where: the
pg / ( V g [ 1 - p g ] = 1/ {Vmono " C )
+ {C- 1) p g / { V m o n o " C )
C = exp { (FAds. - FCond.) / RT} , a n d pg is t h e g a s p r e s s u r e . Vg is
gas volume
measured;
Vmono is t h e
gas volume
of t h e
monolayer
c a l c u l a t e d f r o m t h e k n o w n d i m e n s i o n s of t h e n i t r o g e n - g a s m o l e c u l e s ; FAds. is t h e Gibbs free e n e r g y condensation,
of a d s o r p t i o n ,
pg is m e a s u r e d
a n d FCond. is t h e
free
e n e r g y of
as t h e r a t i o of t h e e q u i l i b r i u m p r e s s u r e
at
specific t e m p e r a t u r e s , i.e.- r o o m a n d liquid n i t r o g e n t e m p e r a t u r e s . It h a s b e e n f o u n d t h a t a plot of pg / {Vg [1-pg] vs: pg is l i n e a r for t h e p r e s s u r e r a n g e of 0 . 0 5 to 0.4, w i t h a slope of (C - 1) / (Vmono
9 C ) a n d i n t e r c e p t of
1/ (Vmono " C ). Let u s n o w do a s i m p l e c a l c u l a t i o n u s i n g B E T d a t a o b t a i n e d . S u p p o s e we h a v e a 2 0 gm. s a m p l e h a v i n g a d e n s i t y of 2.0. We m e a s u r e t h e s u r f a c e a r e a as 6 m 2 . F r o m t h e a r e a of a s p h e r e , A = n D 2 , a n d t h e v o l u m e of a s p h e r e , V = 4 / 3 n D 3 ,, we find t h e total v o l u m e of n s p h e r e s to b e 10 cc, i.e.- n { 4 / 3 n D3} = 10. T h e s u r f a c e a r e a of n{nD 2} s p h e r e s is 6 m 3. T h e t o t a l n u m b e r of s p h e r e s p r e s e n t , n, is t h e s a m e in b o t h f o r m u l a s . T h e r e f o r e ,
by
s u b s t i t u t i o n , we find D= 10 la. If we o b t a i n a p a r t i c l e d i a m e t e r b y s o m e o t h e r m e t h o d a n d find t h a t it is m u c h s m a l l e r t h a n t h a t of t h e B E T m e t h o d , w e infer t h a t t h e p a r t i c l e s a r e p o r o u s . We t h u s s p e a k of t h e p o r o s i t y a n d n e e d to c o r r e c t for t h e p o r e s u r f a c e a r e a if we are to m a k e a r e a s o n a b l e e s t i m a t e of the true d i a m e t e r by the BET m e t h o d .
247
Particle Size by Laser R e f r a c t o m e t r y is b a s e d u p o n Mie scat t eri ng of p a r t i c l e s in a liquid m e d i u m . Up until about 1985, the power of c o m p u t e r s s u p p l i e d with laser diffraction i n s t r u m e n t s was not sufficient to utilize the rigorous solution for h o m o g e n e o u s spherical particles formulated by Gustave Mie in 1908.
Laser
particle
instrument
manufacturers
therefore
used
a p p r o x i m a t i o n s conceived by Fraunhofer. The h y p o t h e s e s m a d e in Mie T h e o r y include: I. The particle i s a n optically h o m o g e n e o u s s m o o t h sphere w hose real a n d imaginary refractive indices are b o t h k n o w n . 2. The sphereical particle is illuminated by a plane wave of infinite extent an d of defined wavelength. 3. The real a n d imaginary refractive
indices
of
the
medium
s u r r o u n d i n g the particle are bot h k n o w n . The Fraunhofer a p p r o x i m a t i o n includes: 1. The in c i de nt light-wave is plane, of infinite extent and of k n o w n wavelength. 2. The scattering is from a circular a p e r a t u r e in a t h i n opaque s c r e e n . 3. The extinction coefficient for all sizes is 2. 0 Fraunhofer rules do not include
the
influence
of refraction,
reflection,
polarization and o t h e r optical effects. Early laser particle analyzers u s e d Fraunhofer a p p r o x i m a t i o n s because the c o m p u t e r s of t h a t time could n o t h a n d le the storage a n d m e m o r y r e q u i r e m e n t s of the Mie m e t h o d . For example, it has b e e n found t h a t the F r a u n h o f e r - b a s e d i n s t r u m e n t a t i o n c a n n o t be u s e d to m e a s u r e the particle size of a s u s p e n s i o n of lactose {R.I. = 1.533) in iso-octane (R.I. = 1.391) b e c a u s e the relative refractive index is 1.10, i.e.- 1 . 5 3 3 / 1 . 3 9 1 . This is due to the fact t h a t diffraction of light passi ng t h r o u g h the particles is nearly the s a m e as t h a t passi ng a r o u n d the particles, creating a c o m b i n e d interference p a t t e r n vchich is not indicative of the t r u e
248
scattering in the far field where the detector is located. The Mie solution anticipates this. A laser is required to provide a single wavelength so that photons passing through or around any given particle is diffracted and scattered, free form any other optical interference. The Mie theory is rigorous and is used to predict the scattering from particles whose size range from Angstroms to centimeters. Mie originally devised his theory to better define the properties of "fog", i.e.a dispersion of very small circular drops of water in the atmosphere. It has now been adapted to particle counting and particle distributions. Mie t h e o r y requires that the real and imaginary refractive be known or be m e a s u r e d . This may require additional work initially and the choice of liquid m e d i u m , dispersing agents the like may be subject to experimentation initially. This may be especially true if one is trying to determine the PSD of pharmaceutical agents such as new drugs. Laser diffraction particle size i n s t r u m e n t s have now become one of the major p r o c e d u r e s for particle size determination, particularly for the Pharmaceutical Industry, i.e.- organic based particles. Suggested Readin.g 1. R.R. Irani and Clayton F. Ca!lis, "Particle Size- M e a s u r e m e n t , Interpretation and Application" - J. Wiley & Sons, New York (1963). 2. J o h n Wulff et al, "The S t r u c t u r e and Properties of Materials - Volumes I, II, III, & IV" - J. Wiley & Sons, New York (1964). 3. Polakowski and Ripling, "Strength and S t r u c t u r e of E n g i n e e r i n g Materials" - Prentice-Hall, Englewood Cliffs, NJ (1966). 4. R.E. Newnham, "Structure-Property Relations" - Springer-Verlag, New York (1975).
249
p r o b l e m s for C h a p t e r 5 1. For ZrO 2, given t h a t y -= 1 8 0 0 d y n e / c m . ; MP = 2 , 7 1 5 ~
d = 5.89 gm/cc,
c a l c u l a t e t h e m i n i m u m d i a m e t e r at w h i c h z i r c o n i a p a r t i c l e s will n o t a i ~ t e r . 2. Given a c u b e of 1.00 c m a c r o s s in size, Give t h e n u m b e r of c u b e s p r o d u c e d and
their
size
in m i c r o n s
d i m e n s i o n s is m a d e ? ;
produced
if:
100 c u t s a c r o s s ? ;
10
cuts
across
each
of t h r e e
1 0 0 0 c u t s a c r o s s ? Also, give t h e
total s u r f a c e a r e a p r o d u c e d in e a c h case. 3. Given t h e following w e i g h t f r a c t i o n s in % for a s a m p l e of s a n d , plot y o u r c a l c u l a t e d d a t a in t e r m s of: 1. H i s t o g r a m 2 . " F r e q u e n c y Plot" 3. "Cumulative F r e q u e n c y Plot" using:
#10, # 18, #20, #30, # 4 0 , #50, #80, # 1 0 0 , # 1 7 0 , #200, #270, #325 & #400 screens. S a m p l e size w a s 2 0 0 g m . S c r e e n Data= % R e t a i n e d
# 1 0 = 1.5%; # 1 8 = 3.0 %; # 2 0 = 4.5%; # 3 0 = 6 . 0 % ; #40=8.0%;
# 50=
10%; # 8 0 =
16%; # 1 0 0 = 18%;
# 1 7 0 = 15%; # 2 0 0 = 8%; # 2 7 0 = 5%; # 3 2 5 = 3.5%; # 4 0 0 = 1 . 5 % .
250
4. Plot y o u r s c r e e n - d a t a via log-probability;
are t h e r e
any limits
to t h e
distribution? 5. You have o b t a i n e d the following particle data: Particle Count
Measured Diameter
4
2.8
12
3.2
84
3.7
804
7.7
2404
9.3
4824
15.7
6428
20.3
7610
76.7
7930
29.3
8002
36.0
A. Calculate the p a r a m e t e r s of t h e d i s t r i b u t i o n . B. Classify the d i s t r i b u t i o n as to its p r o b a b l e origin. C. Plot the d a t a as: I. H i s t o g r a m ; II. F r e q u e n c y ; III. Cumulative F r e q u e n c y . Make s u r e t h a t you specify all of the d i s t r i b u t i o n p a r a m e t e r s esch method.
C o m m e n t on t h e efficiacy of the m e t h o d s
s t u d y of particle size analysis.
available for
as a p p l i e d to t h e
251
Chapter 6
.............
Growth of Crystals Having e x a m i n e d particle size and particle growth, i.e.- powders, in s o m e d ep th in the last chapter, let us now t u r n to an investigation of the g r o w t h of single crystals. Many of the devices t h a t we use on a daily basis employ a single crystal e l e m e n t as the h e a r t of the m e c h a n i s m . A good example is the "quartz-crystal" w a t c h t h a t you wear on your wrist. Here, a quartz crystal is m a d e to vibrate u n d e r an applied voltage. Its vibrations are coupled to a s ens i ng circuit a n d t r a n s l a t e d into seconds, m i n u t e s and h o u r s by using and count i ng the k n o w n r e s o n a n t frequency of vibration of the crystal. The r e s o n a n t vibrational frequency is d e t e r m i n e d by the angle of "cut" (or angle in relation to the crystallographic axes) and the size of the crystal. There are m a n y o t h e r s ens i ng devices b a s e d u p o n a crystal c o m p o n e n t s u ch as a device w h i c h controls heating, t r a n s l a t e s force into electrical voltage, m o d u l a t e s light, or regulates motion. We use t h e m as electrical heaters, strain gauges, laser controllers or piezoelectric devices. We will explore some of these later in this chapter, particularly single crystal silicon u s e d to fabricate i nt egr at ed circuits u s e d in c o m p u t e r s . As we s tate d previously, particles usually grow from a nucl eus to w h i c h a t o ms are added in a regular m a n n e r to form a t h r e e - d i m e n s i o n a l structure. S u c h crystals cease growing w h e n the "nutrient" (the m a t e r i a l which serves to form the particle) b e c o m e s depleted. S u c h particles are k n o w n as "crystallites". Each will consist of several grains, having a differing orientation of the crystal lattice, within each individual particle, namely:
!]
252
Grain b o u n d a r i e s form j u n c t i o n s b e t w e e n grains within the particle, due to vacancy an d line-defect formation. This situation arises because of t h e 2nd Law of T h e r m o d y n a m i c s (Entropy). Thus, if crystaUites are formed by precipitation from solution, the p r o d u c t will be a powder consisting of m a n y small particles. Their actual size will d e p e n d u p o n the m e t h o d s u s e d to form them. Note t hat each crystallite can be a single-crystal but, of necessity, will be limited in size. However, if one desires a large ~ l a ~ e - ~ , t h e n the m e t h o d s n e e d e d to grow it differ considerably. This is the subject of this Chapter. We will examine crystal-growing m e t h o d s a n d the e q u i p m e n t n e e d e d to do so. We will t h e n examine the different type of crystals u s e d b o t h as s e n s o r s and as the basis of specific devices u s e d in the electronics industry. 6.1- METHODS OF GROWTH OF CRYSTAI~ Obviously, the major difference in the single-crystal and polycrystalline (crystaUite) state is a m a t t e r of size. For the single-crystal, the size is large (> 10 cm), w h e r e a s in the polycrystalline state, the size of the crystals is small (10 ~ n = 0.001 cm.) The m e t h o d s for obtaining one or the o t h e r differ considerably. They include formation from: 6. I. 1-
Single Crystal
Crystallites [ p o w d e r s )
Liquid solvent
Vapor
Vapor Melt Molten salt
Melt Flux Precipitation from solution
The m e t h o d of choice for growing a single crystal d e p e n d s u p o n m a n y factors. Most relate to the physical p r o p e r t i e s of the c o m p o u n d w h o s e single crystal we desire. Some of the m ore i m p o r t a n t p r o p e r t i e s of such a c o m p o u n d are given in 6.1.2. on the next page. For the m o s t part, single crystals are grown from a melt of the c o m p o u n d , provided t h a t m e l t i ng the c o m p o u n d does not cause it to decompose, i.e.-
253
6.1.2.-
Melting p o i n t Partial v a p o r p r e s s u r e of m e l t T h e r m a l stability of solid p h a s e Reactivity of liquid or g a s e o u s p h a s e T h e r m a l c o n d u c t i v i t y of b o t h liquid a n d solid p h a s e s .
m e l t incongr~aently. Before we c o n s i d e r crystal g r o w t h in detail, let us e x a m i n e the h a r d w a r e n e e d e d to obtsin a m e l t . T h e r e a s o n for this is t h a t m a n y of the f u r n a c e c o m p o n e n t s
available have t e m p e r a t u r e
limitations,
a n d m a n y of the c r y s t a l s we m i g h t w i s h to grow have high m e l t i n g p o i n t s , i.e.- > 1 6 0 0 ~
The first a p p a r a t u s we m a y n e e d is a furnace, w h i c h is
s i m p l y a closed space, h e a t e d by electrical e l e m e n t s , w h e r e i n t h e i n t e r n a l t e m p e r a t u r e is c o n t r o l l e d . 6.2. FURNACE C O N S T R U C T I O N T h e r e are m a n y ways to build a furnace. Basically, a f u r n a c e c o n s i s t s of a few e s s e n t i a l p a r t s , e a c h of w h i c h c a n be varied a c c o r d i n g to t h e final o p e r a t i n g r e q u i r e m e n t s n e e d e d for the furnace. T h e following s h o w s t h e e s s e n t i a l s r e q u i r e d for the p r o p e r design of a furnace: 6.2. I.- E l e m e n t s of F u r n a c e Design a. a power s o u r c e , b. h e a t i n g e l e m e n t s c. t h e r m a l insulation, d. a crucible to hold the m e l t e. a s e n s o r for t e m p e r a t u r e - f e e d b a c k f. a t e m p e r a t u r e s e t - p o i n t c o n t r o l l e r g. a relay or o t h e r p o w e r - c o n t r o l device for the p o w e r s o u r c e . The p o w e r source, relay, s e t - p o i n t c o n t r o l l e r
and sensor need
n o t be
d i s c u s s e d here. However, t h e insulation, h e a t i n g e l e m e n t s , a n d c r u c i b l e s involve m a t e r i a l s , a n d n e e d to be e x a m i n e d in m o r e detail. H e a t i n g e l e m e n t s c a n be m e t a l w i r e s or c e r a m i c r o d s w h i c h b e c o m e
254
incandescent when
an electrical
current
flows t h r o u g h
them.
Their
c o m p o s i t i o n s are critical and have been developed over m a n y years to optimize their p e r f o r m a n c e as heaters. Insulation is u s e d to retain t h e heat g e n e r a t e d and to disperse the heat uniformly t h r o u g h o u t the h e a t e d space, namely the internal cavity of the furnace. Table 6-1 s u m m a r i z e s t h e t h e r m a l p r o p e r t i e s of Insulation and Heating E l e m e n t s for furnaceconstruction.
TABLE 6-1 INSULATION
HEATING ELEMENTS
Max. T e m p . Usabl.e
In Air ........
Max. Temp.
Power N e e d e d Voltage C u r r e n t
Glass Wool
600 ~
Nichrome Wire
med.
med.
Fiberfrax
1350
"Globars"TM(SiC) 1475
low
high
Kanthal Wire
1300
reed.
med.
MoSi2
1700
low
high
Alumina(foam& beads) 1850~ Zirconia (ZrO2) 2400
Pt (40% Rh) ZrO2 :Y
1800 1900
low low
high high
Magnesia
LaCh~ 3
1900
10w
high
Quartz wool Fire Brick
.
.
.
.
.
.
1100 1100 to 1650~ ,,
900 ~
,,
Those
2800
heating e l e m e n t s
given in Table 6-I
are generally u s e d in air
a t m o s p h e r e , up to about 1800 ~ If one needs to p r o d u c e a melt above 1800 ~ it is n e c e s s a r y to use refractory metals which m u s t be u s e d in an inert a t m o s p h e r e . Table 6-2 lists some of these heating e l e m e n t s : Table 6-2 E l e m e n t s For NON- .AIR Usage Mo or W wire
Voltage C u r r e n t 2400 to 2800~ low high
Iridium w i r e
2400
low
hi gh
Graphite R.F. C u r r e n t
3400 2800
low low
high hi gh
4000
NA
NA
Oxy-hydrogen flame
The t e m p e r a t u r e s given are approximate, and are p r e s e n t e d solely for
255
comparison
purposes.
In
furnace
insulation,
Fiberfrax TM
(fibers
of
a l u m i n u m silicate) and "fire-brick" (bricks m a d e from insulating silicate c o m p o u n d s ) are the two m o s t c o m m o n l y u s e d materials. For very high t e m p e r a t u r e work, Zirconia (= ZrO2) in the form of beads, "wool", and b o a r d s p r e s s e d from fibers are u s e d for t e m p e r a t u r e s above 1600 ~ Alumina, i.e.- A1203 , is m u c h cheaper, b u t does not have the t h e r m a l shock, or very high t e m p e r a t u r e capability (i.e.- > 2 0 0 0 ~
Zirconia.
Wire-wound e l e m e n t s are u s e d m o s t frequently. They are usable in air up to about 1200 ~
and consist of a heat i ng wire or coil, w o u n d u p o n an
i n s u l a t i n g - p r e f o r m . They are cheap and will last for considerable l e n g t h s of time, especially if they are r u n at < 1200 ~ ( i.e.-Kanthal TM wire). On the o th er hand, wire m a d e from precious metal, i.e.- 60% Pt - 40% Rh = {Pt(Rh)}, can be o p e r a t e d up to 1800 ~ in air, and will o p e r a t e continuously at 1700 ~ for long periods. However, it is expensive and special care is r e q u i r e d w h e n w r a p p i n g a furnace core to form the furnace element. Another idiosyncrasy of this type of heating el em ent is t h a t t h e p o w e r - s o u r c e n e e d s to be especially designed. The Pt(Rh) wire has a very low r e s i s t a n c e degrees,
at r o o m t e m p e r a t u r e .
As it w a r m s
to a few h u n d r e d
its resistivity c h a n g e s considerably. Thus, a cttrr 9169
is
n e e d e d in the power control circuit during start-up, or the {Pt(Rh)} w i r e will m e l t . "Globars T M
(silicon carbide rods)
are the
next m o s t
frequently u s e d
furnace h eatin g elements. They will operate continuously at 1450 ~ and i n t e r m i t t e n t l y at 1500 ~ A newer type of element, Mo -~re coated w i t h silicide, i.e.- MoSi2 (to p r o t e c t the Mo wire against oxidation), has b e c o m e c o m m o n . S u c h heating e l e m e n t s have a p p e a r e d as "hairpins" and will operate at 1750 ~ in air on a c o n t i n u o u s basis. Another heat i ng e l e m e n t coming into use is the defect conduct or , Z r 0 2 , doped with Y203 to m a k e it conducting. However, this type of heating e l e m e n t has special o p e r a t i n g c h a r a c t e r i s t i c s w hi c h h i n d e r its w i d e - s p r e a d usage. It does not b e c o m e conductive until 600 ~ is reached. But, it can be o p e r a t e d continuously at 1800 ~ C. in air for long periods of time, with a m a x i m u m of 1900 ~ I t does require very high c u r r e n t s a n d low voltage to operate satisfactorily. Still a n o t h e r type of heat i ng e l e m e n t
is t h a t of l a n t h a n u m c h r o m i t e ,
256
LaCrO3. These are available in the form of rods and will operate at 1 8 0 0 ~
in air for long p e r i o d s .
Most heating e l e m e n t s fail due to the d e v e l o p m e n t of internal flaws in their s tr u ctu r e. For example, a "globar" is formed by c o m p r e s s i n g SiC particles to form a rod, a nd t h e n sintering it. During operation (especially if it is o p e r a t e d at the u p p e r end of its t e m p e r a t u r e - o p e r a t i n g range), it develops "hot-spots". These are due to oxidation a n d formation of localized resistive areas within the rod (due to diffusion and collection of vacancies at grain boundaries). These areas dissipate power locally, so t h a t the rod eventually fails, i.e.- melts locally at the h o t - s p o t and b e c o m e s non-conductive. Wire-wound e l e m e n t s fail in a similar m a n n e r ,
except
t h at formation of vacancies within the metallic s t r u c t u r e is the m o s t prevalent m e c h a n i s m w hi c h causes "hot-spots" in the operational h e a t i n g coil. These vacancies also migrate to grain boundaries. The grainb o u n d a r y - j u n c t i o n decreases in conductivity, due to vacancy d e f e c t formation. T h e r e u p o n , h o t - s p o t s form within the wire during operat i on, causing ultimate failure of the heating e l e m e n t . Among those heating e l e m e n t s which require the use of neutral, r e d u c i n g a t m o s p h e r e s , or vacuum, M o - w i r e or W-wire in the form of heat i ng coils, graphite in the form of rods or semi-cylinders, are m o s t often used. Iridium wire is also u s e d but it is very expensive. Both Mo and W wire are usable up to 2800 ~ while Ir can be u s e d only to 2 4 0 0 ~ G raphi t e heating e l e m e n t s can be u s e d above 3000 ~ We have also included R.F. (radio-frequency) c u r r e n t as a heating e l e m e n t , although it is only a heating m e t h o d w h e n employed with a suitable succeptor. Finally, one ot her m e t h o d is listed for the sake of c o m p l e t e n e s s , t h a t of the oxy-hydrogen flame. It generat es c o m b u s t i o n p r o d u c t s (H20) but the RF- m e t h o d can be u s e d in any a t m o s p h e r e including vacuum. The m o s t critical e l e m ent in m e l t - g r o w t h of single crystals is t h e container, or crucible. The first r e q u i r e m e n t for selection of a suitable crucible is t h a t the crucible does not react with the melt. The second is
257
t h a t it be t h e r m a l l y s h o c k temperature
resistant.
capability. A f o u r t h
A third
is t h a t
it be
is t h a t of o p e r a t i o n a l stable
in
the
chosen
atmosphere. These requirements eliminate many potential crucible m a t e r i a l s for a given application. For u s e in air, t h e silica crucible (Si02) h a s no p e e r w h e n u s e d with o x i d e - b a s e d m a t e r i a l s u p to 1200 ~ a l m o s t n o n - r e a c t i v e , t h e r m a ~ y s h o c k - r e s i s t a n t , a n d inexpensive.
It is
Mullite,
i.e.- a l u m i n u m silicate, is m o r e reactive, less s h o c k - r e s i s t a n t b u t c h e a p e r t h a n silica. It is u s e d in m a k i n g g l a s s - m e l t s for the m o s t part. Table 6 - 3 lists the
crucible
materials
most
often
used
and
their
temperature
capabilities. TABLE 6- 3 COMPOSITIONS SUITABLE FOR CRUCIBLES FOR U S E IN AIR
FOR U S E IN NON-OXIDIZING A T M O S P H E R E
MATERIAL MAX. T E M P .
MATERIAL
IVIAX. T E M P .
Silica
1200 ~
Iridium
2400 ~
Alumina
1700
Zirconia*
2400
Platinum
1750
Magnesia*
2800
Mullite
1400
Carbon*
2800
Boron
1400
Platinum*
1700
Nitride * Not in h y d r o g e n Most m e t a l s c a n be u s e d as crucible m a t e r i a l s , b u t only the p r e c i o u s m e t a l s s e e m to p o s s e s s the n o n - r e a c t i v i t y r e q u i r e d for m e l t s at t h e h i g h e r t e m p e r a t u r e s . A l u m i n a is less s h o c k - r e s i s t a n t t h a n silica b u t c a n be u s e d at h i g h e r t e m p e r a t u r e s . S h o c k - r e s i s t a n c e r e l a t e s to how fast one c a n h e a t the crucible a n d its c o n t e n t s u p to the m e l t i n g point of the m a t e r i a l w i t h o u t c r a c k i n g the crucible. Z r 0 2 a n d BN are m o s t useful for m e t a l melts. Pt is u s e d for m e l t i n g in air a n d r e m a i n s c h e m i c a l l y i n e r t to m o s t melts. For p r e p a r a t i o n of m e l t s in i n e r t a t m o s p h e r e ,
Ir s t a n d s alone. It is n o n -
reactive, h a s a very high t e m p e r a t u r e limit, a n d is not s u b j e c t to t h e r m a l
258
s h o c k or stress. Pt c a n also be u s e d b u t at lower t e m p e r a t u r e s . Ir is about 4 t i m e s as expensive as Pt. A good rule of t h u m b is to u s e a m e t a l c r u c i b l e for oxide m e l t s a n d an oxide crucible for m e t a l melts, w h e n e v e r possible. Next, we n e e d to d e t e r m i n e exactly how one goes about o b t a i n i n g a single crystal. 6 . 3 . - S T E P S IN GROWING A SINGLE CRYSTAL Materials t e n d to grow polycrystaUine. This behavior is r e l a t e d to the 2 n d Law of T h e r m o d y n a m i c s a n d the E n t r o p y of the s y s t e m . W h a t h a p p e n s is t h a t a large n u m b e r of nuclei begin to a p p e a r as the melt t e m p e r a t u r e a p p r o a c h e s the freezing point (but before it freezes). All of t h e s e n u c l e i grow at about the s a m e rate, a n d at the freezing p o i n t p r o d u c e a large n t t m l m r of small crystals. If we w i s h to r e s t r i c t
the g r o w t h to j u s t o n e
crystal, we w o u l d like a single n u c l e u s to grow
preferentially
at t h e
e x p e n s e of the o t h e r s . But usually, it does not. However, if we u s e a "seed" crystal a n d set up c o n d i t i o n s so t h a t it will grow, t h e n we c a n obtain o u r d e s i r e d single crystal. One m e t h o d
we
might
u s e is to cool
the
melt
to i n c i p i e n t
nuclei-
formation, toss in the seed-crystal, a n d allow the m e l t to freeze into a single crystal. This is the KYROPOUI~S m e t h o d w h i c h we will d i s c u s s in detail later. Alas, this m e t h o d only w o r k s for a few s y s t e m s , n o t a b l y alkali halides (cubic) a n d the like. We find t h a t we c a n u s e a s e e d - c r y s t a l to grow
single
crystals, b u t
only ff we
use
it
under
carefully
defined
c o n d i t i o n s . A modified Kyropoulos m e t h o d h a s b e e n u s e d for m a n y y e a r s to form single-crystal s a p p h i r e u p to 13.0 i n c h e s in d i a m e t e r . Plates c u t from s u c h crystals are u s e d as w i n d o w s a n d s u b s t r a t e s for all s o r t s of i n t e g r a t e d circuits, as well as w a t c h "crystals". The p r o b l e m s of o b t a i n i n g a s e e d - c r y s t a l are not simple. We c a n f r e e z e the m e l t to a p o l y c r y s t a n i n e state. W h e n cool, we e x a m i n e the boule (after first r e m o v i n g the crucible) to try to find a single crystal large e n o u g h for a seed (* 3 - 6 ram.). We could also c a s t the m e l t into a m o l d a n d t h e n look for seeds. We could also freeze a polycrystalline rod by pulling it
259
vertically from the melt. We w o u l d use a small loop of Pt wire to c a t c h p a r t of the m e l t by surface tension. By r o t a t i n g the wire loop while pulling vertically, we find t h a t a polycrystalline rod of small d i m e n s i o n builds up. Once we have the polycrystalline rod, we c a n r e h e a t it next to the m e l t surface so t h a t it r e m e l t s diagram:
and
"necks-in"
as s h o w n
in the
following
What h a p p e n s is t h a t t h e crystaUites m e l t a n d fuse into a small tip. If w e do this carefully, we will have o u r "seed". The
tip's small size l i m i t s
r e g r o w t h of the r e m e l t e d p a r t to t h a t of a single crystal. T h e n , w h e n w e r e t u r n the seed to the melt, we c a n initiate the g r o w t h of a m u c h l a r g e r single crystal, p r o v i d e d t h a t g r o w t h - c o n d i t i o n s are suitable. A n o t h e r way to obtain a s e e d is to dip a capillary t u b e into the m e l t . Surface t e n s i o n c a u s e s the t u b e to fill a n d w h e n it freezes inside, a small seed results. The difficulty w i t h this m e t h o d is t h a t it is difficult to obtain a t u b e of p r o p e r d i a m e t e r , m a d e of the p r o p e r material. Glass softens at too low a t e m p e r a t u r e a n d q u a r t z m e l t s a r o u n d 1 4 0 0 - 1 5 0 0 ~
Usually, w e
are r e s t r i c t e d to m e t a l s a n d even then, we m u s t be able to cut the t u b e to obtain the seed, since it is c o n f i n e d w i t h i n the tube. Once in a while, w e c a n u s e the tube directly a n d obtain g r o w t h directly u p o n the seed, even t h o u g h it h a s r e m a i n e d w i t h i n t h e tube. T h e r e is one o t h e r m e t h o d t h a t c a n be e m p l o y e d to o b t a i n a seed. We use a m e t a l crucible having a small tip a n d c a u s e a m e l t to form. The tip acts
260
in the
s a m e way to form t h e seed.
Nevertheless,
we have the
same
p r o b l e m as w h e n we u s e the m e t a l capillary. We n e e d to o b t a i n the s e e d free from its h o l d e r .
T h u s , the crucible m u s t be sacrificed, or else the whole m a s s m u s t be e x t r a c t e d from the crucible with the s e e d in the tip intact. If t h e r e is a sufficient difference in c o n t r a c t i o n b e t w e e n the m a s s a n d the crucible, p e r h a p s t h e n we c a n obtain the whole m a s s intact, i n c l u d i n g o u r s e e d . 6.4.- CZOCHRALSKI GROWTH OF SINGLE CRYSTAI~ The m o s t c o m m o n m e t h o d for growing single crystals, w h e t h e r t h e y be a m e t a l or a c o m p l e x m i x t u r e of oxides, is to pull a single crystal from a melt.
This
is the
so-called
C
~
Method,
using
the
method
i n v e n t e d in 1918 by t h e Polish s c i e n t i s t J a n Czochralski, w h i c h he called crystal pulling. Large crystals c a n be g r o w n rapidly from the liquid f o r m e d by m e l t i n g
any given m a t e r i a l
(providing
t h a t the m a t e r i a l s
does
not
d e c o m p o s e u p o n melting). One a t t a c h e s a seed crystal to the b o t t o m of a vertical a r m s u c h t h a t the s e e d is barely in c o n t a c t with the m a t e r i a l at the surface of the m e l t a n d allows the crystal to slowly form as the a r m is lifted from the melt.
Let us e x a m i n e
this m e t h o d
in m o r e
detail
to
illustrate its versatility in crystal growth. As an example, we will grow a crystal from a m e l t
of oxides w h o s e m e l t i n g
points
exceed
1800
C.
Automatically, we are limited to u s e of an i r i d i u m (Ir) crucible a n d we will u s e an R . F . - g e n e r a t o r for the p o w e r source. In 6.4.1., (see n e x t page), w e illustrate the typical s e t u p for the crucible in the Czochralski a p p a r a t u s .
261
W e p l a c e t h e Ir c r u c i b l e c o n t a i n i n g t h e m i x t u r e o f o x i d e s o n a Z r O 2
262
platform. This acts as a t h e r m a l b a r r i e r for the b o t t o m of the a p p a r a t u s . We m a y t h e n place a larger Z r 0 2 cylinder a r o u n d t h e crucible for f u r t h e r insulation. An R.F. coil is p l a c e d in position a r o u n d the o u t s i d e of t h e insulation. Finally, an o u t s i d e wall of i n s u l a t i o n is p u t into place a n d a t o p cover plate is p u t into position. At 2 0 0 0 ~ the outerwall t h i c k n e s s of Z r 0 2 n e e d s to be at least 2.5 - 3.0 cm. The whole is t h e n covered by a bell-jar having a hole at the top. The d o m e a n d its c o n t e n t s are f l u s h e d for several m i n u t e s w i t h an i n e r t gas before the R.F.- g e n e r a t o r is t u r n e d on. Gas flow is m a i n t a i n e d t h r o u g h o u t the e n t i r e operation. As t h e c r u c i b l e h e a t s ups, it's entire c o n t e n t s degas. As the m a t e r i a l s melt, t h e y c o n t r a c t so t h a t it is usually n e c e s s a r y to a d d m o r e m a t e r i a l to the m e l t until t h e crucible is full before actual c r y s t a l g r o w t h is a t t e m p t e d . This m a y t a k e 3 4 crucible v o l u m e s of m a t e r i a l . T h u s , the top-hole
needs
to be large
e n o u g h to a c c o m m o d a t e this o p e r a t i o n . a g o o d single c r y s t a l is n o t easy. T h e r e are m a n y factors involved, e a c h of w h i c h i m p o s e s r e s t r a i n t s u p o n the others. S o m e d e p e n d u p o n t h e crystal pulling s y s t e m design, while o t h e r s d e p e n d u p o n t h e n a t u r e of t h e material
being
grown.
These
factors,
for
a given
system,
become
parameters, i.e. t h e y are i n t e r - r e l a t e d . T h e p a r a m e t e r s for CZOCHRALSKI GROWTH are listed in t h e o r d e r of their importance
9
6.4.2.- CZOCHRAI~KI CRYSTAL GROWTH PARAMETERS I. Melt t e m p e r a t u r e a n d its t h e r m a l c o n d u c t i v i t y 2. C h e m i c a l stability of t h e m e l t 3. Degree t h a t m e l t will "super-cool" 4. T e m p e r a t u r e control a n d t e m p e r a t u r e g r a d i e n t achievable 5. Interface angle w h i c h forms b e t w e e n crystal a n d m e l t 6. Degree of d i a m e t e r control p o s s i b l e 7. Rotation r a t e u s e d 8. Rate of p u l l i n g 9. Melt level m a i n t a i n e d
263
All of t h e s e
factors
are
dependent
upon
the
nature
of the
crystal
c o m p o s i t i o n being grown i n c l u d i n g its t h e r m a l , physical a n d c h e m i c a l properties.
Because of the
importance
of R.F. g e n e r a t o r s
to
crystal
growth, let us n o w e x a m i n e t h e m in m o r e detail. A r a d i o - f r e q u e n c y g e n e r a t o r is essentially a gigantic R.C.-taruk circuit (R.C. = r e s i s t a n c e - c a p a c i t a n c e ) w h i c h u s e s m e r c u r y - p o o l - d i o d e s as oscillators. The f r e q u e n c y is fixed a n d the g e n e r a t o r is self-regulating in p o w e r o u t p u t . As a result, c h a n g e of power- o u t p u t , w h i c h affects t e m p e r a t u r e regulation, is slow. The actual o u t p u t of p o w e r o c c u r s t h r o u g h the R.F. coil. The coil itself is a carefully-wound c o p p e r t u b e helix w h i c h has cooling w a t e r r u n n i n g t h r o u g h it, as s h o w n in t h e following:
If a s u s c e p t o r s u c h as a m e t a l crucible is placed w i t h i n the coil, The R.F. power i n d u c e s " e d d y - c u r r e n t s " in t h e crucible,
c a u s i n g it to h e a t up.
E d d y - c u r r e n t s are circular electrical c u r r e n t s i n d u c e d w i t h i n the m e t a l by the R.F. field of the coil.
It is essentially a "skin" effect, a n d the d e p t h of
p e n e t r a t i o n , i.e.- d e p t h of e d d y - c u r r e n t g e n e r a t i o n w i t h i n the crucible is defined by: 6.4.4.-
depth =
1 / 2 ~ [ p / ~tf x 10 9 ]1/2
w h e r e ~t is a p e r m e a b i l i t y , p is a resistivity of the s u s c e p t o r (crucible) mad f is t h e f r e q u e n c y of the R. F. field. The s p a c i n g of the coils is e x t r e m e l y critical. One usually s p e a k s of the "coupling ratio" for a given crucible- R.F. coil c o m b i n a t i o n . This is the ratio of p o w e r t r a n s m i t t e d to t h e c r u c i b l e divided by the power delivered to the coil. R. F. g e n e r a t o r s various sizes, as follows on the n e x t page:
come
in
264
6.4.5.-
10kc-
20KW
50kc-
100 kc - 50 KW
25KW
2 meg. - 75 KW
The size to u s e d e p e n d s u p o n the s u s c e p t o r b e i n g used, the t e m p e r a t u r e of o p e r a t i o n
desired
a n d the h e a t losses w i t h i n the s y s t e m . For an I r
crucible, the I 0 k c - 2 0 KW g e n e r a t o r w o r k s b e t t e r t h a n the 2 meg.- 7 5 KW g e n e r a t o r . R e t u r n i n g to Czochralski growth,
of the 9 p a r a m e t e r s
given in 6 . 4 . 1 .
above, the first 3 are f u n c t i o n s of the m a t e r i a l w h o s e single crystal we are trying to grow. #4 r e l a t e s b o t h to the m a t e r i a l a n d t h e physical design of the
melt-furnace
p l u s t h a t of the
coil.
Parameter
#5
relates
almost
entirely to the o p e r a t i o n of the s y s t e m . As we have i n d i c a t e d , t h e s t e p s in o p e r a t i n g the a p p a r a t u s are: 6.4.6.-
OPERATION OF THE CZOCHRALSKI APPARATUS 1. Load crucible a n d s t a r t melt. times.
Maintain i n e r t a t m o s p h e r e
at all
2. Add m a t e r i a l to m e l t until crucible is full. 3. W h e n the crucible is full, gradually lower the m e l t t e m p e r a t u r e to achieve s u p e r c o o l i n g a n d i n c i p i e n t n u c l e a t i o n . 4. Allow s y s t e m to equilibrate a n d dip s e e d into melt. Rotate s e e d at predetermined speed. 5. Allow s e e d to grow o u t w a r d to d e s i r e d d i a m e t e r . 6. Begin
pulling
incipient
crystal o u t of m e l t
at a r a t e
which
m a i n t a i n s c r y s t a l size a n d g r o w t h . We find t h a t the r o t a t i o n r a t e affects b o t h the "interface angle", i.e.- t h e angle b e t w e e n c r y s t a l a n d melt, a n d control of crystal d i a m e t e r , as s h o w n in the following d i a g r a m , given as 6.4.7. on the n e x t page. Note t h a t we have defined
"interface angle" as the angle b e t w e e n
the
growing crystal a n d the r e s i d u a l melt. Rate of pulling also affects t h e quality of the c r y s t a l as well as the actual n u m b e r of i n t r i n s i c d e f e c t s w h i c h m a y a p p e a r in t h e final crystal. In t h e u p p e r left of 6.4.7., a fiat-
265
interface between the crystal and melt surface has been maintained by regulating the rate of rotation. If it is not maintained correctly, the edges of the crystal may grow too fast (resulting in a hollow crystal- u p p e r right) or the edges may r o u n d (lower left) or facet (lower fight). If faceting is allowed to continue, we find that the crystal so p r o d u c e d is not usable because the facets produce a polycrystalline rod r a t h e r t h a n a single crystal. Diameter control, P a r a m e t e r #6, is i m p o r t a n t to the final quality of t h e obtained crystal. The sides of the crystal need to be straight because they reflect the regularity of the lattice planes within the crystal. Effects of deviation from "correct" growing conditions on the quality of the crystal so-produced are shown in the following diagram, given as 6.4.8. on t h e next page. When growth conditions are not "optimum", serious defects can appear in the growing crystal as a result of physical c i r c u m s t a n c e s of the crystal growth apparatus. Because of this, we need to be very careful while t h e crystal is growing.
266
It is this factor w h i c h m a n d a t e s the very careful design of the Czochralski Apparatus. A p r o p e r design c o n s i s t s of a heavy base, to m i n i m i z e effects of e x t e r n a l vibrations on the surface of the melt, a p r e c i s i o n screw driven by a c o n t r o l l e d r e v e r s i n g - m o t o r (so as to control rate of pulling precisely), a n d a precision m o t o r controlling rate of rotation. S u c h a design is s h o w n on the s u c c e e d i n g page as 6.4.9. Note t h a t we have n o t s h o w n the R.F. g e n e r a t o r . However, we have s h o w n one design of the pulling a p p a r a t u s (there are many). The next m o s t i m p o r t a n t p a r a m e t e r s in Czochralski g r o w t h of crystals are: the h e a t flow a n d hcmt lo~m~ in the system. Actually, all of t h e parameters
(with the possible exception
of #2
a n d #9)
are s t r o n g l y
affected by the h e a t flow w i t h i n the crystal-pulling s y s t e m . A typical heatflow p a t t e r n in a Czochralski s y s t e m involves b o t h the crucible a n d t h e melt. The p a t t e r n of heat-flow is i m p o r t a n t b u t we will n o t e x p a n d u p o n this topic here. Let it suffice to point o u t t h a t heat-flow is set u p in t h e melt by the direction of r o t a t i o n of the crystal being pulled. It is also affected by the u p p e r surface of the m e l t a n d h o w well it is t h e r m a l l y i n s u l a t e d from its s u r r o u n d i n g s . The circular h e a t flow p a t t e r n c a u s e s t h e surface to radiate heat. The crystal also absorbs h e a t a n d r e - r a d i a t e s it
267
f u r t h e r u p on the s t e m . If the crystal is k e p t stationary, we see t h a t t h e h e a t flow p a t t e r n is u n e v e n . T h u s , it is m a n d a t o r y t h a t the crystal be r o t a t e d to control crystal d i a m e t e r , so as to obtain a defect-free crystal. It s h o u l d be clear t h a t the m o s t irnportaxtt p a r t of the a p p a r a t u s is tile "pullrod ~. In m o s t cases, this is f o r m e d from a p r e c i s i o n screw w h i c h is t u r n e d to raise the rod while the whole a s s e m b l y is being r o t a t e d . The above d e s c r i p t i o n
applies to the s y s t e m w h e r e
only the g r o w i n g
crystal is rotated. T h e r e is at least one o t h e r way to "stir" the m e l t so as to control h e a t flow. This is i l l u s t r a t e d as follows: 6.4.11.-
+_ c r y s t a l r o t a t i o n = +_ crucible r o t a t i o n + crystal r o t a t i o n ,
•
crucible r o t a t i o n
268
We c a n r o t a t e the crucible by itself, or in c o n j u n c t i o n with the crystal. But a n o t h e r c o m p l e x i t y arises,
n a m e l y w h a t d i r e c t i o n of r o t a t i o n a n d w h a t
relative s p e e d of r o t a t i o n s h o u l d we u s e for both, or e i t h e r ? If we r o t a t e the c r y s t a l clockwise a n d the crucible c o u n t e r - c l o c k w i s e , flow p a t t e r n s b e c o m e
complex
indeed.
These
then the heat
complexities
have b e e n
s t u d i e d in detail b u t will not be e n u m e r a t e d h e r e . The b e s t c o m p r o m i s e s e e m s to be fast- r o t a t i o n for the crystal a n d slow o r no r o t a t i o n for t h e crucible. Of all the possible m e t h o d s
of s t i r r i n g t h e
melt, the s t a t i c - c r u c i b l e m e t h o d s e e m s to be the best, a n d this is t h e m e t h o d u s e d by m o s t m ' y s t a l - ~ e r s .
T h e n e x t b e s t m e t h o d s e e m s to be
r o t a t i n g the crucible at a slow rate, c o u n t e r to the d i r e c t i o n of the c r y s t a l rotation. It is clear t h a t crystal- r o t a t i o n n e e d s to d o m i n a t e the s t i r r i n g p a t t e r n so t h a t m i x i n g of the m e l t c o n t i n u e s while the crystal is g r o w i n g . The
Czochralski M e t h o d
method
for
complexities control
obtaining
has remained single
the m o s t f r e q u e n t l y
crystals.
The
involved have b e e n c o n q u e r e d
of the c r y s t a l - g r o w i n g
Parameters.
seemingly
by t h e
employed formidable
u s e of c o m p u t e r -
One s u c h s y s t e m ,
available
c o m m e r c i a l l y , is s h o w n in 6.4.12. (on the n e x t page). Here, we s h o w only a b a r e outline of t h e individual c o m p o n e n t s
in t h e
overall s y s t e m . This SYSTEM is capable of o p e r a t i o n in i n e r t a t m o s p h e r e or
vacuum.
A
slave-processor
controls
both
crystal
diameter
and
m e n i s c u s - c o n t a c t of the growing crystal. As we have stated, this is m o s t i m p o r t a n t ff we w i s h to obtain a crystal essentially free from i n g r o w n defects.
This t a k e s
separate monitor observing
the
the
form
is p r o v i d e d
of a m e l t / s e e d for the o p e r a t o r
crystal d i a m e t e r
as it grows.
contact
monitor
and a
as a C C T V c a m e r a for There
is
also
a crystal
a n n e a l i n g f u r n a c e to r e m o v e any crystal s t r a i n t h a t m a y have b e e n i n d u c e d by the c r y s t a l - g r o w i n g
conditions.
A base heater
h e l p s to m a i n t a i n
a
u n i f o r m t e m p e r a t u r e g r a d i e n t in the m e l t - c r u c i b l e d u r i n g crystal g r o w t h . Note t h a t b o t h t h e crucible a n d crystal r o t a t i o n c a n be controlled.
In
o r d e r to control the h e a t - c o n v e c t i o n p a t t e r n s w h i c h n o r m a l l y a p p e a r in t h e melt, a n e x t e r n a l c r y o m a g n e t c a n be s u p p l i e d . Its m a g n e t i c field h e l p s control h e a t l o s s e s a n d m a i n t a i n s a b e t t e r control of t h e c r y s t a l growth.
269
This h a s n o t b e e n s h o w n b u t i n c l u d e s a s o u r c e of liquid n i t r o g e n for t h e
270
c r y o m a g n e t as well as a c o n t r o l l e r to m a i n t a i n the c o r r e c t m a g n e t i c field n e e d e d for defect-free g r o w t h of the crystal. A final c o m m e n t on the Czochralski Method: GaAs h a s b e c o m e i m p o r t a n t in c o n s t r u c t i o n
of i n t e g r a t e d
circuits
for
computers
because
p r o m i s e of s p e e d of r e s p o n s e a n d d e n s i t y of c o m p o n e n t s ,
of t h e
c o m p a r e d to
silicon wafers. Both As a n d Ga t e n d to oxidize in air as t h e y a p p r o a c h t h e melt stage a n d As203 sublimes. Both e l e m e n t s are toxic to m a n . In t h e melt stage, they have high partial p r e s s u r e s as well, so t h a t t h e u s e of an inert a t m o s p h e r e is n o t sufficient to allow g r o w t h of a single crystal. One m e t h o d t h a t h a s b e e n u s e d for this case h a s e m p l o y e d a "liquid e n c a p s u l a t i n g agent". As s h o w n in the following diagram, this c o n s i s t s of a lower m e l t i n g a g e n t u s e d to form a liquid barrier, floating on t h e surface of the m e l t w h i c h serves as the source for the crystal (in this case, Ga-As).
The arrow indicates the liquid b a r r i e r layer. This u s e of a b a r r i e r m e l t illustrates t h a t t h e r e are several ways to grow crystals w h i c h w o u l d be difficult to obtain u n d e r "ordinary" m e a n s of crystal growth, i.e.p r e v e n t i o n of oxidation a n d evaporation of GaAs d u r i n g crystal g r o w t h . 6 - 5 - T h e B r i d g e m a n - S t o c k b a r g e r M e t h o d for Crystal G r o w t h W h e r e a s the Czochralski m e t h o d r e q u i r e s r a t h e r elaborate e q u i p m e n t to obtain single crystals of good quality, the B r i d g e m a n ( S t o c k b a r g e r ) m e t h o d uses a fairly f~mple a p p a r a t u s . This is s h o w n in the following diagram, given on the next page as 6.5. i.
271
The major c o m p o n e n t s n e e d e d to grow single crystals by this m e t h o d are: A two (2) zone furnace Two (2) set point t e m p e r a t u r e - c o n t r o l l e r s A crucible with "seed" tip A constant-speed elevating a n d lowering the crucible.
device
for
The p r o c e d u r e involves obtaining a full crucible of melt w h o s e c omp o s itio n m i r r o r s t h a t of the crystal we wish to grow. We t h e n l ow er the crucible c o n t a i n i n g the melt t h r o u g h a baffled zone within the furnace
272
at a slow rate. The baffles within the furnace p r o d u c e s a u n i f o r m t e m p e r a t u r e decrease b e t w e e n the two zones, resulting in a t e m p e r a t u r e proi~fle like th at given on the fight in the Figure. The t e m p e r a t u r e setpoint of the u p p e r zone is j u s t above the melting point of the material to be grown, and the lower zone is set j u s t below the melting point of t h e material. This r e s ul t s in a s m o o t h t e m p e r a t u r e prot~fle, above and below t h at of the crystal fusion point. Thus, if we can induce a seed to form in the tip of the crucible, then, as the crucible is lowered t h r o u g h t h e freezing p ar t of the t e m p e r a t u r e zone, the rest of the crucible will freeze as a single crystal. The p a r a m e t e r s for the lh'idgemml M e t h o d are: 6.5.2.- pARAMETERS INVOLVED IN THE BRIDGEMAN METHOD I. T e m p e r a t u r e Profile within Furnace 2. Rate of Crucible Raising or Lowering 3. Melt T e m p e r a t u r e 4. Supercooling of Melt 5. Annealing T e m p e r a t u r e 6. T h e r m a l Conductivity of Melt and Crystal 7. T h e r m a l E xpans i on of Crystal 8. Crucible Material U s e d 9. Chemical Stability of Material Being Grown P a r a m e t e r # 1 is a m a t t e r of furnace design. There shoul d be provision for several baffles so as to adjust the t e m p e r a t u r e - gradient distance. Then, it is a m a t t e r of adjusting the two set-point t e m p e r a t u r e s to achieve t h e p ro p er gradient. For some crystals, the gradient needs to be sharp, w h e r e a s for o th er s it can be m or e gradual. The two set-point p a r a m e t e r d e p e n d s primarily u p o n the degree of supercooling experi enced in t h e melt, prior to nucleation. This in t u r n m a y be affected by purity of t h e c o n s t i t u e n t s . The raising and lowering m e c h a n i s m can be simple, t h a t of a gear-driven m o t o r with a c o u n t e r w e i g h t for the crucible-melt m ass. It is convenient to use the lower set- point as the annealing t e m p e r a t u r e for the crystal. But, for very high melting points, this m a y not be possible. Then, we need to add a lower annealing furnace. As the crystal freezes, it m a y not do so uniformly. If so, i n t e r n a l strain resul t s (a polariscope will
273
reveal this). F u r t h e r m o r e , ff the expansion coefficients of the crystal and crucible are too disparate, t h e n external strain on the crystal will g e n e r a t e internal strain. The crystal will t h a n have to be annealed to relieve this strain. The B r i d g e m a n M e t h o d is useful for m a n y types of crystals. T h e key to getting this m e t h o d to w o r k is to induce a seed to form in t h e "seed-tip". If the crucible "seed- tip" is not properly designed, the m e t h o d will not w o r k . A similar way to grow crystals is the Kyropoulos M e t h o d . In this m e t h o d , we first form a melt and t h e n i n t r o d u c e a seed. By raising the m e l t t h r o u g h the t e m p e r a t u r e gradient, a single crystal will grow from t h e point w h e r e follows:
the seed engages the melt.
The
apparat us is shown as
Note t h a t we have r e v e r s e d the t e m p e r a t u r e gradient within the furnace and th at the top is cooler t h e n the bottom, w here the melt is first f o r m e d . In a variation of this m e t h o d , the seed is i n t r o d u c e d after the m e l t t e m p e r a t u r e has been stabilized and t h e n b r o u g h t to incipient nucleation. In this case, the whole m a s s can be m a d e to freeze nearly instantaneously. It is this m e t h o d w h i c h is c u r r e n t l y being u s e d to m a n u f a c t u r e s a p p h i r e boules as large as 12 inches in diameter. The boule is t h e n cut into slabs
274
w h i c h are p o l i s h e d a n d u s e d for UV t r a n s m i t t i n g w i n d o w s , s u b s t r a t e s for various e l e c t r o n i c devices a n d even n o n - s c r a t c h i n g faces on y o u r w a t c h . Note
that
transmitting
sapphire
is
about
as h a r d
as d i a m o n d
and
capability a l m o s t equal to m a n y metals,
has
while
a heat-
remaining
essentially c h e m i c a l l y i n e r t a n d electrically n o n - c o n d u c t i v e . In o t h e r variations of the Kyropoulos m e t h o d , we raise the m e l t t h r o u g h the freezing point of the melt, by raising it p a s t the baffles of t h e furnace. A n o t h e r possible m e t h o d
is one w h e r e we u s e a single- zone furnace,
stabilize the melt, lower the f u r n a c e t e m p e r a t u r e to i n c i p i e n t n u c l e a t i o n a n d t h e n cool to form t h e crystal. However,
this w o r k s only for a few
s y s t e m s . T h e r e a s o n is p r o b a b l y supercooling. T h e r e are only a few m e l t s w h e r e a large d e g r e e of s u p e r c o o l i n g occurs. Addition of a s e e d will t h e n c a u s e very r a p i d g r o w t h of the single crystal. But, it is usually s t r a i n e d a n d m u s t be carefully a n n e a l e d to obtain the m a s s intact.
If the a p p a r a t u s
s h o w n in 6.5.3. is u s e d a n d the crucible is exactly p o s i t i o n e d so t h a t a vertical t e m p e r a t u r e
g r a d i e n t is m a i n t a i n e d
e z a c t l y along t h e c r u c i b l e
h e i g h t , t h e melt, w h e n seeded, will grow into a single crystal m o r e slowly. T h e n , the degree of s u p e r c o o l i n g is not as i m p o r t a n t . As a m a t t e r of fact, m e l t s w i t h little or no d e g r e e
of s u p e r c o o l i n g c a n be i n d u c e d to f o r m
single c r y s t a l s by following this p r o c e d u r e . 6.6.-
ZONE MELTING AS A MEANS FOR FORMING SINGLE CRYSTALS
T h e r e is n o t h i n g to say t h a t we m u s t m e l t all of the m a t e r i a l at one t i m e . If we have a long rod of polycrystalline m a t e r i a l , a n d m e l t a p a r t of it, i.e.a "zone", we c a n sweep this zone down the l e n g t h a n d u l t i m a t e l y m e l t a n d freeze all of the rod. The m a j o r p r o b l e m is, again, i n d u c i n g a "seed" of single- c r y s t a l m a t e r i a l to form (and to continue). In t h e forward d i r e c t i o n of travel, t h e zone is m e l t i n g w h e r e a s at the b a c k of t h e zone, f r e e z i n g occurs. If we c a n i n d u c e the b a c k p a r t to freeze as single- crystal, t h e n w e can transform
the
whole
rod.
This
means
that
we
polycrystalline m a t e r i a l a n d e n d u p with a single- crystal: 6.6.1.-
P o w d e r ~ P o l y c r y s t a l l i n e ~ Single Crystal
can
start
with
275
For the case of Z o n e - M e l t i n g to f o r m a s i n g l e between
crystal, we c a n d i s t i n g u i s h
two s e p a r a t e cases, i.e.- h o r i z o n t a l a n d vertical zone m e l t i n g .
This is s h o w n as follows:
Our choice a m o n g h e a t i n g e l e m e n t s is limited to the R.F.- coil, a h o t - w i r e coil or p e r h a p s the MoSi2 "hairpin" element. The r e a s o n is t h a t we m u s t r e s t r i c t the melt zone as m u c h as possible, while m o v i n g the zone t h r o u g h the material. Heating by r a d i a t i o n is not very effective since it o c c u r s in a 4n direction. One possible solution is to u s e a h e a t reflector a r o u n d t h e wire
heating element
to limit
the
h e a t i n g length_ of the
melt
zone.
A n o t h e r limitation of the m e t h o d is t h a t the p o w e r losses in the s y s t e m are large b e c a u s e we m u s t u s e a protective t u b e or o t h e r i n s u l a t i o n a r o u n d the m a t e r i a l so as to be able to move the h e a t source. Unless we are willing to s q u a n d e r power, we c a n n o t r e a c h the very high t e m p e r a t u r e s of m e l t i n g r e q u i r e d for s o m e m a t e r i a l s . Therefore, the z o n e - m e l t i n g m e t h o d of single crystal g r o w t h h a s usually b e e n confined to m a t e r i a l s of m o d e r a t e to low m e l t i n g t e m p e r a t u r e s s u c h as silicon. The vertical m e t h o d s h o w n above h a s s o m e t i m e s b e e n called the "floating zone" m e t h o d .
The
thickness
of polycrystaUine
rod
determines
the
276
m a x i m u m l e n g t h of m e l t zone t h a t c a n be u s e d successfully. T h i s r e l a t i o n c a n be c a l c u l a t e d f r o m : 6.6.3.-
THIN RODS ZMax -
THICK RODS_
2 (3r}I/2
ZMax = 2.8 [ y / p g ]
w h e r e r is t h e r a d i u s in cm., 7 is the s u r f a c e t e n s i o n of t h e m e l t , p is its d e n s i t y , g is the g r a v i t a t i o n a l c o n s t a n t , a n d ZMax is t h e m a x i m u m l e n g t h of the floRtlng zone. 6.7.- ZONE R E F I N I N G W h e n a c r y s t a l freezes f r o m t h e melt, it t e n d s to reject i m p u r i t i e s . If z o n e - r e f i n i n g is a p p l i e d to s u c h a crystal, the r e s u l t i n g single c r y s t a l eml b e
p u r e r t h a n t h e originaL If we m a k e m o r e t h a n one p a s s , we c a n a p p r o a c h a h i g h d e g r e e of purity. S u c h a p r o c e d u r e is called "zone- refining". It h a s b e e n d e t e r m i n e d
that there
is a d i s t r i b u t i o n coefficient
for t h e
i m p u r i t i e s b e t w e e n c r y s t a l a n d m e l t w h i c h favors t h e melt. We c a n s e e h o w this a r i s e s w h e n we reflect t h a t i m p u r i t i e s t e n d to c a u s e f o r m a t i o n of i n t r i n s i c defects w i t h i n the c r y s t a l a n d lattice s t r a i n as a r e s u l t of t h e i r p r e s e n c e . In the melt, no s u c h r e s t r i c t i o n applies. Actually, e a c h i m p u r i t y h a s its o w n d i s t r i b u t i o n coefficient.
However, o n e c a n a p p l y a n average
value to b e t t e r a p p r o x i m a t e t h e b e h a v i o r of t h e m a j o r i t y of i m p u r i t i e s . One c a l c u l a t e s t h e c o n c e n t r a t i o n of i m p u r i t i e s left in t h e single crystal, as a f u n c t i o n of a single p a s s , f r o m : 6.7.1.-
Ci
--
Co
[1 - (1-ko) exp {- k o L / Z }l
w h e r e Co is the o H g l m ~ c o n c e n t r a t i o n of i m p u r i t i e s , L is the l e n g t h t h e zone travels (in cm.), a n d Z is t h e m e l t - z o n e
length.
Note t h a t we are
t a k i n g a ratio of L to Z. We n e e d to m i n i m i z e Z in o r d e r to m a k e t h e p r o c e s s efficient in s e g r e g a t i o n of i m p u r i t i e s , ko is the d i s t r i b u t i o n coefficient, defined by:
277
6.7.2.-
ko = ci {solid) / ci {melt)
We plot c i / Co vs: L / Z, t h e n u m b e r of z o n e - l e n g t h s solidified. T h i s is i l l u s t r a t e d in t h e following d i a g r a m :
278
At t h e top of this d i a g r a m , we s h o w t h e effects of o n e p a s s on various s e l e c t e d values of t h e d i s t r i b u t i o n coefficient, k o . Note t h a t at values of ko > 1, we do not o b t a i n any significant i m p r o v e m e n t in i m p u r i t y c o n t e n t . For e x a m p l e , we s t a r t at k = 5.0, b u t e n d up at 1.0. Even at ko = 0.5, t h e f u r t h e r we move t h e m o l t e n zone, t h e less we purify t h e m a t e r i a l . T h i s h a s b e e n called t h e i m p u r i t y - l e v e l i n g effect. At t h e very low values of ko, one still c a n n o t i m p r o v e t h e i m p u r i t y level to any significant degree, u s i n g j u s t one
pass. We find
that multiple
passes
are
required
to
obtain
purification. At t h e b o t t o m of 6 . 7 . 3 . is s h o w n t h e effect of m u l t i p l e p a s s e s u p o n t h e degree of p u r i f i c a t i o n o b t a i n e d . Here, we have used: 6.7.4.-
ko
=0.5 andL/Z=8
a n d have r e c a l c u l a t e d t h e d a t a given before. Note t h a t as t h e n u m b e r of p a s s e s r e a c h e s 10, we o b t a i n a c h a n g e of s o m e 90 t i m e s in t h e i m p u r i t y c o n t e n t a t t h e front of t h e rod. But, at t h e back, i.e.- L / Z = 8, we a p p r o a c h an u l t i m a t e d i s t r i b u t i o n w i t h 20 p a s s e s (the d o t t e d line). If we could s e e t h e i n t e r n a l d i s t r i b u t i o n of i m p u r i t i e s after t h e rod h a d b e e n z o n e - r e f i n e d by 20 p a s s e s , we w o u l d see:
where
t h e d e n s i t y of dots r e p r e s e n t s
the
concentration
of i m p u r i t i e s .
W h a t h a s h a p p e n e d is t h a t we have m o v e d m a n y of t h e i m p u r i t i e s f r o m t h e front to t h e b a c k , b u t not all. a n d we finally e n d up w i t h an i m p u r i t y d i s t r i b u t i o n we c a n n o t c h a n g e . To u n d e r s t a n d this, we m u s t e x a m i n e t h e i m p u r i t y - l e v e l i n g factor in m o r e detail.
279
6 . 8 . T H E IMPURITY LEVELING F A i R When
a melt-zone
is
moved
through
a long
crystal,
an
impurity
c o n c e n t r a t i o n b u i l d s u p in t h e m e l t z o n e d u e to r e j e c t i o n b y t h e c r y s t a l as it resolidifies. We c a n also say t h a t t h e d i s t r i b u t i o n coefficient p u r i f i c a t i o n p r o c e s s , i.e.- k<< are c o n c e r n e d )
favors a
1. A n o t h e r r e a s o n (at l e a s t w h e r e
is t h a t a s o l i d - s o l u t i o n b e t w e e n
metals
impurity and host ions
exists. It h a s b e e n o b s e r v e d t h a t t h e following s i t u a t i o n , as s h o w n in t h e following d i a g r a m , o c c u r s :
T h e i m p u r i t y , x , b u i l d s u p at t h e solid- liquid i n t e r f a c e as t h e liquid z o n e m o v e s a n d t h e solid forms. We c a n w r i t e for t h e d i s t r i b u t i o n c o e f f i c i e n t : 6.8.2.where
kx = CxL / CxS CxL is t h e i m p u r i t y - c o n c e n t r a t i o n
in t h e liquid, a n d C~s is t h e
i m p u r i t y c o n c e n t r a t i o n in t h e solid. We t h e n e s t i m a t e k x f r o m : 6.8.3.-
k x NI / N MX exp - ( EM - EX ) / k T
w h e r e I is t h e i m p u r i t y , MX is t h e c o m p o u n d u n d e r c o n s i d e r a t i o n , a n d E M , EX a r e t h e a c t i v a t i o n e n e r g i e s for f o r m a t i o n of solid s o l u t i o n of MX I X . Note t h a t we h a v e a s s u m e d t h a t I is a c a t i o n i m p u r i t y in t h e c r y s t a l , MX. We c a n d i f f e r e n t i a t e
between
2 separate
cases,
as s h o w n
in t h e
following d i a g r a m , given as 6 . 8 . 4 . o n t h e n e x t p a g e . Here, w e s h o w two c a s e s for i m p u r i t y s e g r e g a t i o n
between
melt
and
c r y s t a l as it g r o w s in t i m e . Note t h a t a n initial p u r i f i c a t i o n o c c u r s in b o t h c a s e s b u t t h e d i s t r i b u t i o n coefficient for t h e c a s e o n t h e r i g h t is s u c h t h a t t h e a m o u n t of i m p u r i t y a c t u a l l y i n c o r p o r a t e d into t h e c r y s t a l , ki - Co.
280
6.8.4.- Behavior of I m p u r i t i e s as a F u n c t i o n of Type of Solid Solution Formed
ICase I- CXL> Cxs
I
ko<1
I~ k x " ~ Liquid rlI~ i ~.~ (Melt) I ~. kx2 ir~~ Sol
.
.
I ! i
I I i
XI rl
ih._ iil,'-
Li quid
ko<1
~
kx2
(Melt) j ~ . ~kx, [2
/
.,/!
~i
X2
L.-
1.1"!
SoJil
9
9
I I
I I
9
X
]
9
J
x
I
x2
1
Note t h a t it rapidly a p p r o a c h e s the orlglm~ i m p u r i t y c o n c e n t r a t i o n , c o . At t~, it actually in~re, m ~ over the original c o n c e n t r a t i o n at s o m e p o i n t w i t h i n the solid crystal. It s h o u l d be clear t h a t if the i m p u r i t y freezes into the solid from the melt, t h e r e m u s t be a certain a m o u n t of solid solution formation, even t h o u g h the i m p u r i t y c o n t e n t be less t h a n 0.01%. Case I & II s h o w simple solid solution b e h a v i o r for k < 1. For CxL > CxS , we will get an i m p r o v e m e n t in p u r i t y in the crystal. But for o p p o s i t e effect is seen. T h u s , two different
CxL < CxS
impurities
,
the
could m a n i f e s t
o p p o s i t e behaviors, d e p e n d i n g u p o n w h a t h o s t t h e y were in. The following diagram, given as 6.8.5. on the next page, i l l u s t r a t e s f u r t h e r p h e n o m e n a r e g a r d i n g zone refining. The s a m e s i t u a t i o n s e e n in 6 . 8 . 4 . occurs
for the
distribution Nevertheless,
case
at the
coefficient simple
bottom
is s u c h t h a t
right the
of 6.8.5. impurity
except buildup
that is
the
slower.
solid-solution for i m p u r i t y s y s t e m s is rarely t h e
n o r m . The m o s t p r e v a l e n t case is t h a t of Case III of 6.8.5. Limited solid solution occurs, a n d we get a t w o - p h a s e s y s t e m .
281
This
illustrates
the
fact
that
impurity
segregation
and
purification
p r o c e s s e s are d e p e n d e n t u p o n the type of i m p u r i t y involved and its individual segregation coefficient. As we illustrated above in 6.8.1., t h e p r o b l e m is th at the i m p u r i t y is initially rejected from the solid, but its c o n c e n t r a t i o n builds up in f l o a t of the g r o w i n g crystal, The s e g r e g a t i o n coefficient, ki , t h e n operates on t h a t i n c r e a s e d c o n c e n t r a t i o n and t h e product, ki Co, i ncr eas es . If we use individual zone lengths, as shown in 6.7.3. , we would have: 6.8.6.-
ZONE I~
2. 3.
IMPURITY CONCENTRATION (Co - k Co) (Co-kco) + k(co-kco) (Co - k c o ) +k(co -kco) +k2(co -kco),
etc.
This is the r eas on for the behavior s how n in 6.8.4. The i m p u r i t y front builds up until its c o n c e n t r a t i o n s u r p a s s e s the original c o n c e n t r a t i o n
282
( s o m e t i m e s by manyfold). T h e r e u p o n , the i m p u r i t y c o n c e n t r a t i o n levels out (but not n e c e s s a r i l y to the s a m e Co we have u s e d for i l l u s t r a t i o n in 6.8.4.).
It is for t h e s e
reasons
t h a t zone-refining
has found limited
application, since actual purification by this m e t h o d does not p r o d u c e a crystal with a c o m p l e t e l y u n i f o r m i m p u r i t y d i s t r i b u t i o n . The c o n c l u s i o n we m u s t d r a w is t h a t we s h o u l d purify o u r r a w m a t e r i a l s b e f o r e we a t t e m p t to grow o u r single crystal, not after. Zone refining has b e e n found to be effective only in a few limited cases. It is not applicable to the g e n e r a l case or to high m e l t i n g crystals. But if we w i s h to do z o n e l e v e l i a g of a n a d d e d i m l m f i t y , t h e n we have a very useful t e c h n i q u e .
A
good e x a m p l e w o u l d be to a d d a small a m o u n t of Ga to Ge . We c a n a d d a small v o l u m e of Ga to the front zone a n d will fund t h a t it h a s b e c o m e evenly i n c o r p o r a t e d into the Ge crystal after several p a s s e s , u s i n g zonerefining. 6.9.- THE VERNEUIL METHOD OF CRYSTAL GROWTH This m e t h o d
h a s also b e e n called the "flame-fusion" m e t h o d
of c r y s t a l
growth. If a p o w d e r is blown t h r o u g h a flame, it will m e l t if t h e flame is hot e n o u g h . T h e only flame hot e n o u g h to do this is the o x y - h y d r o g e n flame.
However,
a specially d e s i g n e d
burner
is r e q u i r e d
so t h a t t h e
crystaUites will m e l t d u r i n g the s h o r t time t h a t t h e y p a s s t h r o u g h t h e flame-front. The original w o r k w a s a c c o m p l i s h e d by Verneufl (1931)
and
the a p p a r a t u s is n a m e d after this investigator. T h e tip of t h e t o r c h is i m p o r t a n t . One d e s i g n u s e d for s u c h a t o r c h is given as follows:
283
The center tube is used for oxygen gas which t r a n s p o r t s the powder. T h e b u r n e r is designed so that the outer tubes contain only hydrogen gas, with the interstiee~ between the H 2 - tubes t r a n s p o r t i n g additional oxygen gas. This design will melt Y203 powder which has a melting point of 2380 ~ The overall Verneuil apparatus, shown in 6.9.2. on the next page, consists of a sealed hopper to contain the powder, the TORCH itself, a refractory pedestal to hold the growing crystal, and an after-furnace to anneal t h e crystal. The procedure for using the apparatus shown in 6.9.2. is given as follows: 6.9.3.-
Operating Instructions for Verneuil Apparatus I. Fill powder hopper, close and attach to burner. 2. Light b u r n e r and adjust flame to oxidizing. 3. Adjust pedestal to proper height and begin rotation. 4. Slide after-furnace into position. 5. Turn on and adjust oxygen flow in powder h o p p e r . 6. Begin tapping. 7. As melt begins to build up, adjust both height and speed of rotation so that crystal begins to form in a regular m a n n e r . 8. When the proper crystal size has been reached, stop powder flow by shutting off the oxygen flow to the h o p p e r . Continue flame operation and pedestal rotation. 9. Lower the crystal into the after- furnace, and anneal crystal, Gradually lower furnace t e m p e r a t u r e temperature.
and let cool to r o o m
Thermal stability is important in this m e t h o d because the high t e m p e r a t u r e s r e a c h e d may be sufficient to cause decomposition of t h e material. The Verneuil Method of crystal growth is not generally applicable to all types of crystals. There are serious deficiencies in t h e method. For example, there is a large t e m p e r a t u r e drop of h u n d r e d s of degrees over a few millimeters within the crystal. This causes a large difference in thermal expansion within a limited space, and c o n s e q u e n t
284
strain. Many crystals are not refractory e n o u g h to w i t h s t a n d the s t r e s s
285
buildup an d so crack into m a n y smaller parts. This m a k e s it very difficult to obtain a single crystal of any size. Thus, if a crystal is grown by this technique, it m u s t be annealed carefully in order to obtain it intact. Generally, the m e t h o d is r e s t r i c t e d to crystals like A1203 w hose t h e r m a l conductivity is high and w hos e refractive n a t u r e m a k e s it possible to obtain a crystal. For the m o s t part, one is r e s t r i c t e d to growing s i m p l e oxides by this m e t h o d s . Complex oxides s u c h as Ca2Si04 or Ca2P207 generally c a n n o t be g r o w n easily an d the Czochralski Method b e c o m e s the m e t h o d of choice. The p a r a m e t e r s involved in the Verneufl m e t h o d are: 1. Melt T e m p e r a t u r e 2. T h e r m a l Stability at Melt T e m p e r a t u r e 3. T e m p e r a t u r e Gradient p r e s e n t in l~arnace
and
after-
furnace. 4. Sintering Volume Losses 5. T h e r m a l Conductivity of Crystal 6. Annealing T e m p e r a t u r e R e q u i r e d 7. Effects of Reducing Flame on Material 8. Chemical Stability of Material being U s e d 6-10: MOLTEN FLUX GROWTH OF CRYSTALS This m e t h o d employs a m o l t e n flux which dissolves the material and redeposits it u p o n a selected substrate. T hat is, the m o l t e n flux acts as a t r a n s p o r t m e d i u m . The t e m p e r a t u r e of the flux can be varied to suit t h e material an d to p r o m o t e high solubility of the solute material in t h e m o l t e n solvent. One example is '"fiG", y t t r i u m iron garnet, i.e.- Y3Fe5012. This material is u s e d in the Electronics I n d u s t r y as single crystals for microwave method.
generating
devices.
It can be grown via the m o l t e n
A typical molten-flux a ppa r at us is s how n as 6. I0. I. on the next page.
flux
286
The six steps involved in using this m e t h o d are as follows: 1. A flux s u c h as lead borate is melted. PbB204 is useful in this m e t h o d because it will under g o supercooling r a t h e r easily. 2. The material w hi ch is to form single crystals is dissolved in the m o l t e n flux to near saturation (Note t h a t this r e q u i r e s prior knowledge regarding solubility of c o m p o u n d in m o l t e n flux). 3. The crucible, w hi ch is usually platinum, is rot at ed to obtain a
uniform
temperature
distribution
within
the
melt-
c o m p o u n d solution. 4. The solution t e m p e r a t u r e is gradually lowered to i n c i p i e n t nucleation. At this point, because of the physical a r r a n g e m e n t
287
of the h e a t i n g e l e m e n t s ,
a temperature
g r a d i e n t will e x i s t
along the l e n g t h of the crucible, from top to b o t t o m . 5. Single c r y s t a l s will begin growing along t h e b o t t o m of t h e crucible, a n d s o m e t i m e later along t h e e d g e s . 6. T h e crucible is k e p t r o t a t i n g to m a i n t a i n a u n i f o r m m i x i n g a n d h e a t flow while the c r y s t a l s are g r o w i n g . T h i s m e t h o d h a s s e r i o u s deficiencies for u s e as a g e n e r a l m e t h o d . We find t h a t if we dissolve MX in a BX 2 flUX a n d g r o w all MX c r y s t a l , it is likely to be c o n t a m i n a t e d w i t h B, or even KK2. The c r y s t a l - g r o w i n g p a r a m e t e r s for this m e t h o d are: 6.10.2.-
Molten F l u x G r o w t h P a r a m e t e r s 1. Flux m e l t t e m p e r a t u r e 2. Solubility of MX in t~K2 3. Degree of s u p e r c o o l i n g 4. T e m p e r a t u r e g r a d i e n t a c h i e v e d 5. Rate of r o t a t i o n u s e d
If t h e s e are not w i t h i n the c o r r e c t
range, one does not obtain single
crystal growth. This m e t h o d h a s b e e n u s e d in t h e p a s t only b e c a u s e of its relative simplicity of apparatlas a n d m a t e r i a l s . crystals so-produced
h a s b e e n r a t h e r poor.
However,
the quality of
Crystals p r o d u c e d
by t h i s
m e t h o d are suitable for s t r u c t u r e deterwAnations, b u t are poor in o p t i c a l quality a n d are n o t a t all s u i t e d for e l e c t r o n i c a p p l i c a t i o n s . T h e r e is one a r e a w h e r e m o l t e n flux g r o w t h h a s b e e n u s e d to form an epitaxial g r o w t h of a single c r y s t a l • m on a s u b s t r a t e . In this case, we c a n u s e m o l t e n lead t e t r a b o r a t e (PbB407), w h i c h m e l t s at about 9 6 0 ~ T h e m e l t is r a i s e d to 9 8 0 ~ The t e m p e r a t u r e
a n d t h e r e q u i s i t e oxides are dissolved t h e r e i n .
is lowered
to n e a r 9 6 0 ~
a n d s u p e r c o o l i n g begins.
Since the substra_te is cooler, a g a r n e t • m
will grow on its surface u n d e r
t h e s e conditions. T h e surface of the ~
slice will have b e e n carefully
p o l i s h e d to m i n i m i z e surface d e f e c t s .
288
It takes about 6 m i n u t e s to grow a single-crystal film about 5o - IOO thick. The trim grows in an epitaxial m a n n e r , that is- it builds up on t h e crystallographic planes of the substrate itself. It should be obvious that the degree of supercooling that the melt will undergo before the dissolved oxides precipitate out depends upon the amount of oxides dissolved. This is generally d e t e r m i n e d by trial a n d e r r o r . We lower the t e m p e r a t u r e to just above that point. A substrate slice of single- crystal ~ (gadolinium gallium garnet = Gd3Ga5 O12) is then s u b m e r g e d in the molten flux, while being rotated. Expitaxial growth was used in the supplanted by plasma deposition and the like.
past but has b e e n
6.11.- HYDROTHERMAL GROWTH Single crystal growth by h y d r o t h e r m a l m e a n s utilizes water as t h e m a t e r i a l - t r a n s p o r t medium. The m e t h o d is most often used for growing single crystal quartz. Quartz (SiO2) is not very soluble in water, but its solubility increases considerably at higher t e m p e r a t u r e s . Thus, growth is accomplished at high p r e s s u r e s in a sealed autoclave. These quartz crystals are used as resonant frequency "tuning forks" for timing applications in digital watches. The following diagram, given as 6.11.1 on the next page, shows a typical apparatus. Seed crystals are h u n g within an autoclave on a revolving hanger. Nutrient (high purity sand or natural crystal quartz) is contained at t h e
289
b o t t o m a n d dissolves as the autoclave is heated. A t e m p e r a t u r e g r a d i e n t is m o s t often u s e d so t h a t the n u t r i e n t dissolves a n d is t r a n s p o r t e d to t h e cooler area w h e r e it is r e d e p o s i t e d
as single crystal material. Note t h e
t e m p e r a t u r e g r a d i e n t at t h e baffle. The solubility of the solute (in this case, quartz) is a function of b o t h p r e s s u r e a n d t e m p e r a t u r e . P r e s s u r e could be in t h e o r y be u s e d as t h e controlling p a r a m e t e r r a t h e r t h a n t e m p e r a t u r e . However, it is difficult to design an a p p a r a t u s with a p r e s s u r e gI'adient, w h e r e a s o b t a i n i n g a t e m p e r a t u r e g r a d i e n t is fairly easy. Actually, w h a t is c o n t r o l l e d is the critical v o l u m e from the e q u i l i b r i u m : 6.11.2.-
H20(g)
r
H20(1)
w h e r e 1 a n d g refer to the liquid a n d g a s e o u s state, respectively. T h e p h a s e d i a g r a m for w a t e r is s h o w n at the lower left of the following diagram, given as 6.11.3. on the n e x t page.
290
Above the critical t e m p e r a t u r e , water exists as a gas at all pressures. But, if we fLx the volume of both gas and liquid (as in an autoclave), then no liquid is possible below the critical volume (-- 30 % by volume). By filling the available volume greater t h a n 30% with water, we can go to very high p r e s s u r e s (i.e.- > 3000 atmospheres) and still maintain a liquid volume.
In hydrothermal growth, the materials ~ grown as single crystals are t h o s e classified as in-qoluble at standard t e m p e r a t u r e and pressure (STP). For quartz, growth is usually accomplished a t m o s p h e r e s at 350 ~
at
85%
fill
and
2000
The p a r a m e t e r s for h y d r o t h e r m a l growth of single crystals are: 6.11.4.-
Parameters Controlling Hydrothermal Growth of Single Crystals. 1. Operating P r e s s u r e 2. Operating T e m p e r a t u r e 3. Solubility in super-critical w a t e r 4. Degree of supersaturation 5. Degree of supercooling 6. Purity of N u t r i e n t
291
The last t h r e e factors r e q u i r e s o m e f u r t h e r c o n s i d e r a t i o n . We will d i s c u s s t h e s e in light of t h e g r o w t h of quartz, since it is this crystal for w h i c h t h e m o s t e x p e r i e n c e h a s b e e n gained. The r a t e of crystal g r o w t h is a f u n c t i o n of s e e d - c r y s t a l orientation. The r a t e of growth, r h k l , m a y vary several orders
of m a g n i t u d e ,
depending
upon
the
{hkl}
plane
orientation.
However, a c e r t a i n degree of s u p e r s a t u r a t i o n is m a n d a t o r y as the n u t r i e n t dissolves, Otherwise,
passes the
through nutrient
the would
baffle,
and
moves
to
precipitate
before
reaching
the
seed
area.
the
seed
crystals. It h a s b e e n d e t e r m i n e d t h a t t h e r a t e of crystal g r o w t h is a d i r e c t function of the degree of s u p e r s a t u r a t i o n , A Sat: 6.11.5.-
rhkl
where ~hkt
=
(x - k h k t
" A Sat
is the s e e d o r i e n t a t i o n factor a n d a is a c o n s t a n t d e p e n d e n t
u p o n the crystal s y s t e m . However, it h a s b e e n found t h a t the d e g r e e - o f s u p e r c o o l i n g factor is c o n t r a - i n d i c a t i v e to t h e g r o w t h rate. To u n d e r s t a n d this, i m a g i n e the face of a growing crystal. Rejection of i m p u r i t i e s at t h e growing interface c a u s e s a localized i n c r e a s e of i m p u r i t y c o n c e n t r a t i o n . This is s h o w n in t h e following d i a g r a m :
If the s u p e r i m p o s e d t e m p e r a t u r e g r a d i e n t is Ta, i.e.- d T / d l is a c o n s t a n t , a n d Te
is the e q u i l i b r i u m curve, i.e.- d C / d T e , t h e n s u p e r c o o l i n g will
292
occur. The rate of d e p o s i t i o n t h e r e b y c h a n g e s . If it b e c o m e s slower, crystal g r o w t h slows w h e r e a s if it s p e e d s up, t h e n d e n d r i t i c g r o w t h o r faceting occurs. Note t h a t the impurity- rejection m e c h a n i s m , o b s e r v e d for the case of Molten Flux growth, also o c c u r s h e r e . For all t h e s e r e a s o n s , p u r i t y of m a t e r i a l s is one of, if n o t the, i m p o r t a n t of the p a r a m e t e r s controlling h y d r o t h e r m a l g r o w t h . 6-12:
most
VAPOR METHODS USED FOR SINGLE CRYSTAL GROWTH
If the m a t e r i a l w h o s e single crystal we w a n t is volatile or sublimable, t h e n we m a y choose a v a p o r - m e t h o d of crystal growth. T h e s e m e t h o d s have b e e n u s e d for a variety of crystals i n c l u d i n g ZnS a n d CdS. In this m e t h o d , a carrier- gas is m o s t often u s e d for m a t e r i a l t r a n s p o r t a n d for t h e sulfides, H2S is the gas of choice. The following s h o w s a simple apparatus:
In this m e t h o d ,
we s t a r t the gas flow a n d t h e n begin heating.
It is
i m p o r t a n t to h e a t the m a t e r i a l to j u s t below the p o i n t of s u b l i m a t i o n (volatilization) a n d let the s y s t e m come to equilibrium. Gas flow n e e d n o t be rapid b u t n e e d s to be sufficient to carry the volatiles to the cooler p a r t of the furnace. The t u b e u s e d in the furnace is m o s t often a silica-tube, a l t h o u g h m e t a l t u b e s have s o m e t i m e s b e e n used. The choice u p o n the n a t u r e of the m a t e r i a l b e i n g s u b l i m e d a n d crystallized.
depends
293
For ZnS an d CdS, it is i m p o r t a n t to exclude all traces of oxygen since these materials are easily oxidized: 6.12.2.-
2 ZnS + 3 02
= 2 ZnO + SO2
The operating p a r a m e t e r s for the vapor p h a s e m e t h o d of growing crystals are s h o wn in the following: 6.12.3. - Operating P a r a m e t e r s for Vapor Phase Growth of Crystals i. T e m p e r a t u r e of sublimation (volatilization) of m a t e r i a l 2. A m o u n t of gas flow u s e d 3. Degree of furnace- t e m p e r a t u r e set- point above material sublimation t e m p e r a t u r e . 4. T e m p e r a t u r e gr a di e nt at crystal-growing j u n c t i o n of tube. Obviously, w h e t h e r the material has a low (high vapor pressure) or a hi gh t e m p e r a t u r e of sublimation is i m p o r t a n t because of furnace- c o n s t r u c t i o n material considerations. In general, we c a n n o t use this m e t h o d for materials wh ich are volatile above about 1200 ~
because m o s t m a t e r i a l s
of c o n s t r u c t i o n c a n n o t w i t h s t a n d the corrosive n a t u r e of the vapors at this high t e m p e r a t u r e . If we set the t e m p e r a t u r e of the furnace above t h e sublimation point of the material, it will volatize all at o n c e . This w oul d n eces s itate
setting
the
gas-
flow
such
that
all of the
material
is
t r a n s p o r t e d by the gas. It would be b e t t e r to set the t e m p e r a t u r e j ust below the vaporization (sublimation) point. There will be enough m a t e r i a l t r a n s p o r t e d to begin growth of single crystals. In fact, it has b e e n determined obtained.
th at the
slower
the
growth,
the b e t t e r
are the
crystals
There is a n o t h e r m e t h o d t h a t has been s o m e t i m e s employed in the vapor p h a s e growth of crystals. This m e t h o d uses an evacuated capsule as s h o w n in 6.12.4., given on the next page. The capsule is generally m a d e f r o m quartz, although p l a t i n u m is s o m e t i m e s used. T h e capsule n e e d s to b e e~-acuatcxl t o r e m o v e any r e s i d u a l g a s l ~ f o r e h e a t i I ~ i s s t a r t e d . Otherwise, the internal p r e s s u r e would build until the capsule would explode.
294
Even t h o u g h it is evacuated, c a p s u l e s have b e e n k n o w n to explode b e c a u s e the q u a r t z (metal) walls could not c o n t a i n the i n t e r n a l vapor p r e s s u r e of the m a t e r i a l being grown as single crystal. Care m u s t be e x e r c i s e d n o t t o h a n d l e t h e h o t eJ~am~le before a n d after crystal g r o w t h . In addition
to s u b l i m a t i o n or vaporization, we c a n
also u s e c h e m i c a l
t r a n s p o r t as a m e t h o d of single crystal growth. For example, we could use e i t h e r of the a p p a r a t i of 6.12.1. or 6.12.4. to grow a crystal of ZnCI2 by the following r e a c t i o n s : 6.12.5.-
ZnO+3HI
= ZnI2 il + H 2 0
Zn + I2
= ZnI2
Metal c a r b o n y l s are also c o n v e n i e n t for g r o w t h of c e r t a i n METAL single crystals, vis6.12.6.-
M(s} + x OD(g}
~
M(CO(g})x
M(CO{g})x
~
M(s} + x CO(g}
In t h e s e cases, one is limited
to the g r o w t h
of single c r y s t a l s of t h e
t r a n s i t i o n m e t a l s since it is t h o s e m e t a l s w h i c h form volatile c a r b o n y l c o m p o u n d s . The alkali m e t a l s , alkaline e a r t h m e t a l s a n d c e r t a i n of t h o s e e l e m e n t s w h i c h are allotropic in n a t u r e are not at all s u i t e d for this t y p e of crystal g r o w t h .
295
6.13.- EDGE DEFINED CRYSTAL GROWTH Many times, the form of the crystal o b t a i n e d is n o t s u i t e d for the e n d use c o n t e m p l a t e d . For example, a fiat plate of ~ - A1203 is often u s e d as a base for i n t e g r a t e d circuits (IC's) b e c a u s e of its high t h e r m a l c o n d u c t i v i t y a n d its low electrical conductivity. Si is vapor d e p o s i t e d on t h e surface of t h e A l u m i n a plate, a n d t h r o u g h various p h o t o g r a p h i c t e c h n i q u e s a n d s e l e c t i v e etching
(with
integrated
suitable
circuit
additives
diffused
is built up. T h e
into
IC relies
the
silicon
upon
the
layer),
high
an
thermal
c o n d u c t i v i t y of the A l u m i n a b a s e for its long life since "hot-spots" c a n quickly d e s t r o y the IC. One w a y to m a k e t h e s e p l a t e s c o n s i s t s of pulling an ( z - AI203 crystal by Czochralskd m e a n s , slicing it into wafers, p o l i s h i n g b o t h sides of the wafers a n d t h e n c u t t i n g e a c h one into s m a l l e r fiat p l a t e s of the r e q u i r e d size. cr
A1203 ( c o r u n d u m ) is e x t r e m e l y h a r d (9.5 on the Mohs scale) a n d is
difficult to w o r k with. It w o u l d be m u c h easier if we could grow (~ - •1203 directly as a fiat plate. By u s i n g e d g e d e f i n e d g r o w t h , one c a n do this. A typical a p p a r a t u s is s h o w n as follows:
The a p p a r a t u s c o n s i s t s of a n o r m a l Czochralski m e l t w i t h an anvil at t h e surface of the melt.
Once the crystal h a s s t a r t e d
to grow, vce pull it
t h r o u g h the anvil, t h u s defining its size. Once it is in the form of a s t r i p ,
296
as s h o w n below, it c a n be d r a w n a n d w o u n d over a large wheel. The s t r i p is later cut directly into plates, with no p o l i s h i n g r e q u i r e d . Because of t h e high m e l t i n g point of ~-A1203 (M.P. = 1920 ~ an i r i d i u m crucible a n d anvil are needed.
But, the m e t h o d
is m o r e
versatile
t h a n we
might
s u p p o s e . We c a n grow crystals in the form of tubing, r o d s or strip, as s h o w n by the anvils at the right.
In fact, we c a n grow in n e a r l y any
configuration we m i g h t wish. T u b i n g in the form of a - Al203 is u s e d for the c o n s t r u c t i o n of the familiar high- p r e s s u r e s o d i u m - vapor l a m p s u s e d for street- lighting. End- c a p s of n i o b i u m m e t a l are sealed on the tubing. The c a p p e d t u b i n g is evacuated, s o d i u m m e t a l is a d d e d a n d the whole sealed off a n d m o u n t e d . O p e r a t i o n of the l a m p o c c u r s a t - -
800
~
a n d about
15 a t m o s p h e r e s
internal
p r e s s u r e of s o d i u m vapor. T h e s e o p e r a t i n g c o n d i t i o n s m a n d a t e the u s e of a t r a n s p a r e n t , chemically- a n d t h e r m a l l y - stable t u b i n g s u c h as a - A1203. In fact, no o t h e r m a t e r i a l is k n o w n t h a t will successfully w i t h s t a n d t h e s e operating conditions. 6 . 1 4 . - MELTING AND STOICHIOMETRY Although we have d e s c r i b e d the u s e of m e l t s to grow single crystals, w e have said little
concerning
how
such
melts
are
obtained
and
their
s t o i c h i o m e t r y . In general, one a d d s the c o r r e c t ratio of oxides a n d m e l t s t h e m to obtain a m e l t of the
compound desired.
We m a y also p r e - r e a c t t h e
oxides to form the c o m p o u n d a n d t h e n melt it. W h e n a crystal is g r o w n from either
melt,
little
difference
can be n o t e d
in individual crystal
p r o p e r t i e s . However, this applies only to c o n g r u e n t l y meltimg c o m p o u n d s . What this m e a n s is t h a t the m e l t r e t a i n s the s a m e c h e m i c a l s t o i c h i o m e t r y as the crystal u s e d to m a k e the melt. As a m a t t e r of fact, it is possible to use an excess of cations, or a n i o n s (as oxides), in the m e l t a n d still obtain a
stoichiometric
crystal.
There
are
some
cases
where
a
non-
s t o i c h i o m e t r i c c o m p o s i t i o n will be o b t a i n e d even t h o u g h the c o m p o u n d is c o n g r u e n t l y - melting. An e x a m p l e of s u c h a p h a s e - s y s t e m is s h o w n in 6.14.1., p r e s e n t e d on the next page. Even t h o u g h this p h a s e d i a g r a m is c o m p l i c a t e d , it is easy to u n d e r s t a n d .
297
6.14.1-
I"Phase .................. Diagram For a Non-Stoichiometric Composition I Congruently Melting Composition
Liquid
r T
L o w Temperature Stoichiometric Composition
i' Change in Composition We s t a r t with c o m p o u n d s
"A" a n d "B", one on e a c h e n d of the p h a s e
diagram, i.e.- 100% A or 100% B. T h e r e are two regions in b e t w e e n t h e s e limits w h e r e solid solutions of A & B occur. More i m p o r t a n t l y , a r e g i o n exists w h e r e the c o m p o s i t i o n freezes a n d m e l t s c o n g r u e n t l y (that is- t h e m e l t does n o t d e c o m p o s e . W h e n it melts, however,
the m e l t t h e n d e c o m p o s e s
into two s e p a r a t e
p h a s e s . On e i t h e r side of t h e c o n g r u e n t l y - m e l t i n g c o m p o s i t i o n is a p h a s e
298
region of p a r t i a l - solid- solution, In t h o s e regions, one solid freezes b e f o r e the other, so t h a t it is i m p o s s i b l e to grow a crystal from a m e l t of t h e s e m i x e d oxides. Note t h a t even at the eutectic c o m p o s i t i o n
(there are two
of them), one still obtains a m i x t u r e s of oxides. However,
t h e r e is a c o n g r u e n t l y -
compositions
a s s o c i a t e d with
melting
it. The
composition
a n d a r a n g e of
low t e m p e r a t u r e
stoichiometrie
c o m p o s i t i o n m e l t s i n c o n g r u e n t l y b u t it is not easily achieved from t h e melt. It shifts c o m p o s i t i o n u p o n m e l t i n g or freezing! It t u r n s o u t t h a t t h i s behavior is m o r e p r e v a l e n t t h a n one m i g h t realize. It is, in fact, typical for m a n y s y s t e m s a n d s o m e of t h e s e are listed in Table 6-3, s h o w n on t h e n e x t page. The m a x i m u m c o m p o s i t i o n -
existence
r a n g e is given along with t h e i r
d y s t e e t i e c o m p o s i t i o n , t h a t is, the m o s t usual c o m p o s i t i o n . A closer e x a m i n a t i o n of Table 6-3 reveals a r a t h e r s t a r t l i n g conclusion. It c a n be s e e n t h a t m o s t of t h e s e
compounds
are s u b j e c t to s t r u c t u r e -
v a c a n c y defects. Certainly all of t h e p n i c t i d e s fall into this class. We are even given the defect c o n c e n t r a t i o n . T h u s in GaP, we have: 6.14.2.where freezing
6 pp 5
--7
is usually 0 . 0 0 0 0 5 . behavior
stoichiometry.
of
a
However,
defects in the crystal
PGa + ( 1 + 6 ) Vp + (xVi We c a n c o n c l u d e
compound
has
a
t h a t the
significant
melting effect
of
and its
it a p p e a r s to m a n i f e s t itself m a i n l y as p o i n t
produced.
The e s s e n c e of this d i s c u s s i o n is t h a t
a l t h o u g h we m e l t the c o m p o n e n t s , w h e t h e r t h e y be oxides or o t h e r w i s e , to f o r m a d e s i r e d c o m p o u n d or c o m p o s i t i o n , t h e r e are m a n y c a s e s w h e r e we do not obtain the s t o i c h i o m e t r y we e x p e c t to get. This is g r a p h i c a l l y i l l u s t r a t e d w h e n we c o n s i d e r the t y p e s of defects t h a t are actually o b t a i n e d in single c r y s t a l s as t h e y are b e i n g g r o w n .
299
T A B L E 6- 3 N o n s t o i c h i o m e t r i c N a t u r e of S o m e B i n a r y C o n g r u e n t l y Melting Compounds COMPOUND
MAX. E X I S T E N C E R A N G E
DYSTECTIC COMPOSITION
G ~ . 5 + x Po.5-x
+ 0.00025
to - 0 . 0 0 0 0 5
+ 0.00006
Gao.5+x As0.5-x
+ 0.00023
to - 0 . 0 0 0 1 8
+ 0.00004
Pb0.5+xS0.5-x
+ 0.0005
Pb0.5+x Sc0.5-x
to - 0 . 0 0 0 0 5
NOT KNOWN
+ 0.0005 - 0.00005
Pbo.5+x T eo.5-x
+ 0 . 0 0 0 5 to - 0 . 0 0 0 1 3
- 0.00012
Sno.5+xSo.5-x
+ 0
- 0.000005
Cdo.5+xTeo.5-x
+ 0.000002
to - 0 . 0 0 0 0 0 8 to - 0 . 0 0 0 0 0 8
NOT K N O ~
Mgl+xA12-2xO4-2x + 0 . 4 7
to
Gd3+xGa5_x O12
+ 0.30
to - 0 . 0 0 2
Lil_5xNb l+xO3
+ 0 . 0 3 1 to O-
+ 0.0092
Lil-5xTal+xO3
+ 0 . 0 2 5 to O
+ 0.0066
6.- 15:
- 0.42
- 0.000005
+ 0.05
ACTUAL I M P E R F E C T I O N S IN S I N G L E C R Y S T A I ~
Now we can summarize
all of t h e i m p e r f e c t i o n s
l i k e l y to a p p e a r in s i n g l e
c r y s t a l s . S o m e o f t h e s e , p a r t i c u l a r l y s t a c k i n g - fmalts, w e r e d i s c o v e r e d o n l y w h e n s i n g l e c r y s t a l s w e r e g r o w n l a r g e e n o u g h so t h a t t h e d e v i a t i o n f r o m long range order became apparent. T h e i n t r i n s i c d e f e c t s f o u n d in s i n g l e c r y s t a l s i n c l u d e v a c a n c i e s ,
300
interstitials, i m p u r i t i e s a n d i m p u r i t y c o m p e n s a t i o n s , reverse order, a n d c o m b i n a t i o n s s u c h as V- S a n d I- S, etc. T h e i r n u m b e r s are well d e s c r i b e d by: 6.15.1.-
Ni
= No exp - A Ei / k T
w h e r e i refers to the intrinsic defect. In addition, we have dislocations, b o t h edge (line) a n d spiral (screw), b o t h of w h i c h are three- d i m e n s i o n a l . Their n u m b e r s are well d e s c r i b e d by: 6.15.2.-
A Gi =
n AHi
-
T (ASconfig +
n ASvib)
This e q u a t i o n arises b e c a u s e b o t h of t h e s e e ~ ' i n a i c
defects
affect t h e
e n e r g y of the crystal. We can also have grain b o u n d a r i e s w h i c h m a y be: c l u s t e r i n g of line defects or m o s a i c blocks. The latter m a y be r e g a r d e d as very large g r a i n s in a crystallite. Another
imperfection
in crystals
is called
"twinning".
This
usually
h a p p e n s w h e n e m m t i o m o r p h s are p r e s e n t , or possible. A good e x a m p l e is quartz, i.e.6 . 1 5 . 3 .-
a-quartz
"---v
~- q u a r t z
573 ~ In this case, two crystals grow a n d are j o i n e d at a given plane, each b e i n g a m i r r o r image of the o t h e r . The o t h e r crystal i m p e r f e c t i o n we have not covered is "stacking faults". A good e x a m p l e is SiC. Here, we have two mxblattices, one b a s e d on Si a n d the o t h e r on C, each of w h i c h is hexagonal. In s t a c k i n g a l t ~ t e
layers of
identical atoms, we first s t a c k Si a n d t h e n C. If we refer to "A" as the 1st layer, "B" as the 2 n d layer, a n d "C" as the 3rd layer, t h e n the n o r m a l s t a c k i n g s e q u e n c e for the h e x a g o n a l lattice is: 6.15.4.-
AI~-
AI~-
AI~
301
w h e r e we have s h o w n t h r e e s e q u e n c e s . For SiC, "A" in
t h e first s e q u e n c e
is Si, "B" is C, a n d "C" is Si. We still h a v e t h e s a m e p a c k i n g s i n c e o n l y "A" a t o m s are over "A" a t o m s , as s h o w n in t h e following diagrmm: 6.15.5.-
JSTACKING SEQUENCES IN THE HEXAGONAL LATTICE I
.LAYERS
A
.....
C
'
B A
,
C
....
B
A
A
A C
-
C
oTA
A
w
C A
A '
C
,
B A
B A
B
'
C
B A
B
A
C
B A
B
A
C
B A
....
A
C A
A
B
C
......... A
C
B A
8o
Here, we have a r r a n g e d t h e l a y e r s o n a t w o - d i m e n s i o n a l s t r u c t u r e , e v e n t h o u g h t h e layers are a r r a n g e d in t h r e e d i m e n s i o n a l o r d e r . Note t h a t only two c r y s t a l l o g r a p h i c a x e s are i n d i c a t e d , We call t h i s t h e n a t u r a l s t a c k i n g s e q u e n c e b e c a u s e of t h e n a t u r e of t h e h e x a g o n a l close- p a c k e d l a t t i c e . However, SiC also e x h i b i t s o t h e r s t a c k i n g s e q u e n c e s , as s h o w n in 6 . 1 5 . 6 . , given o n t h e n e x t page. T h e s e a r r a n g e d l a y e r s are called "polytypes" a n d are p r e v a l e n t w h e r e s i m p l e c o m p o u n d s s u c h as SiC a n d SiN are involved. In m a n y cases, t h e p r o p e r t i e s
of s u c h c o m p o u n d s
depend,
to a l a r g e
e x t e n t , u p o n t h e specific s t a c k e d layers o b t a i n e d d u r i n g f o r m a t i o n . 6.15.6.
p - s~c
-
ABC A t ~
SiC - 4H
=
ABCA ABCA
SIC - 6 H
=
ABCACB AI~ACB
S i C - 15R
= AI~BACABACBCACBABCBACABACBCACB
For SiC, w e c a n also h a v e "polytypes" w h e r e two s t a c k i n g s e q u e n c e s l i k e 4H - 6H c a n c o m b i n e to f o r m a u n i t . A n o t h e r " p o l y m o r p h " is 4H - 1 5 R .
302
This p h e n o m e n o n h a s b e e n t h o r o u g h l y s t u d i e d a n d p o l y m o r p h s of
87R
a n d 2 7 0 R have b e e n r e p o r t e d . A n o t h e r t y p e of s t a c k i n g fault is called
"polystructure".
A good e x a m p l e is
ZnS, w h i c h is d i m o r p h i c (has two forms). The cubic form of ZnS is called sphalerite, w h e r e a s the h e x a g o n a l form is called w u r t z i t e (These are t h e i r mineral
names,
after
the
first
geologist w h o
discovered
them).
The
s t a c k i n g s e q u e n c e for s p h a l e r i t e is: AB or ABBA; t h a t for w u r t z i t e is: ABC. A polystructure
sometimes
results
when
sphalerite
is c o n v e r t e d
to
wurtzite: ~
6.15.7.-
ZnS cubic
1200 o c.
=
Z n S hexagonal
The p o l y s t r u c t u r e s e q u e n c e is: ABC ...... AB .......A I ~ .....AB ......ABC. This m a y be r e g a r d e d as cubic- close- p a c k i n g w i t h i n a hexagonal- close- p a c k e d s t r u c t u r e . We m a y also note t h a t ZnS is subject to the s a m e "polytype" s t a c k i n g faults as t h o s e given for SiC above. T h u s , the
s t a c k i n g fault
p a t t e r n s n o t e d are a function of the type of lattice involved, not on t h e c h e m i c a l c o m p o s i t i o n of the material. For the m o s t part, t h e s e s t a c k i n g faults are found only in the high s y m m e t r y lattices
s u c h as h e x a g o n a l
c l o s e - p a c k e d a n d cubic c l o s e - p a c k e d s t r u c t u r e s . 6.16-
ELECTRONIC PROPERTIES OF CRYSTAI~
Although we have d e s c r i b e d the g r o w t h of crystals in s o m e detail, we have not c o n s i d e r e d the behavior of e l e c t r o n s in either crystallites or single crystals. It is the electronic p r o p e r t i e s of s u c h m a t e r i a l s t h a t are useful in i n d u s t r i a l applications. Therefore,
it w o u l d behoove us to c o n s i d e r t h e
factors t h a t c a u s e c h a n g e in electronic p r o p e r t i e s of solids as a function of s t r u c t u r e a n d b o n d i n g . It is evident t h a t this aspect is very i m p o r t a n t , since the electrical n a t u r e of solids varies a c c o r d i n g to b o t h c o m p o s i t i o n a n d a r r a n g e m e n t of a t o m s in the s t r u c t u r e . S o m e m a t e r i a l s
are s e m i -
c o n d u c t i n g a n d o t h e r s are dielectric insulators. Still o t h e r s are g o o d c o n d u c t o r s of c h a r g e (metals). Still o t h e r s have u n i q u e optical p r o p e r t i e s , due to a r r a n g e m e n t of e l e c t r o n s a n d a t o m s w i t h i n the solid state.
303
One e x a m p l e of the l a t t e r is the crystal, ~- BaB204. T h i s crystal b e l o n g s to the trigonal s y s t e m w i t h point syrrm~etry of C3v. It is a negative uniaxial crystal a n d its m a i n u s e is to double the frequency of a laser b e a m . T h e r e is a high t e m p e r a t u r e form, a - B a B 2 0 4 {transition t e m p e r a t u r e of the ~ to a - f o r m = 925 ~ b u t the a - f o r m is not optically active. It is n a t u r a l to a s k w h y this s h o u l d be so. In the case of ~- BaB204, we k n o w t h a t w h e n photons
from a l a s e r b e a m t r a v e r s e
the
crystal, m a n y are
absorbed,
c a u s i n g local a t o m s to b e c o m e e n e r g i z e d {i.e.- go into an excited state). B e c a u s e of the p r e v a l e n c e of a d e n s e p h o n o n s p e c t r u m (i.e.- vibrational s t a t e s of the
lattice),
the
photon
emitted
by e a c h
excited
atom
is
e n h a n c e d by e x t r a e n e r g y a d d e d by the p h o n o n states. T h e s e p h o n o n s t a t e s are c o u p l e d to t h e atomic excited s t a t e s in t h e ~ - f o r m b u t not in the ~- form (probably due to the difference
in lattice
symmetry and
s t r u c t u r e ) . The e m i t t e d p h o t o n t h u s is twice as e n e r g e t i c the fact t h a t its f r e q u e n c y is twice
(2X) t h a t of the
absorbed
wavelength
by the
lattice
while
the
is
as evinced by
original
half
photon
(1/2X).
This
p h e n o m e n o n o c c u r s only w i t h c e r t a i n c l a s s e s of lattice s y m m e t r y a n d c e r t a i n c o m p o s i t i o n s of m a t t e r . A m o n g t h e s e are: L i N b 0 3 , K T i P 0 4 , LIB02 a n d K2TiO3. In s e m i - c o n d u c t i n g c o m p o u n d s , we k n o w t h a t s o m e of the e l e c t r o n s f o r m b o n d s b e t w e e n t h e cation a n d t h e anion, e i t h e r as covalent or ionic b o n d s (or s o m e w h e r e in between). W h a t h a p p e n s to the r e s t ? Do t h e y r e m a i n a r o u n d t h e p a r e n t a t o m ? Why are s o m e solids c o n d u c t i v e while o t h e r s are not? T h e following d i s c u s s i o n a d d r e s s e s t h e s e q u e s t i o n s . Obviously, w e c a n n o t be e x h a u s t i v e b u t we c a n e x a m i n e
the m a i n
features
of e a c h
p h e n o m e n o n to s h o w w h a t h a p p e n s in the solid. We will not derive t h e equations
associated with
each
subject.
This
aspect
is left
to
more
a d v a n c e d studies. A. Conductivity..'.m I o n i c C o m p o u n d s We have a l r e a d y d i s c u s s e d diffusion in solids to s o m e degree. While b u l k p r o p e r t i e s s u c h as h e a t c a p a c i t y are not sensitive to defect c o n c e n t r a t i o n , m a n y o t h e r p r o p e r t i e s s u c h as c o n d u c t i v i t y are. T h u s , the m e t h o d of p r e p a r a t i o n b e c o m e s i m p o r t a n t if one w i s h e s to obtain a c o n d u c t i v e o r
304
even a s e m i - c o n d u c t i n g solid. Most materials in I n d u s t r y are polycrystalline r a t h e r t h a n single-crystal because of cost and difficulty of m an u f actu r e. However, only the single-crystal state suffices for s o m e applications. The degree of conductivity of solids is d e p e n d e n t
u p o n at
least two factors, s t r u c t u r e and ionicity. Ceramic materials are notoriously low in conductivity b e c a u s e their b a n d gaps bet w een the valence and c o n d u c t i o n b a n d are relatively large. This t ransl at es to conductivities of 10 -6 or lower. Contrast this to metals where conductivities of 102 are common. Conductivity in solids d e p e n d s u p o n m o v e m e n t of charge t h r o u g h t h e lattice and includes bot h types of charge. In o x y g e n - d o m i n a t e d m a t e r i a l s s u ch as solid ceramics, the diffusion of charge can only involve e l e c t r o n s and the cation t h r o u g h the s t r uct ur e . We have already c o n s i d e r e d
this
aspect in Chapter 3. In certain s t r u c t u r e s , the electrical conductivity associated with ion m ot i on can exceed conductivity from electrons by several orders of m a g n i t u d e . Diffusion and ionic conductivity are r e l a t e d t h r o u g h the N e a r s t - E i n s t e i n equation, vis: 6.16.1.-
o = Dnq 2 kT
w h er e D is the diffusion coefficient, n is the n u m b e r of charge c a r r i e r s per u n it volume, q is the charge per ion, k is Boltzmann's c o n s t a n t and T is the absolute t e m p e r a t u r e . D generally refers to the more rapidly m o v i n g species. However, there are m a n y ambiguities in the use of this equation to characterize the degree of conductivity, especially w h e n a d i r e c t c u r r e n t is involved. Diffusion usually occurs by the m o v e m e n t of ions to a neighboring crystal defect. In a salt crystal, the m e a s u r e d c u r r e n t m ay be i n d u c e d by m o v e m e n t of interstitial ions (Frenkel) or vacancies (Schottky). The position of a defect c h a n g e s w h e n a neighboring ion moves in to Fill it. S c h o t t l ~ defects p r e d o m i n a t e in KCI where bot h cation and anion vacancies occur. In AgCI, some Ag ions occupy interstitial sites p r o d u c i n g positive Frenkel effects and negative S c h o t t k y defects. Nonetheless, for stoichiometric c o m p o u n d s , the vacancy c o n c e n t r a t i o n and ionic conductivity is very low. If one adds certain "dopants", t h e
305
conductivity will c h a n g e a n d t h a t is w h a t is done to p r o d u c e solids w i t h suitable c o n d u c t i v i t y for c e r t a i n electronic devices. To illustrate exactly w h a t we are discussing, c o n s i d e r the following diagram, w h i c h is b a s e d o n a solid array of w a t e r molecules, i.e.- "ice":
Here, we have a t w o - d i m e n s i o n a l c h a i n of w a t e r m o l e c u l e s w h i c h
are
b o n d e d by van der W a ~ s forces b e t w e e n positive a n d negative c h a r g e s of the individual w a t e r dipoles. If an electrical field (via a voltage) is a p p l i e d to ice, c h a r g e c a n move by diffusion of p r o t o n s . E a c h w a t e r m o l e c u l e in ice is s u r r o u n d e d by four (4) n e i g h b o r i n g molecules. H y d r o g e n a t o m s lie n e a r lines joining a d j a c e n t oxygen a t o m s a n d are closer to one t h a n t h e other. Two n e u t r a l i t y c o n d i t i o n s are satisfied: 1) Water m o l e c u l e s are i n t a c t a n d electrically n e u t r a l 2) The integrity of the h y d r o g e n - b o n d i n g n e t w o r k r e m a i n s intact. One a n d only one h y d r o g e n directly c o n n e c t s to two n e i g h b o r i n g oxygen ions. Violation of either n e u t r a l i t y rule p r o d u c e s an electrically-active defect. A positive b o n d i n g defect w o u l d look like this, as s h o w n in t h e following d i a g r a m as 6.16.3. on the next page.
306
If a p r o t o n is t r a n s f e r r e d to a n o t h e r molecule, a positive h y d r o n i u m ion is c r e a t e d along with a negative hydroxyl ion, i.e.: 6.16.4.-
2H20r
H3 O+ + O H -
The d o t t e d line s h o w s the e x t e n t of the positive defect due to p a c k i n g of the w a t e r m o l e c u l e s in a lattice s t r u c t u r e w h i c h violate the h y d r o g e n b o n d i n g n e t w o r k rule. The s a m e c a n be s e e n for the negative b o n d i n g defect:
Note t h a t the actual b o n d i n g c o n d i t i o n is t h r e e - d i m e n s i o n a l .
In b o t h of
t h e s e cases, r o t a t i o n of a w a t e r m o l e c u l e r e s u l t s in either a positive or negative b o n d i n g defect w h i c h is electrically active. In the first case, a
307
positive defect results w h e n 2H are on the same b o n d and a negative defect w h e n no h y d r o g e n s are present. Note t h a t this type of defect d i s r u p t s the s t r u c t u r e to a m u c h greater degree t h a n the b o n d i n g type of defect.
It is possible for the two types of ions, i.e.- h y d r o n i u m and
hydroxyl, to be n e a r e s t neighbors in the lattice s t r u c t u r e (although w e have not s h o wn t h e m as s u c h here). This gives rise to bot h positive and negative ionic defects in the s t r uct ur e, as show n in the following diagram:
The motion of h y d r o n i u m a n d hydroxyl ions leaves molecules o r i e n t e d against the applied electrical field. The molecular dipole m o m e n t is t h e n anti-paraUel to the field. If b o n d i n g defects are p a s s e d by either of t h e h y d r o n i u m and hydroxyl ions, the molecular dipoles are left parallel to t h e field. Bonding defects dom i nat e the polarization in pure ice because t h e y
308
are mo r e n u m e r o u s t h a n ionic defects. C o n c e n t r a t i o n s of b o n d i n g defects average about 10 .6 per mole of ice. Although ionic defects are fewer in n u m b e r t h a n b o n d i n g defects, they have higher mobility (compared to t h e diffusion m e c h a n i s m of b o n d i n g defects). Thus, the t r a n s p o r t of c h a r g e due to ionic defects is about equal to t ha t actually t r a n s p o r t e d by b o n d i n g defects, w h e n a direct c u r r e n t is applied to ice. Our motive in p r e s e n t i n g this analysis of the m ot i on of charge in ice w h e n an electrical voltage is applied has been designed to acquaint you with t h e complexities of m ot i on of charge in a crystalline solid. Motion of charge in an a m o r p h o u s solid s u c h as glass is even slower t h a n m o s t crystal solids. Solids are divided into three groups bas e d u p o n their conductivity, as w e have already discussed. They are: metals, semi-conductors and insulators.Aqueous solutions are the ot her class of c o n d u c t o r s w hi ch can be u s e d to carry a c u r r e n t of electrons. Metals carry charge because t h e i r valence and c o n d u c t i o n b a n d s overlap, allowing electrons to be easily t r a n s p o r t e d . S e m i - c o n d u c t o r s have a n a r r o w b a n d gap bet w een the two energy b a n d s in the solid and a slight electrical
field is all t hat is
n e c e s s a r y for t h e m to t r a n s p o r t c u r r e n t (electrons). 6.17.- Silicon Single Crystals and I nt e gr at ed Circuits in C o m m e r c e We have already referred to the use of quartz crystals as u s e d in "quartzcrystal" w a t c h e s and timepieces. However, the single crystal grown in largest
quantity
is
silicon
(Si).
Single-crystal
silicon
is
endemic
t h r o u g h o u t our culture and is responsible for the c u r r e n t "InformationAge" e n g e n d e r e d by the use of c o m p u t e r s and ot her e l e c t r o n i c e q u i p m e n t . However, growing defect-free silicon crystals is not an easy task. A. Silic0n Silicon (Si) is a nonmetallic chemical e l e m e n t of the carbon family (Group IVa of the periodic table) and m a k e s up 27.7 p e r c e n t of the E a r t h ' s crust. It is the s eco n d m o s t a b u n d a n t el em e nt in the crust, being s u r p a s s e d only by oxygen.
309
Its e l e c t r o n i c p r o p e r t i e s are: Atomic n u m b e r = 14; atomic w e i g h t = 2 8 . 0 9 Melting p o i n t = 1410 ~ boiling p o i n t = 2 3 5 5 ~ D e n s i t y = 2.33 g / c m S ; oxidation s t a t e = - 4 & +4 E l e c t r o n c o n f i g u r a t i o n = 1 s 2 2 s 2 2 p 2 3 s 2 3 p 2. Silicon w a s first isolated a n d d e s c r i b e d as an e l e m e n t in 1824 b y J 0 n s J a c o b Berzelius, a S w e d i s h c h e m i s t . Silicon does n o t o c c u r u n c o m b i n e d in n a t u r e , i.e.- as a n e l e m e n t . It is f o u n d in p r a c t i c a l l y all r o c k s as well as in sand, clays, a n d softs, c o m b i n e d e i t h e r w i t h oxygen as silica (SiO2= silicon dioxide) or w i t h oxygen p l u s o t h e r e l e m e n t s (e.g., a l u m i n u m , m a g n e s i u m , calcium,
sodium,
p o t a s s i u m , or iron)
as silicates.
Its c o m p o u n d s
also
o c c u r in all n a t u r a l w a t e r s , in t h e a t m o s p h e r e (as siliceous dust), in m a n y plants, a n d in the s k e l e t o n s , tissues, a n d b o d y fluids of s o m e animals. P u r e e l e m e n t a l silicon is a h a r d , d a r k g r a y solid w i t h a metallic l u s t e r a n d with a crystalline s t r u c t u r e the s a m e as t h a t of the d i a m o n d
form of
carbon. For this r e a s o n , silicon s h o w s m a n y c h e m i c a l a n d p h y s i c a l similarities. T h e r e is also a b r o w n , p o w d e r y form of silicon h a v i n g a m i c r o c r y s t a l l i n e form. The e l e m e n t is p r e p a r e d c o m m e r c i a l l y by r e d u c i n g the oxide by r e a c t i n g it w i t h c a r b o n (as coke) in electric f u r n a c e s . On a small scale, silicon h a s b e e n o b t a i n e d from the oxide by r e d u c t i o n w i t h aluminum metal. Silicon, like carbon, is relatively inactive at o r d i n a r y t e m p e r a t u r e s .
But,
w h e n h e a t e d , it r e a c t s vigorously w i t h the h a l o g e n s (fluorine, c h l o r i n e , bromine,
a n d iodine)
to form halides a n d with c e r t a i n m e t a l s to f o r m
silicides. It is u n a f f e c t e d by all acids e x c e p t hydrofluoric. At r e d heat, silicon is a t t a c k e d by w a t e r v a p o r or by oxygen, forming a surface layer of silicon dioxide. W h e n silicon a n d c a r b o n are c o m b i n e d at electric f u r n a c e t e m p e r a t u r e s of 2 , 0 0 0 to 2 , 6 0 0 ~ carbide (Carborundum reacted wi~-hydrogen,
TM
( 3 , 6 0 0 to 4 7 0 0 OF), t h e y form silicon
= SIC), w h i c h is a n i m p o r t a n t
abrasive. Vv"nen
silicon forms a series of h y d r i d e s ,
the sflanes.
Silicon also f o r m s a series of organic silicon c o m p o u n d s called silicones, w h e n r e a c t e d with various organic c o m p o u n d s .
310
Sflicon's
atomic
semiconductor.
structure
makes
Highly purified
silicon,
it
an
doped
extremely with
important
such elements
as
boron, p h o s p h o r u s , a n d arsenic, is the basic m a t e r i a l u s e d in c o m p u t e r chips, t r a n s i s t o r s , silicon diodes, a n d various o t h e r e l e c t r o n i c circuits a n d electrical-current
s w i t c h i n g devices. Silicon of l e s s e r p u r i t y is u s e d in
m e t a l l u r g y as a r e d u c i n g a g e n t a n d as an alloying e l e m e n t in steel, brass, and bronze. The m o s t i m p o r t a n t c o m p o u n d s of silicon are the dioxide (silica) a n d t h e various silicates. Silica in the form of s a n d a n d clay is u s e d to m a k e c o n c r e t e a n d b r i c k s as well as r e f r a c t o r y m a t e r i a l s for h i g h - t e m p e r a t u r e applications. T h e m i n e r a l quartz, i.e.- Si02, m a y be s o f t e n e d by h e a t i n g a n d s h a p e d into glassware. Silicates, m o s t of w h i c h are insoluble in w a t e r , are e m p l o y e d in malOalg glass as well as in the fabrication of e n a m e l s , pottery, china, a n d o t h e r c e r a m i c m a t e r i a l s . S o d i u m silicates, c o m m o n l y known
as w a t e r glass, or silicate of soda, are u s e d
in soaps,
in t h e
t r e a t m e n t of wood to p r e v e n t decay, for the p r e s e r v a t i o n of eggs, as a cement,
a n d in dyeing.
Silicones
are
synthetic
organo-silicon
oxides
c o m p o s e d of the e l e m e n t s silicon, oxygen, carbon, a n d h y d r o g e n . T h e y are
used
as
lubricants,
hydraulic
fluids,
waterproofing
compounds,
v a r n i s h e s , a n d e n a m e l s b e c a u s e , as a class, t h e y are c h e m i c a l l y i n e r t a n d unusually stable at high t e m p e r a t u r e s . T h r e e stable isotopes of silicon are known: silicon-28, w h i c h m a k e s up 92.21 p e r c e n t of the e l e m e n t in n a t u r e ; silicon-29 =4.70%; a n d silicon-30 = 3.09 %. Five r a d i o a c t i v e isotopes are k n o w n . B. Silicon as a S e m i - C o n d u c t o r In s e m i c o n d u c t o r s s u c h as silicon, e a c h a t o m in the s t r u c t u r a l lattice has four o u t e r electrons, e a c h of w h i c h covalently p a i r s w i t h an e l e c t r o n f r o m one of the four n e i g h b o r i n g a t o m s to form the i n t e r a t o m i c b o n d s , i.e.- t h e "diamond"
structure.
Completely
pure
silicon t h u s h a s e s s e n t i a l l y no
e l e c t r o n s available at r o o m t e m p e r a t u r e for e l e c t r o n c o n d u c t i o n , m a k i n g it a v e r y p o o r c o n d u c t o r . However, the key is g e t t i n g the silicon p u r e e n o u g h . Originally, silicon w a s t h o u g h t to be a n a t u r a l s e m i - c o n d u c t o r until really p u r e silicon b e c a m e available.
311
Growth of silicon crystals begins with the p r e p a r a t i o n of extremely p u r e polycrystalline silicon having fewer t h a n 1 d o p a n t a t o m per 10 billion silicon atoms. This
silicon is m e l t e d
in a quartz-lined
furnace. T h e
t e m p e r a t u r e of the m o l t e n silicon is r e d u c e d to j u s t above the m e l t i n g point, an d a small bar (the seed)
of silicon in single-crystal form is
i n t r o d u c e d into the surface of the melt. The m o l t e n silicon freezes slowly onto the seed with a crystalline s t r u c t u r e t h a t is contiguous with t h e s t r u c t u r e of the seed (For m o r e details, see the Czochralski m e t h o d given above). The seed is slowly w i t h d r a w n , while rotating u n d e r carefully controlled conditions, to form a single-crystal cylindrical ingot of silicon. This ingot is greater t h a n 200 m i l l i m et ers in d i a m e t e r a n d weighs up to 100 kilograms (220 pounds). After growth, the silicon crystal is g r o u n d to a s m o o t h cylinch'ical s h a p e and sliced into thin wafers, using d i a m o n d tools. These wafers are usually about 0.6 millimeter thick. The surfaces of the wafers are polished fiat by a series of successively finer abrasives until one side has a perfect m i r r o r finish. For the m a n u f a c t u r e of i n t e g r a t e d circuits, the m e t h o d s u s e d to achieve planarity and s m o o t h n e s s of t h e individual discs are extremely i m p o r t a n t . We will discuss these below. If an a t o m from c o l u m n V of the periodic
table, s u c h as e l e m e n t a l
p h o s p h o r u s , is s u b s t i t u t e d for an atom of silicon, four of its five o u t e r electrons are us e d for b o n d i n g in the t e t r a h e d r a l lattice, b u t the fifth is free to move within the crystal (which t h e n b e c o m e s a "negative-type" semi-conductor). If the r e p l a c e m e n t a t o m comes from c o l u m n III of t h e periodic table- s u c h as boron, it will have only three out er electrons, i.e.one too few to complete the four i n t e r a t o m i c bonds. Since the crystal a t t e m p t s to become electrically neut r a l were
this b o n d complete,
the
vacancy acquires a positive charge because an electron is m i s s i n g in t h e overall electronic s t r uct ur e . A neighboring electron can move into t h e vacancy, leaving a n o t h e r vacancy in the space previously occupied by t hat electron. This -vacancy, with its positive charge, is t h u s mobile and is called
a "hole."
Holes in
semiconductors
move
about as readily
as
electrons do, but because they are positively charged, they obviously m o v e in a direction opposite to the m o t i o n of electrons. This form of silicon is called a "positive-type" s e m i c o n d u c t o r .
312
The p r o c e s s of s u b s t i t u t i n g e l e m e n t s
for the silicon is called d o p i n g ,
while the e l e m e n t s are r e f e r r e d to as d o p a n t s . The a m o u n t of d o p a n t t h a t is r e q u i r e d dopant
in practical devices is very small, r a n g i n g from about 1 0 0
a t o m s per
million
silicon
atoms
downward
to
1 per
billion.
D o p a n t s are usually a d d e d to the silicon after the crystal g r o w t h p r o c e s s , w h e n a n i n t e g r a t e d circuit is b e i n g f o r m e d on the surface of the wafer. C. S e m i c o n d u c t o r Devices The fact t h a t p u r e silicon is not a c o n d u c t o r b u t is "doped" to m a k e it a good s e m i - c o n d u c t o r
might
s e e m odd,
p a r t i c u l a r l y since c o n s i d e r a b l e
effort goes into o b t a i n i n g very p u r e silicon. N o n e t h e l e s s ,
the u n d o p e d
silicon is n o t conductive. This allows one to form d i s c r e t e a r e a s of n - t y p e a n d p-type silicon o n the s a m e wafer a n d to position t h e s e in c o n j u n c t i o n with e a c h o t h e r in a m a n n e r so t h a t a c u r r e n t amplifying device r e s u l t s . An e x a m p l e of s u c h a device is s h o w n in the following diagram:
Here, we s h o w a so-called " c o m m o n - e m i t t e r "
configuration of a p - n - p
t r a n s i s t o r , i.e.- the e m i t t e r s t a t e s are c o u p l e d together. In general, s u c h a
313
configuration w o u l d be f a b r i c a t e d by forming the p- a n d n - t y p e s of silicon t h r o u g h injection
of the p r o p e r
i m p u r i t y at n e i g h b o r i n g
sites on t h e
surface of the silicon wafer. As s h o w n in the diagram, a voltage is a p p l i e d between
the p o i n t s E & B (where
E is electrically c o n n e c t e d
to t h e
e m i t t e r p o r t i o n of the p - t y p e a r e a s a n d B is c o n n e c t e d to the b a s e (or ntype) area). The c o n n e c t i o n s are usually c o n d u c t i v e lines p r i n t e d on t h e surface of t h e n o n - c o n d u c t i v e Si-wafer. One p - t y p e a r e a is u s e d as the e m i t t e r ( h o l e - c o n d u c t i o n ) while the o t h e r is u s e d as the collector (of c u r r e n t ) w h e n the i n p u t voltage is a p p l i e d b e t w e e n p o i n t s B & E at t h e t r a n s i s t o r . T h i s r e s u l t s in a c u r r e n t , I B , f r o m the b a s e as well as a c u r r e n t ,
IC , from t h e collector.
T h u s two local
circuits are at work, one t h r o u g h the e m i t t e r - b a s e a n d t h e o t h e r t h r o u g h the base-collector. The i m p o r t a n t p a r t to notice is t h a t a l t h o u g h t h e c u r r e n t , I B , is in m i c r o - a m p s , the c u r r e n t , I c , is in m i l l i a m p s , an amplification of 1000 x. T h u s , the p - n - p c o n f i g u r a t i o n on the surface of a silicon
wafer
results
in
an
amplifier
of c u r r e n t
(also
known
as
a
transistor). A n u m b e r of d i s c r e t e s t e p s are r e q u i r e d to m a k e s u c h a t r a n s i s t o r a n d passive p a r t s s u c h as r e s i s t e r s a n d c o n d e n s o r s
are also a d d e d to m a k e
w h a t is called an " i n t e g r a t e d circuit" or IC. D. I n t e g r a t e d C i r c u i t s An i n t e g r a t e d circuit (IC) is a m o n o l i t h i c a s s e m b l y of electrically i s o l a t e d circuit e l e m e n t s . W h a t this m e a n s is t h a t e a c h circuit e l e m e n t is f o r m e d on top o f , or b e n e a t h , o t h e r circuit e l e m e n t s to f o r m a c o m p a c t assembly. E a c h c o n d u c t i v e layer is s e p a r a t e d by a n o n - c o n d u c t i n g layer, usually c o m p o s e d of an oxide s u c h as silicon dioxide, SiO2. T h e a s s e m b l y i n c l u d e s b o t h active s e m i c o n d u c t o r
devices ( t r a n s i s t o r s a n d diodes)
a n d passive
c o m p o n e n t s ( c a p a c i t o r s a n d resistors). T h e s e are c o n n e c t e d
t o g e t h e r by
m e a n s of electrically c o n d u c t i n g i n t e r c o n n e c t i o n s s e p a r a t e d b y i n s u l a t i n g layers w i t h holes fabricated
for layer-to-layer i n t e r c o n n e c t i o n .
in situ by an iterative
process
AU e l e m e n t s
of l i t h o g r a p h i c
are
definition,
deposition, a n d e t c h i n g on a c o m m o n s u b s t r a t e (in m o s t cases, silicon) in
314
s u c h a m a n n e r t h a t the resulting i n t e r c o n n e c t e d e l e m e n t s p e r f o r m t h e desired electrical circuit function. Lithographic refers to the p h o t o g r a p h i c process u s e d w her e a p h o t o r e s i s t (a material w h i c h f o r m s either a water-soluble or water-insoluble area u p o n exposure to the p r o p e r wavelength of light) is u s e d to define the areas exposed. It is these areas which are t h e n subjected to definition, deposition a n d etching. These are a m o n g the m a n y p r o c e s s e s to which each wafer is subjected during t h e process to m a k e IC's. Many ICs, typically about 5.5 m m long or up to 33 square millimetres in area, are fabricated c o n c u r r e n t l y on silicon wafers up to 3 0 c e n t i m e t e r s (12 inches) in d i a m e t e r and s u b s e q u e n t l y sawed into individual chips (dies) prior to packaging. An IC chip t h u s p r o d u c e d is usually sealed in a plastic package with
electrical
leads
that
are
internally c o n n e c t e d by f'me wires to o u t p u t pads on the silicon die t hat p e r m i t the p a c k a g e d IC to be a t t a c h e d to a circuit card. The integration of a large n u m b e r of s e m i c o n d u c t o r devices on a single die of silicon is m a d e possible by the high operational efficiency of t h e individual devices. Because of this, power dissipation is m i n i m a l as are t h e r e q u i r e m e n t s for he a t removal. The result is an IC of high dependability, which is further e n h a n c e d by the process of integration itself. It is t h e m e t h o d of m a n u f a c t u r i n g the electrical i n t e r c o n n e c t i o n s b e t w e e n t h e devices and circuit e l e m e n t s by metal d e p o s i t i o n and etching t h a t yields an extremely dependabl e circuit s t r uct ure. The n u m b e r of devices i nteg r ated on a single tiny chip has i n c r e a s e d from an initial few to nearly 1 0 , 0 0 0 , 0 0 0 individual circuit e l e m e n t s per die with ever-smaller features in the d e v e l o p m e n t stage. This has, in turn, led to a progressive i n c r e a s e in complexity, as exemplified by the m e t a l - o x i d e - s e m i c o n d u c t o r (MOS), the dynamic random-access memory (DRAM), and the MOS microprocessor. Since m a n u f a c t u r i n g cost is pr opor t i onal to chip area, the use of s m a l l e r features has not only led to an increase in complexity a n d r e s u l t i n g functionality b u t also has p r o d u c e d a decrease in cost per t r a n s i s t o r and an increase in circuit p e r f o r m a n c e . There are two r e a s o n s for the latter:
315
(i) the p e r f o r m a n c e of the individual active devices improves as their internal d i m e n s i o n s become smaller. (2) the quality of the p e r f o r m a n c e of the entire circuit improves as the active devices are positioned closer to one a n o t h e r . Large-volume
applications
for
IC
dies
have
further
lowered
the
m a n u f a c t u r i n g costs per IC. The cumulative result is t h a t the i n t e g r a t e d circuit has become the m o s t pervasive technology of the 20t h century. It has provided
the
cornerstone
of m o d e r n
microelectronics
and
has
p r o m o t e d the d e v e l o p m e n t of the so-called information society. Applications of ICs include their use in c o m p u t e r s as well as o t h e r i n s t r u m e n t s . It is t h e s e applications t h a t are bringing about revolutionary advances in medical
diagnosis, biotechnology,
aeronautical and space
e ng in eer in g of our age. Other technologies affected (and vastly i m p r o v e d ) are t e l e - c o m m u n i c a t i o n s , and military defense systems. IC's have fueled the d e v e l o p m e n t of new c o n s u m e r p r o d u c t s capable of bringing new types of services an d information to the h o m e
and office e n v i r o n m e n t
that
otherwise would not have b e e n possible. Our next step will be to describe the steps r e q u i r e d in the m a n u f a c t u r e of Ics. As you will see, they have becom e quite c o m p l i c a t e d . E. Manufacture of I n t e g r a t e d Circuits v
The p r o ces s of fabricating s e m i c o n d u c t o r devices is a complex series of m o r e t h a n 600 sequential steps, all of w hi ch m u s t be done with u t m o s t precision in an e n v i r o n m e n t cleaner t h a n a hospital operat i ng room. If particles
are present,
they can cause electrical
shorting
among
the
conductive lines et ched on the surface of the silicon wafer. Thus, no impurities which m i g h t affect the wafer surface either physically or chemically can be tolerated. A series of layers is t h u s formed. This reality m a n d a t e s the m a n u f a c t u r e of IC's in a closed "clean-room". Since a h u m a n being emits a r o u n d 5 0 0 0 particles per m i n u t e (notably skin particles), it is n e c e s s a r y t h a t all oper a t i ng p e r s o n n e l involved in the m a n u f a c t u r i n g p ro ces s wear special clothing and m a s k s to prevent c o n t a m i n a t i o n of t h e wafer during the various 600 o p e r a t i o n s r e q u i r e d to m a k e a finished IC.
316
The objective is to a d d the c o r r e c t d o p a n t s in the p r o p e r a m o u n t s in t h e right places on the silicon wafer to form t r a n s i s t o r s a n d c o n d u c t o r s at t h e right place on t h e surface layer, w h i c h t h e n m a y be covered
u p by a
s u c c e e d i n g layer. It is usual to form a n u m b e r of s e p a r a t e i n t e g r a t e d circuits on e a c h wafer, to form an isolated a r e a on t h e "die" or "chip". As many
as several
thousand
are
formed
at
the
same
time.
This
is
a c c o m p l i s h e d by u s e of an applied coating w h i c h is sensitive to light, i.e.a "photoresist". By u s e of a carefully crafted film, m u c h like a p h o t o g r a p h i c negative, the outline a n d details of the i n t e g r a t e d circuit are f o r m e d by e x p o s i n g only c e r t a i n p a r t s of the p h o t o r e s i s t layer or film to t h e light as modified by the " p h o t o m a s k " u s e d in e x p o s u r e . E a c h die is f o r m e d by a machine
called
a
"stepper".
The
photo-outline
desired
is
formed
s e q u e n t i a l l y a c r o s s t h e e n t i r e surface of the silicon wafer, as s h o w n in 6.17.2., given on the n e x t page. Note t h a t lines of 0.13 p, i.e.- 0.13 m i c r o n s , in w i d t h are b e i n g f o r m e d r o u t i n e l y in the m a n u f a c t u r e of IC dice
t o d a y ( J u s t 3 y e a r s ago, t h e
n u m b e r w a s 0.18 p. It is e x p e c t e d to go to 0.08 ~ by 2010).
Once t h e
basic circuit is formed, t h e n s u b s e q u e n t s t e p s on e a c h individual die f o r m b o t h n- a n d p-layers, electrically isolated from e a c h o t h e r by a d i e l e c t r i c s u c h as S i O 2 . Both r e s i s t o r s a n d c o n d e n s e r s are r o u t i n e l y f o r m e d in p l a c e as well. Note t h a t f o r m a t i o n of s o m e of the layers is a c c o m p l i s h e d by use of g a s e s s u c h as ASH3, BBr3, or P H3. In o t h e r cases, a thin-trim p r o c e s s is u s e d to form the layers. T h i n - f i l m p r o c e s s e s u s e d in the m a n u f a c t u r e of IC's i n c l u d e : Physical v a p o r d e p o s i t i o n
Chemical vapor deposition
Electron-beam evaporation
Plasma etching
Electroplating
Photoresist
Reactive ion e t c h i n g Wet e t c h i n g
Photolithography
Molecular b e a m e p i t a x y
Ion i m p l a n t a t i o n
Chemical-mechanical polishing Rapid t h e r m a l p r o c e s s i n g Vacuum sealing
S p i n - o n glass d e p o s i t i o n Cathodic arc Ion p l a t i n g
Resistance heating
317
In practice, the s t e p p e r consists of a m a c h i n e i n c o r p o r a t i n g a light source, a p h o t o m a s k holder and a lens for focusing the p a t t e r n on t h e p h o t o r e s i s t layer on the silicon wafer. The p a t t e r n is r e p e a t e d clear across the wafer, step by step, hence the name. The lens s y s t e m m u s t be of highest quality so t h a t definition of lines and areas r e m a i n accurate and do not overlap each o t h e r . Note t h a t there are two types of p h o t o r e s i s t s - positive a n d negative. One is polymerized (made insoluble in water) by exposure to light while t h e
318
o t h e r b e c o m e s soluble ( d e - p o l y m e r i z a t i o n ) u p o n e x p o s u r e to light of t h e p r o p e r w a v e l e n g t h . T h e u s e of one or the o t h e r d e p e n d s u p o n t h e actual step in IC m a n u f a c t u r e b e i n g a c c o m p l i s h e d . simple
washing
w a s h i n g or m o r e
procedure, strenuous
whereas means
the such
One c a n be r e m o v e d by a
other
is r e m o v e d
as b a k i n g or
removal of the n o n - e x p o s e d p a r t s of the p h o t o r e s i s t ,
by e i t h e r
ashing.
Before
the n e x t step is to
expose the silicon surface to w h a t e v e r r e a c t a n t is r e q u i r e d to form t h e layer u n d e r c o n s t r u c t i o n on e a c h IC wafer. T h i s is done r e i t e r a t i v e l y until the basic IC circuit is formed. Once this is done, t h e layers are covered to form the final form of the wafer.
T h e n the p o r t i o n c o n t a i n i n g e a c h circuit is c u t into a small s q u a r e called a "die", m a n y being called "dice". The scale of line d i m e n s i o n s , i . e . - w i d t h , in i n t e g r a t e d circuits in 1997 w a s 0 . 2 5 m i c r o n s (2.5 x 10 v m e t e r s ) . It c o n t i n u e s to d e c r e a s e y e a r by year. A p p r o x i m a t e l y
1,850
dice
c a n be
o b t a i n e d from a 2 2 0 m m wafer, if all of the dice t e s t "good". T h u s , t h e d i a g r a m given above is not a c c u r a t e b e c a u s e the details of m y d r a w i n g cannot
be
made
precise
enough
to
accurately
detail
all
of
the
c h a r a c t e r i s t i c s of dice f o r m a t i o n on the surface of the silicon wafer a n d still illustrate the point. A h i g h - p o w e r s e m i c o n d u c t o r device for i n d u s t r i a l use, on the o t h e r h a n d , m a y be so large as to r e q u i r e a slice of silicon m e a s u r i n g well over 125 m i l l i m e t e r s in d i a m e t e r . Of late, the c u r r e n t size {or c r o s s - s e c t i o n ) for a s e p a r a t e line or c o n d u c t o r in an i n t e g r a t e d c i r c u i t is 18 m i c r o n s . R e s e a r c h h a s d e c r e a s e d this size to 13 m i c r o n s in 2 0 0 3 with 8 m i c r o n s (~rn) in the offing. Obviously, this i n c r e a s e s t h e yield in the n u m b e r of dice from one wafer by d e c r e a s i n g the actual size of e a c h individual die b e i n g formed. T h i s year, the first 3 0 0 m i l l i m e t e r c a m e on s t r e a m in p r o d u c t i o n
units making integrated
circuits.
wafer This
e n l a r g e m e n t in size w a s d e s i g n e d to i n c r e a s e the yield of dice by 1 4 5 % over w a f e r s only 2 0 0 m m in d i a m e t e r . A m a j o r c h a n g e in e q u i p m e n t was n e e d e d to h a n d l e the larger w a f e r s a n d the total cost to do so w a s in t h e billions of dollars. F. S t e p s in t h e M a n u f a c t u r e of I n t e g r a t e d Circuits The fabrication of ICs b e g i n s w i t h the p r e p a r a t i o n of silicon of very h i g h
319
purity. Single c r y s t a l b o u l e s w i t h a d i a m e t e r as large as 30 c e n t i m e t e r s are p r o d u c e d . T h e b o u l e s are sliced into w a f e r s h a v i n g a specified c r y s t a l o r i e n t a t i o n . This m e a n s t h a t t h e d i r e c t i o n of s i n g l e - c r y s t a l g r o w t h m u s t be controlled. W h e n t h e i r s u r f a c e s have b e e n p o l i s h e d fiat to a m i r r o r l i k e finish t h a t is free of defects, the silicon wafers are r e a d y for fabrication into
IC devices.
The
supreme importance formed.
For example,
methods
of p l a n a r i z a t i o n
and
polishing
are
of
to t h e overall quality of t h e c h i p s or dice b e i n g the following lists s o m e of t h e factors t h a t a r e
specified for a c c e p t a b l e silicon wafers w h i c h are u s e d to form 0.13 v m lines in the IC: Critical P r o c e s s S t e v Oxygen c o n t e n t > 30 p p m
Crystal g r o w t h
F l a t n e s s = 1.5 lma (side to side)
Lap ping, G r i n ding,Po l i s h i n g
W a r p = 25 ~ m
Slicing
Particles = < 1 0 0 / w a f e r
Polishing, Cleaning,
Non-critical m e t a l s = < 16 p p m
Cleaning
Critical m e t a l s = < 45 p p m
Cleaning
Crystal g r o w t h
Note t h a t the oxygen c o n t e n t is c o n t r o l l e d in the c r y s t a l growing p r o c e s s . The p r e s e n c e of m e t a l s on the wafers is d u e to t h e slicing a n d p o l i s h i n g s t e p s w h e r e the c l e a n i n g p r o c e s s
did not r e m o v e all of t h e s e e m ~ m a l
m e t a l particles. T h e difference b e t w e e n critical a n d n o n - c r i t i c a l m e t a l s is whether
t h e y w o u l d affect t h e c o n d u c t i v i t y of the silicon if t h e y w e r e
a c c i d e n t a l l y c a u s e d to c o m b i n e w i t h the silicon c o m p r i s i n g the wafer. T h e o t h e r factor not yet a d d r e s s e d by u s is the d a m a g e c a u s e d by t h e various p r o c e s s e s u s e d to form the finished wafer. A m o n g the d a m a g e c a p a b l e of b e i n g evoked on t h e surface of t h e silicon is the f o r m a t i o n of vacancies, s c r a t c h e s a n d dislocations in t h e silicon s t r u c t u r e .
For t h e s e
reasons,
e a c h m a n u f a c t u r e r of wafers h a s developed its own p r o p r i e t a r y p r o c e s s . S o m e of t h e s e p r o c e s s e s are slow and, of course, c o n t r i b u t e to t h e overall cost of t h e s o - p r o d u c e d wafers. T h i s is s h o w n in t h e follo~qng table, p r e s e n t e d on t h e n e x t page.
320
Table 5-4 Comparison of Some Wafer Manufacturing Operations Operation
Slicing (ID saw)
Depth of Damage
Flatness of Processed Wafer
Rough, two-side polish
poor high poor medium good low-med good medium zero good zero very good
Finish polishing
zero
good
Plasma chemical e t c h i n g
zero
Plasma torch & ADP*
zero
excellent good
Slicing (wire saw) Lapping(multiple wafer) Grinding(single wafer) Wet chemical e t c h i n g Rough, one-side polish
Relative Speed of Process
slow medium fast fast medium slow slow very slow slow medium
Ease of Automation
good medium poor good good good poor good good good
ADP = Atmospheric Downstream Plasma Note that some processes produce little or no surface damage but that t h e process is slow. What this m e a n s is that the m a n u f a c t u r e r m u s t choose between finishing processes and acceptable damage during processing. When some damage is left on the surface of the wafer or if the planarity is not good, then the IC processes used result in defects in the IC circuit a n d / o r in the individual transistors formed. This results in a "bad" die or chip, i.e.- it does not function properly. It is for this reason that t h e n u m b e r of "good" dice or chips vary from wafer to wafer. Note that electronic testing is required to determine ff a die is good or not. T h e typical IC manufacturing process involves a sequence of more t h a n 6 0 0 operations. These operations may be categorized according to function: 1. Deposition of thin films 2. Introduction of impurities (doping) 3. Lithographic patterning of IC features corresponding to those of the physical layout 4. Etching to define the features of individual circuit e l e m e n t s
321
5. Annealing to cause a chemical reaction or to form t h e desired m i c r o s t r u c t u r e between films
of
deposited
films
or
interfaces
6. Polishing to level and s m o o t h the surface 7. Cleaning to pr e ve nt c o n t a m i n a t i o n a n d the c o n s e q u e n t i n t r o d u c t i o n of defects into circuit e l e m e n t s by p a r t i c u l a t e matter. These o p er ations are r e p e a t e d
again a n d again in different
sequential
order until the IC fabrication is completed. At the sam e time, t hey are n o t the actual steps n e e d e d to form the individual dice. We will a d d r e s s t h e s e later on after we
have described
the
individual operat i ons
used
in
p e r f o r m i n g each step in the IC m a n u f a c t u r i n g process. It is very important to distinguish be t w een manufacturing operations and m a n u f a c t u r i n g steps. The actual m a n u f a c t u r i n g steps involved include: I. Wafer cl eani ng 2. Lithography 3. Planarization 4. Ion i m p l a n t a t i o n 5. S p u t t e r i n g 6. C V D - c h e m i c a l vapor d e p o s i t i o n 7. Resist s t r i p 8. Wafer cl eani ng 9. T h e r m a l p r o c e s s i n g I0. Metrology The following diagram, given as 6.17.3 on the next page, shows the cyclic n a t u r e of the steps u s e d to form the i n t e r m e d i a t e layers of an e l e c t r o n i c device. In this case, we have s h o w n at least 8 individual steps n e e d e d to fabricate this s t r u c t u r e . Note t h a t the use of p h o t o r e s i s t is not i n d i c a t e d in the CVD steps, although it plays a significant role in the overall p r o c e s s . Note t h a t these s a m e 8 steps can be r e p e a t e d so as to build up a series of electrical an d isolated layers w h i c h c o m p r i s e the overall IC d e s i g n
322
6.17.3.-
[I
p,oCe,,, ,o,uo.oo- II INPUT WAFER
+
IWAFER CLEANING (PRE-TREATMENT)]'~------l OXIDATION
--
+
[ETCHING ILIONIMPLANTATION] + [ WAFER CLEANING (POST-TREATMENT)
1
.~
circuits. However, even this diagram does not show all of the cyclic s t e p s and m a c h i n e r y needed to accomplish the 600 individual steps referred to above in the m a n u f a c t u r e of an integrated circuit on a silicon wafer. As shown in 6.17.4. given on the next page, the m a n u f a c t u r e begins with a polished wafer. Study this outline well. It gives m o s t of the 600 steps involved in IC manufacture. The first step is usually formation of an oxidized Film layer, followed by microlithography steps. We have indicated the individual steps involved in lithography, as well as those involved in m a s k making. Note t h a t the n e x t step involves etching and stripping steps. Inspection is the next major step, followed by doping and t h e n diffusion and oxidation ( d e p e n d i n g upon the specific layer being formed). Reinspection t h e n takes place. If
323
[!SEMICONDUCTORFABRICATION 'STEPS I[
6.17.4.-
Equipment Includes: Wafer Processing- Test - Assembly
IR ~
Silicon & Wafer Making[
Includes: Crystal growing, grinding to diameter, wafer slicing & polishing Circuit Design and Mask Fabrication
Includes: Pattern generator, photo-repeater, electron -beam lithography and contact printer
inc1 d :
I or reactive ion etch I'~ Dry or wet strip I or both. I Ist
LInspecti~
Includes either optical or electrical inspection or both
I ~, i~ r
2nd
ASSEMBLY
[~i~olithog.~phy[ Includes: applying photoresist, scrub & dei~0rclrate,mask align & expose, develop, rinse & bake. Equipment: Contact/proximity scan projection alignment, wafer stepper
Ne~:t
Cy~ Ie
.....~................
l_ A,
Ist
IW~-~R PROBE & TEST I includes: Automatic test equipment: KS[ logic I_SI m e m o r y Other testers Probing and handling equipment
I [Film Deposition] Includes: Chemical (oxide films) " and Physical (like "spin-on" glass or metallization films) Chemical Physical Equipment Equipment Normal press C V D Spin -On table Lo-~ press C V D we~uum Plasma C V D evaporator, Epitaxial sputtering
~I
I DopinI~ I Includes: Ion implanterboth m e d i u m & high current; Furnacesdiffusion annealing oxidation
IDiffusion & Oxidation I Includes: Thermal or chemical processes or both
+ I M A S K FINISHEI3-? I y~I
I
I
h._
i
1.Dici.ni~-here x v ~ r is cut in dice
2. Die Attach
3.Wire B o n d - each die mc~anting is bonded, both electricallyand physically
Here each die 4. Mold & Seal is attached to Here, the a mounting mounting is sealed Equipment: Scribers & saws, die bonders, molds & presses, Other.
324
the m a s k lithography is finished, t h e n wafer-probe testing t h e n t a k e s place. If not, t h e n the cycle begins anew at the f'flm deposition stage. After wafer probe an d testing, assembly of the cut dice into a m o u n t i n g t a k e s place by attaching wires to appr opr i at e points of the i n t e g r a t e d circuit, the wires are t h e n bonded, and the whole is sealed before final t e s t i n g and s h i p m e n t . In order
to illustrate
exactly w h a t we
are discussing,
the
following
diagram of a CMOS design u s e d in 1997 is p r e s e n t e d on the following diagram. That is, a p-type silicon source is formed on an n-type well, and vice-versa.
"Sources" are formed in the first step and t hen "Gates" are formed.
A
silicide is t h e n u s e d to lower the contact resistance bet w een the silicon of the gate, source a n d drain a n d the cont act i ng plug. The t h i c k n e s s of gate oxides is only about 4 0 - 5 0 A. They are t herm al l y grown r a t h e r t h a n
325
deposited by CVD. Nitrides, s o m e t i m e s c o m b i n e d with oxides, are b e i n g u s e d to s u p p r e s s bor on p e n e t r a t i o n from the gate. Silicides are formed by depositing a metal s u c h as titanium, t u n g s t e n or cobalt, followed by r a p i d t h e r m a l p r o c e s s i n g to form the silicide. The silicide in greatest usage was t h at of Ti, wh ere the silicide was essentially a TiOxSi type of c o m p o u n d . Ti/TiN is mostly u s e d now. The d e p t h of the s o u r c e / d r a i n s for 0.25 ~ m line CMOS designs is about 60 nm., i.e.- quite shallow. Elemental boron is i m p l a n t e d by p l a s m a implantation, using about 5 kV acceleration of B3+ ions. Polysilicon gate t r a n s i s t o r s are formed separately as p-type and ntype. Diffusion barriers are u s e d to prevent diffusion of materials to or from the r e t r o g r a d e wells already formed. The s m o o t h n e s s and t h i c k n e s s of these films are of particular concern. S m o o t h films help s u b s e q u e n t viahole filling by hot or w a r m a l u m i n u m deposition. Thin films are desirable to keep the r es i s t a nc e of the plug low. T u n g s t e n is u s e d for electrical contact and via-plugs. I n t e r c o n n e c t m e t a l s u s e d in 1997 were a l um i num , s o m e t i m e s c o m b i n e d with copper. T hi s was called "damascene", b u t in 2003, copper is being u s e d al m ost exclusively. Once the m e t a l c o n n e c t is deposited by evaporation or CVD, metal etching is u s e d to remove those p a r t s of the m et al film not n e e d e d . I n t e r c o n n e c t dielectrics include the use of "spin-on-glass" (which is a slurry of l o w - t e m p e r a t u r e - s o f t e n i n g glass particles) or silicon oxide films formed by h i g h - d e n s i t y p l a s m a processes. shown in the
above figure,
are n e e d e d
Note t h a t at least 8 steps, to form the
finished
CMOS
t r a n s i s t o r s tr u c t ur e. The outline given above is the fabrication t e c h n i q u e u s e d to m a n u f a c t u r e this s i m p l e CMOS device on a silicon wafer. R e m e m b e r t h a t the s t r u c t u r e given a nd described above was fabricated and duplicated about 1800 times on a specific silicon wafer. Following t h e f'mal step, the wafer was cleaned and t h e n cut into dice. Each die is t h e n m o u n t e d and electrical c o n n e c t i o n s m a d e prior to its use in a given device. What we have not described adequately is the complexity of achieving j u s t one of the features, i.e.- layers, s h o w n in 6.17.5. C o n s i d e r the actual fabrication steps n e e d e d to m a k e j u s t one of the features s h o w n therein, i.e.- the "gates" of the CMOS s t r u ct ure. At level 3 of 6.17.5., t h e gates are shown. The separate steps are illustrated in the following diagram, p r e s e n t e d as 6.17.6. on the next page.
326
The
major
steps
are
labeled
1 to
5.
However,
there
are
several
i n t e r m e d i a t e s t e p s also involved. At "1", the shallow t r e n c h e s are f o r m e d , s o u r c e a n d d r a i n i m p l a n t s w e r e a c c o m p l i s h e d , diffusion b a r r i e r s w e r e f o r m e d from Ti/TiN a n d a d u m m y gate m a d e from Si3N4 w a s d e p o s i t e d on a d u m m y oxide gate. Five s e p a r a t e p h o t o m a s k s were u s e d to a c c o m p l i s h t h e s e i n t e r m e d i a t e steps. At "2", a p r e - m e t a l dielectric film, S i O 2 , was deposited
by low
pressure
CVD a n d
planarized
by CMP
("Chemical
M e c h a n i c a l Planarization") in o r d e r to u n c o v e r the top of the d u m m y g a t e (2 steps). At "3", wet a n d dry e t c h i n g w a s u s e d to r e m o v e the d u m m y g a t e a n d the gate groove w a s fabricated. A gate oxide of T a 2 0 5 w a s t h e n g r o w n in the groove. (4 steps). At "4", a W / T i N layer w a s d e p o s i t e d (2 steps) a n d then
planarized
to
its
final form
in
"5".
Note
that
a total
i n t e r m e d i a t e s t e p s were r e q u i r e d in the f o r m a t i o n of t h e gates.
of
14
327
Metailization of contacts, formed and c o n n e c t e d .
vias and i n t e r c o n n e c t
metals
still need
to
A significant n u m b e r of different m a c h i n e s are n e e d e d to accomplish t h e above fabrication steps. Such m a c h i n e s includeI. Lithographic- Optical wafer steppers are the most expensive and critical m a c h i n e s used in the Fabrication Laboratory. 2. Planarization- Chemical mechanical planarization m a c h i n e s are used to level the topology of the films deposited on the wafer. Chemical-mechanical smoothing is the process used to improve process uniformity, repeatability, removal rate, planarity and defect reduction. Thus, planarization is requisite to producing defect-free CMOS circuits. 3. Ion Implantation- these plasma m a c h i n e s are used to form t h e various parts of the coupled transistors at voltages of 5 kV to 2 MV. These include retrograde well formation, gates, drains and sources. 4. S p u t t e r i n g - Deposition of copper doped (damascene) aluminum interconnects, as well as diffusion barriers, and anti-reflective stacks of Ti/TiN is done by this technique. The metal is heated by an electron b e a m and "sputters" onto the target. Nitrogen gas is used w h e n TiN is r e q u i r e d . 5. Chemical Vapor Deposition- Deposition of silicon oxide films is accomplished by CVD equipment. Either plasma CVD or ozone oxidation is used. Blanket tungsten films are also deposited by CVD equipment to create contact and via plugs. Polysilicon and silicon nitride films are deposited in hot-waU furnaces. TiN diffusion barrier films are deposited by either sputtering or CVD, the latter giving superior step coverage. 6. E t c h i n g - m e t a l and oxide etch e q u i p m e n t are used to r e m o v e excess parts of the deposited film. High density plasma sources
328
provide a m or e etch in g .
rapid removal of material
and p r o d u c e
cleaner
7. Resist s t r i p p i n g - Both wet and dry removal p r o c e s s e s are u s e d at this step
in processing.
Dry ashing removes
the
b u l k of t h e
p h o t o r e s i s t and wet s t r i p p i n g removes r e m a i n i n g resi dues. 8. W.afer cleaning- wafers are cleaned in a u t o m a t e d wet b e n c h e s using the RCA wet clean m e t h o d (which uses a c o m b i n a t i o n of dilute acids, peroxide and bases in a particular order). E n v i r o n m e n t a l c o n c e r n s has p r o m p t e d the search for a new m e t h o d of cleaning. 9. Th er mal p r o c e s s i n g - Diffusion furnaces are u s e d not only for t h e anneal of i m p l a n t e d d o p a n t s but for growing high quality t h e r m a l oxides,
depositing polysilicon nitride
films (SiN x) and for r a p i d
t h e r m a l p r o c e s s i n g of deposited films. I0. M e t r o l o g y - The goal of m o s t metrology m a c h i n e efforts is to keep
the
pr oc e s s
measurements
under
of physical
control, size
whether
it
involves
of individual features
making and
film
thickness, or m a k i n g electrical m e a s u r e m e n t s of p a r a m e t r i c t e s t s t r u c t u r e s . Defects are also m e a s u r e d and estimated, i n c l u d i n g excess particles and m i s p l a c e d features in the c o m p o s i t e . Let us now discuss in more fabricate IC's. These include:
detail several of the operat i ons
u s e d to
G. Film.. Deposition. Several kinds of thin films are deposited on a silicon wafer by different m e t h o d s (see above) dur i ng various stages of the fabrication process. T h e initial step following cleaning is the formation of a silicon dioxide film. This film is grown by placing the silicon wafer in an oxidizing e n v i r o n m e n t at high t e m p e r a t u r e as, for example, in a quartz-walled furnace tube. This operation m a y be followed by the deposition of a film of silicon nitride. Later in the fabrication process, m et al (e.g.- t u n g s t e n
329
metal) a n d dielectric (e.g.- glass) films are deposited by m e a n s of sputtering. In this technique, a cathode m a d e of the material to be deposited is b o m b a r d e d with electrons, resulting in the ejection of a t o m s and molecules f r om the cathode. This material is deposited on the wafer surface an d forms the desired film. Metal and polysilicon films are formed by a chemical-vapor d e p o s i t i o n process using organometallic gases t h a t react at the surface of the IC s t r u ctu r e. Various metal silicide films m a y also be deposited in this m a n n e r by reaction with the surface of the silicon wafer to form m e t a l silicides. Glass and polymer films are deposited or spin cast or both, as are p h o t o r e s i s t films (those of a photosensft_ive material). T h i s process is a c c o m p l i s h e d by applying a liquid polymer onto a rapidly rotating wafer. The exact m e t h o d u s e d varies from m a n u f a c t u r e r to m a n u f a c t u r e r and usually r e m a i n s p r o p r i e t a r y . H. I m o u ~ W Doping, Selected imp u ri t i e s (e.g.- bor on a n d p h o s p h o r u s ) a r e i n t r o d u c e d into t h e silicon s u b s t r a t e to control its conductivity in a selective m a n n e r . This is a c c o m p l i s h e d by the c o m b i n a t i o n of two m e t h o d s : ion i m p l a n t a t i o n and t h e r m a l diffusion. In the ion i m p l a n t a t i o n process, the silicon wafer is exposed to a b e a m of energetic particles (i.e.- ions accelerated t h r o u g h a potential of several h u n d r e d kilovolts) of the s u b s t a n c e s t h a t are to be i n c o r p o r a t e d into the silicon. These i m pu ri t i es are driven into the silicon wafer via kinetic energy to a d e p t h ranging from a few h u n d r e d a n g s t r o m s to several m i c r o m e t e r s , d e p e n d i n g on the energy a n d the m a s s of the ions in the beam. The wafer is a n n e a l e d after i m p l a n t a t i o n of the i m p u r i t y ions in order to remove damage c a u s e d dur ing the ion i m p l a n t a t i o n p r o c e s s and to diffuse the impurities to the desired positions in the silicon wafer. I. Lithograohic p a t t e r n i n g . The p r o ces s of lithographic p a t t e r n i n g d e t e r m i n e s the geometric features specified by the layout a n d p a t t e r n i n g as the i n t e g r a t e d circuit is fabricated layer by layer. A p h o t o m a s k , containing p a t t e r n information in
330
the form of an e t c he d c h r o m i u m layer on glass, is p r e p a r e d for each layer. Note t h a t a specific p h o t o m a s k is r equi r e d for each layer of the IC. Thus, m a n y differing p h o t o m a s k s are r e qui r ed for the overall p r o c e s s to p r o d u c e all of the layers c o m p r i s i n g individual c o m p o n e n t s .
the
integrated
circuit
and t h e
An image of the p h o t o m a s k is projected onto the surface of the silicon wafer. This is a c c o m p l i s h e d with a very high-precision optical p r o j e c t i o n p r i n t e r after the wafer has been coated with a thin layer of photoresist. A positive p h o t o r e s i s t is a material w hi ch is m o n o m e r i c to begin with and which is cau s ed to polymerize w h e n a light b e a m from the p h o t o m a s k strikes selected por t i ons of the p h o t o r e s i s t so as to becom e insoluble in either water or a selected solvent. There are b o t h positive a n d negative p h o t o r e s i s t s , so-called because the major portion of the p h o t o r e s i s t is c a u s e d to become either insoluble or soluble by the action of bei ng exposed to selected wavelengths of light. The light is focused down to a point. Thus, to p r o d u c e a 18 m i c r o n line in the photoresist, the focus c a n n o t exceed this value. At this point in time, the focus has a p p r o a c h e d the focal-limit of the natural wavelength of visible light and even ultraviolet light c a n n o t be focused beyond a certain point. Thus, x-ray sources are being developed to p r o d u c e the 0.13 m i c r o n lines r e q u i r e d in advanced IC circuits. We will not fully explore the chemical n a t u r e of t h e p h o t o r e s i s t s r equi r e d in this technology except to say t h a t c o n s i d e r a b l e effort has gone into their d e v e l o p m e n t . The exposure is done one die at a time, st eppi ng from each die to t h e next to complete the exposure of the wafer. So-called "steppers" are an i m p o r t a n t part of the overall process for m a k i n g IC circuits on a silicon wafer. The resist containing the p a t t e r n image is developed (usually by exposure to light), and the exposed photosensitive material is removed by w a t e r - w a s h i n g from the areas t h a t have not been exposed to light (in t h e case of a positive photoresist). The desired p a t t e r n is thereby t r a n s f e r r e d from the p h o t o m a s k to the p h o t o r e s i s t on the surface of the partially fabricated IC. This p h o t o r e s i s t p a t t e r n serves to define the areas of t h e wafer where, d u r i n g a s u b s e q u e n t process step, film is to be d e p o s i t e d , i.e.- in a via (passage), material is to be removed by etching, or i m p u r i t i e s
331
are to be introduced. Once the selective deposition or removal of material has been accomplished, the remaining photoresist is cleared off t h e wafer. J. Etching. During this process, material is selectively removed from the wafer surface as defined by the p a t t e r n e d photoresist in order to define t h e structure of the previously deposited layer. The etching process is accomplished by exposing the wafer to a gas plasma, which both chemically reacts with the material to be removed and physically ablates it. At the completion of etching, the remaining photoresist is cleared from the wafer. K. A Final ~ k
at the IC Man llfacturing Process
Although the basic fabrication process of an CMOS circuit has b e e n illustrated above for the process used in 1997, the exact materials and sequence of steps has changed considerably in j u s t two years. T h e following illustrates how the process steps described above have b e e n modified. The details of the components used in manufacturing an CMOS circuit, having a line width of 0.18 ~m, is shown in the following diagram~ given as 6.17.7. on the next page. Contrast this diagram to 6.17.5. In this case, we have shown a n u m b e r of layers comprising the CMOS device and have n u m b e r e d some of the layers. At "1", the m e t a l interconnects are shown. These are composed of t u n g s t e n or c o p p e r metal and are either evaporated or applied by electrolysis in an inert gas atmosphere. The use of "damascene" has decreased b u t is still used for some types of DRAM's. The use of "diffusion barriers" continues, connecting the Cu metal to the active semi-conductors. Inter-level dielectrics being used are fluorocarbon polymers and low-k glasses, both in the form of spin-on suspensions. Siloxane glasses (which are a form of silico-organic materlals) are also in use. For purely electrical "connects ~, t u n g s t e n is still used since its tendency to diffuse through the dielectric layers is almost nil.
332
If a diffusion barrier is required, t h e n a t i t a n i u m l n i t r i d e (Ti/TiN) is used. This c o u n t e r a c t s the t e n d e n c y of m o s t met al s to diffuse t h r o u g h a given structure, particularly if the layers are c o m p o s e d of several different types of metals, c o n n e c t i o n s . After the p h o t o r e s i s t has been developed and the isolation o x i d e / n i t r i d e m a s k defined by etching, the wafer is i o n - i m p l a n t e d to electrically isolate the areas where the MOSFETs are to be formed, and oxide is grown over the i m p l a n t e d regions. The o x i d e / n i t r i d e film is t h e n removed, and a t h i n gate oxide is regrown in these regions, which are the sites for the MOS transistors. Polysilicon m ay be deposited and p a t t e r n e d in the n e x t p h o t o l i t h o g r a p h y p r o c e s s using a second p h o t o m a s k to define the gate s t r u c t u r e of the NMOS transistors. A s u b s e q u e n t i o n - i m p l a n t a t i o n p r o c e s s i n t r o d u c e s the r e q u i r e d i m pur i t i es into the s o u r c e / d r a i n regions of t h e
333
MOSFET's, and silicon oxide is deposited. The s o u r c e / d r a i n p o s i t i o n s where electrical cont act is to be m a d e to the MOSFET's are defined, using the oxide-removal m a s k and an etch process. For shallow t r e n c h isolation, anisotropic mechanical
silicon etch, t h e r m a l oxidation, oxide fill and c h e m i c a l leveling are the processes employed. For shallow
s o u r c e / d r a i n s formation, ion i m p l a n t a t i o n t e c h n i q u e s are still be used. For raised s o u r c e / d r a i n s (as s h o w n in the above diagram) cobalt silicide is being u s e d in st e a d of Ti/TiN
silicides.
Cobalt metal is deposited
and
reacted by a rapid t h e r m a l t r e a t m e n t to form the silicide. Capacitors w e r e m a d e in 1997 from various oxides and nitrides. The
use of t a n t a l u m
pentoxide in 1999 has proven superior. P l a t i n u m is u s e d as the plate material. Metal is t h e n deposited into the o p e n e d vias (openings) in the oxide layer and over its surface. During the s u b s e q u e n t p h o t o l i t h o g r a p h y process, it is p a t t e r n e d to form the desired electrical i n t e r c o n n e c t i o n s . These two steps are r e p e a t e d for each s u c c e e d i n g level to p r o d u c e additional levels of i n t e r c o n n e c t i o n s .
Finally, a protective
overcoat of o x i d e / n i t r i d e
is
applied (passivation), and vias are opened so t hat the wires c o n n e c t i n g the IC chip to its carrier package can be b o n d e d to o u t p u t pads. The m o s t i m p o r t a n t p a r t of the overall p r o c e s s for building or layering an i n t e g r a t e d circuit involves the use of dielectrics to isolate the electrically c o n d u c t i n g t r a n s i s t o r s built into the s t r u ct ure. Diagram 6.17.8., given on the next page, shows how these insulating layers are used. Here, it is easy to see the various layers a n d steps n e c e s s a r y to form t h e IC. We have already e m p h a s i z e d the formation of the n- and p-wells and the individual process steps n e e d e d for their formation. Note t h a t an epitaxial layer is u s e d in the above model. There are isolation b a r r i e r s p r e s e n t wh ich we have already discussed. However, once the polysilicon gate t r a n s i s t o r s are formed, t h e n m et al i n t e r c o n n e c t s m u s t t h e n be placed in p r o p e r position with p r o p e r electrical isolation. This is t h e function of the dielectric layers p u t into place as succeedi ng layers on t h e IC dice. Once this is done, t h e n the wafer is t e s t e d .
334
The a s s e m b l y p r o c e s s b e g i n s with an electrical test of the ICs die by die on e a c h wafer prior
to s e p a r a t i o n .
This
locates
and enumerates
n u m b e r a n d location of the good units. The wafer is t h e n
the
sawed into
individual dies, a n d e a c h good u n i t is installed in a plastic or c e r a m i c p a c k a g e by a t t a c h i n g the die to a lead frame a n d s o l d e r i n g wires b e t w e e n the o u t p u t p a d s on the die a n d the i n t e r n a l leads of the package. A final test is p e r f o r m e d on the p a c k a g e d die to d e t e r m i n e
whether
the u n i t
o p e r a t e s w i t h i n the specified s t a n d a r d s . The following diagram, s h o w n as 6.17.9. on the n e x t page, s h o w s an IC chip m o u n t e d u p o n a circuit board, with a t t e n d a n t r e s i s t o r s , c o n d e n s e r s
335
a n d solder 'l)umps" (the b l a c k spots). The i n t e r c o n n e c t i o n s
(shown as
b l a c k lines on the diagram) are usually copper. T h e y are also f o r m e d by a p h o t o - m i c r o - l i t h o g r a p h i c p r o c e s s similar to the l i t h o g r a p h y p r o c e s s u s e d in m a n u f a c t u r i n g IC circuits. Here, the lines are in mils, i.e.- t h o u s a n d s of an inch, r a t h e r t h a n in m i c r o n s ,
i.e.- millions of a m e t e r .
Note t h a t a
n u m b e r of c o n n e c t i o n s are h i d d e n w i t h i n the device m o u n t i n g a n d c a n n o t
336
be seen directly. L. Crystal Growth and Crystal Defects Affecting IC's Under conventional crystal growth conditions of silicon boules, vacancies agglomerate to form small, low-density octahedral voicls, commonly called "D-defects", i . e . - d i s l o c a t i o n defects. Interstitials can form distributed dislocation clusters. Both have serious effects upon the process of forming integrated circuits. The void defects have been clearly associated with dielectric breakdown failures in integrated circuits, while the dislocation defects have been associated with controlling the rate of the electrical defect producing reactions due to integrating the m a n a g e m e n t of defects throughout the entire growth process. In other words, the dislocation defects t e n d to cause the formation of defects in the integrated circuit at the point of the dislocation defect. Additionally, such a defect may not appear until the IC is being operated. Such defects are known to be related to certain classes of leakage current. The void defects have recently become a particular concern throughout the industry in spite of their extremely low density. In the growth of the single-crystal silicon, the crystal boule is pulled from the melt and is allowed to cool as it is being pulled. By annealing the upper part of the boule and finally subjecting it to a controlled cooling rate, this "zone engineering" ensures that the reactions that p r o d u c e either the void or dislocation cluster defect are completely s u p p r e s s e d . The result is crystals that are completely free of both void (vacancies in our terminology) and dislocation cluster defects. Eliminating one or the other can be readily achieved. Crystals have been made that are completely free of both classes of defects and have earned this material the n a m e "perfect silicon,". At present, defect-flee silicon crystals have been achieved at only at diameters of 200 mm. Comparisons of crystal quality were m a d e among three techniques: a typical conventional Czrochralski crystal g r o w t h technique, a slow-cooled controlled reaction and the "perfect silicon" process. The quality levels achieved in D-defect levels of the material is
337
mirrored in the gate oxide integrity of these materials. This technique is extendible to 300 m m growth where the propagation of in-grown defects is a major challenge. Engineering work on newly developed 300 m m crystal pulling systems has already begun and is e x p e c t e d to be complete in 2003. As device geometries s h r i n k and active gate areas increase, the probability of one of these defects occurring in a sensitive area increases. This can result in a crystal-related device yield limiting factor that can become critical in certain advanced IC structures. Thus various processes that reduce the density of these void defects are being developed to improve yield potential. This has been achieved primarily by controlling the crystal cooling rate through certain important t e m p e r a t u r e ranges that have the effect of controlling the defect g e n e r ating reaction. The effect is fewer, but not zero, voids. *Blow-cool" silicon is a c o m m o n expression used for this general type of approach to the problem. But as device generations progress, it is less clear that such an approach will be successful in producing sufficiently low void densities to produce acceptably profitable yields. Epitaydal silicon provides an alternative but is problematic in certain cost sensitive applications, particularly DRAMs. 6.18.- Future Methods for Manufacture of Integrated Circuits At this point, we have described how integrated circuits have b e e n designed and manufactured. At the dawn of the DIGITAL AGE (which we as a society have already entered), Gordon Moore (who founded Intel Corporation which m a n u f a c t u r e s nearly a~ of the chips used in computers) predicted that the n u m b e r of transistors on an i n t e g r a t e d circuit, and hence its speed, would double every 18 months. He has b e e n accurate and this has become known as "Moore's Law". Since 1965, this law has been the guiding light of the Semi-conductor Industry and has been good for the Industry as well as the c o n s u m e r since c o m p u t e r s have dropped drastically in price while rising dramatically in speed of computing, i.e.- rate of handling bytes. Speed is m e a s u r e d now in megabytes per second w h e r e a s in 1965, it was in t e r m s of kilobytes p e r
338
second. However, Moore's Law will soon collide w i t h a m u c h less flexible set of laws, t h o s e of t h e laws of physics. By 2004, the optical l i t h o g r a p h y u s e d to m a k e i n t e g r a t e d
c i r c u i t s will r e a c h its limits b e c a u s e of t h e
diffraction limit of visible light.
Although we
have d e s c r i b e d
current
d i m e n s i o n s in t e r m s of 0 . 1 8 V, lines less t h a n 0 . 1 0 V will not be possible. However,
t h e solution s e e m s
to be t h a t e i t h e r very s h o r t w a v e l e n g t h
ultraviolet will be u s e d or t h a t a b e a m of e l e c t r o n s will be e m p l o y e d to etch the silicon circuits in a wafer. Both m e t h o d s will e m p l o y a m u c h different a p p r o a c h to t h e s a m e p r o b l e m . For far-UV at 193 n m . , q u a r t z optics c a n be used. However, t h e c a p a c i t y for finer lines is n o t as g r e a t as for 157 nrn. Light s o u r c e s for t h e s e w a v e l e n g t h s do exist b u t the optics r e q u i r e d involve CaF 2. T h i s m a t e r i a l is not stable in air a n d is a t t a c k e d by w a t e r vapor. One solution for t h i s optical p r o b l e m h a s b e e n found to be the u s e of reflecting m i r r o r s . T h e following d i a g r a m s h o w s a c o n v e n t i o n a l s y s t e m for l i t h o g r a p h y :
339
Here, we s h o w n a "conventional" system. It c o n s i s t s of a light source, an etched, t r a n s p a r e n t circuit d i a g r a m a n d a lens to focus the p a t t e r n u p o n the wafer w h i c h h a s a p h o t o r e s i s t layer. Upon e x p o s u r e , the u n e x p o s e d p a r t of the p h o t o r e s i s t is w a s h e d off. S o m e t i m e s , the e x p o s e d area is removed, d e p e n d i n g u p o n w e a t h e r the p h o t o r e s i s t is positive or negative. C o n t r a s t this simple s y s t e m w i t h a m e t h o d u n d e r d e v e l o p m e n t is t h e "Extreme Ultraviolet (EUV) s y s t e m , u s i n g r a d i a t i o n from excited Xe gas, i.e.- 157 rim. The EI_W s y s t e m is s h o w n in the following:
It h a s similar c h a r a c t e r i s t i c s to the above s y s t e m s s h o w n in 6.17.2. a n d 6.18.1. But, ff the EUV m e t h o d is successful, it will r e q u i r e a n e a r v a c u u m since oxygen a n d w a t e r vapor strongly absorb 157 n m radiation. 6.19.- P u s h i n g the Um~its of S e m i - C o n d u c t o r T e c h n o l o g y For the p a s t 30 years, the s e m i c o n d u c t o r i n d u s t r y h a s followed M o o r e ' s law, w h i c h s t a t e s t h a t t r a n s i s t o r p e r f o r m a n c e a n d d e n s i t y double every 3 years {1). Although n o t truly a law, G o r d o n Moore's s t a t e m e n t h a s yet to be violated. But n o w it s e e m s to be in serious danger. F u n d a m e n t a l t h e r m o d y n a m i c limits are b e i n g r e a c h e d in critical areas, a n d u n l e s s new,
340
innovative solutions are found, the c u r r e n t rate of i m p r o v e m e n t c a n n o t b e m a i n t a i n e d . The d o m i n a n t electronic device u s e d today in i n t e g r a t e d circuits is the silicon-based metal oxide s e m i c o n d u c t o r (MOS) t r a n s i s t o r , which consists of a source, drain, channel, and gate region (see t h e figures given above). The source region provides a supply of mobile c h a r g e carriers, enabling c u r r e n t to flow from the source to the drain w h e n t h e t r a n s i s t o r is t u r n e d "on". The source and drain regions are electrically isolated from one a n o t h e r by an oppositely charged channel region. A controlling gate e l e c t r ode is s e p a r a t e d from the c h a n n e l by an insulating oxide material. By applying a voltage across the insulating material, an electric field is created. If the applied voltage repels the c h a n n e l c h a r g e and attracts the source and drain charge, a c o n d u c t i n g layer is f o r m e d , and c u r r e n t can flow from the source to the drain. In contrast, if t h e applied voltage attracts the c h a n n e l charge and repels the source and drain charge, no c o n d u c t i n g layer between the source and drain can form, and the t r a n s i s t o r is "off"' The t r a n s i s t o r t h u s acts as a digital switch t h a t is t u r n e d on or off by applying a voltage to the gate. Individual s w i t c h e s are c o m b i n e d to form the building blocks for m i c r o p r o c e s s o r a n d m e m o r y chips. For more t h a n 30 years, the switching speed of the MOS t r a n s i s t o r has been i n c r e a s e d by r e d u c i n g the size of the device. For proper operat i on, MOS t r a n s i s t o r scaling theory (i.e.- size r e q u i r e m e n t s ) requires all vertical and lateral d i m e n s i o n s to be scaled simultaneously (2). At t h e s a m e time, the total a m o u n t of charge in the source, drain, and c h a n n e l regions m u s t not decrease in order to m a i n t a i n low device r e s i s t a n c e . Charge in the source, drain, and c h a n n e l regions is c r e a t e d by locally adding d o p a n t atoms to the silicon lattice. In silicon, each silicon a t o m is covalently b o n d e d to the four n e a r e s t neighbors in the lattice. Adding a d o p a n t ato m concentration three valence silicon atom;
with five valence electrons increases the mobile c h a r g e by donat i ng an u n b o u n d electron. A d o p a n t a t o m with only electrons needs to accept an extra electron to s u b s t i t u t e a the localized t r a p p i n g of the extra electron effectively
creates a positive free charge referred to as a "hole." T r a n s i s t o r scaling requires an increase in the c o n c e n t r a t i o n of these donor and a c c e p t o r a t oms to m a i n t a i n a c o n s t a n t total charge in the source and drain regions.
341
The d o p a n t c o n c e n t r a t i o n s in MOS t r a n s i s t o r s have i n c r e a s e d m o r e t h a n 100-fold over the p a s t 20 years a n d are on the order of 1% of the silicon lattice density for c u r r e n t device technologies. The maximum t h e r m o d y n a m i c a l l y stable c o n c e n t r a t i o n
of a t o m s in silicon,
or
solid
solubility, varies for different d o p a n t atoms. It is a f u n d a m e n t a l t h e r m o dynamic p r o p e r t y a nd is not d e p e n d e n t on the m e t h o d of i n c o r p o r a t i o n of the d o p a n t atoms. Above the solid solubility limit, the d o p a n t a t o m s begin to interact with each o t h e r as a r e s u l t of e l e c t r o c h e m i c a l i n t e r a c t i o n s and the strain fields c a u s e d by the atomic size m i s m a t c h of the d o p a n t a t o m s a nd the silicon lattice. This leads to the formation of clusters of dopmnt atoms, wh ich are not located on silicon lattice sites a n d do not i n c r e a s e the mobile charge density (3). Unfortunately, the charge c o n c e n t r a t i o n s n e e d e d for c u r r e n t process technologies are at the solid solubility limit for the d o p a n t a t o m s c u r r e n t l y in use. New d o p a n t at om s have b e e n evaluated, b u t none have yet been found to create higher c o n c e n t r a t i o n s of mobile charge. Thus, unl e s s new m e t h o d s are developed, future scaling of the
t r a n s i s t o r will result
in
a loss of total charge,
an increase
in
resistance, and a potential decrease in p e r f o r m a n c e . Scaling of the gate oxide insulating material is facing an equally critical f u n d a m e n t a l limit. The gate oxide-silicon s y s t e m can be t h o u g h t of as a parallel plate capacitor. By applying a voltage on the gate e l e c t r o d e c h a r g e is a t t r a c t e d or repelled at the silicon interface. T h i n n i n g the insulating oxide material increases the
electric
field
and resul t s in a s t r o n g e r
coulombic force, which increases' the charge density in the silicon and leads to lowered r e s i s t a n c e a nd improved device c h a r a c t e r i s t i c s . However, increasing the electric field in the insulating oxide can cause the material to b r e a k down, resulting in device failure. For previous technology generations, this has d e t e r m i n e d the m i n i m u m oxide t h i c k ness t h a t could be used. As supply voltages are scaled with each generation, the oxide t h i c k n e s s has been scaled to m a i n t a i n the s a m e m a x i m u m electric field. However, within the last few technology g e n e r a t i o n s , a new f u n d a m e n t a l limit to t h e scaling of the insulating oxide has emerged. The oxide layer has b e c o m e so thin t h a t q u a n t u m m e c h a n i c a l t u n n e l i n g of electrons f r o m the silicon
342
s u b s t r a t e to the gate electrode is now possible (4). The probability of an electron t u n n e l i n g t h r o u g h a potential barrier d e p e n d s exponentially on the t h i c k n e s s and potential energy of the barrier. State-of-the-art gate oxide t h i c k n e s s e s are c u r r e n t l y between 1.5 and 2.0 n m (5). T hi s r e p r e s e n t s 3 to 4 atomic layers of oxide. At these dimensions, c u r r e n t flow t h r o u g h the gate oxide as a result of electron t u n n e l i n g b e c o m e s substantial. The t u n n e l i n g process does not appear to damage the oxide, but the resulting gate leakage can close circuit failures b e c a u s e circuit designs a s s u m e no appreciable gate current. Even ff circuit t e c h n i q u e s can be designed to deal with the leakage, the a m o u n t of power c o n s u m e d will b eco me unacceptably large. If the insulating gate dielectric c a n n o t be scaled, MOS device p e r f o r m a n c e will be severely degraded. Scaling of the gate dielectric is r eq u ir ed not only for the capacitive coupling of the gate to the c h a n n e l t hat decreases device resistance; it is also critical for scaling t h e t r a n s i s t o r length. I nc r eas e d coupling of the gate to the c h a n n e l allows a higher doping density to be u s e d in the c h a n n e l while m a i n t a i n i n g a low r e s i s t a n c e w h e n the t r a n s i s t o r is switched into the c o n d u c t i n g state. T hi s increase in the c h a n n e l doping density increases the c h a n n e l barrier, thereby improving the isolation between source and drain w h e n t h e t r a n s i s t o r is t u r n e d off. This p e r m i t s the lateral distance bet w een t h e source and drain regions to be scaled. Thus, d e c r e a s e d capacitive coupling and inability to scale lateral d i m e n s i o n s m a y result ff oxide t h i c k n e s s c a n n o t be scaled. Statistical fluctuation is also a potentially f u n d a m e n t a l limit for c o n t i n u e d t r a n s i s t o r scaling (6). The t h a t only about a h u n d r e d trical characteristics. As a distribution of the a t o m s
t r a n s i s t o r d i m e n s i o n s have become so small d o p a n t atoms are n e e d e d to control the elecresult, small c hanges in the exact n u m b e r and can cause appreciable c h a n g e s in the device
behavior. The statistical n a t u r e of the d o p a n t distribution is i n h e r e n t to the fabrication process a nd c a n n o t easily be changed. For very large i n t e g r a t e d circuits t h a t can use more t h a n 10 million transistors, this statistical variation can cause serious design problems. Unless ways for reducing statistical variation are found, it m a y not be possible to scale
343
dimensions to the point where characteristics.
tens of atoms d e t e r m i n e
the
device
Solutions for these problems have not yet been found (7). It has b e e n proposed that the semiconductor material m u s t be changed to continue transistor scaling. Alternate semiconductor materials such as GaAs and SiGe have been evaluated for more t h a n 20 years, but although t h e s e materials have found a niche for certain applications, neither has b e e n able to solve the problems of silicon without causing even more c o m p l e x problems. Alternate insulating materials for the gate dielectric are also u n d e r evaluation. By using an insulating material with a dielectric c o n s t a n t m u c h larger t h a n that of Si02, the t h i c k n e s s of the material can be increased while still increasing the capacitive coupling. The increase in thickness would strongly decrease the electron tunneling c u r r e n t and would permit continued scaling of the transistor. Unfortunately, no material with a substantially increased dielectric c o n s t a n t that is also compatible with MOS transistors has yet been found. A substantial effort is being m a d e to increase charge concentrations by creating dynamic equilibrium. Processes such as laser annealing and epitaxial growth have been proposed for creating ultrahigh mobile c h a r g e concentrations. Unfortunately, these carrier densities are fragile, and the metastable states are extremely difficult to maintain during processing of the device. These fundamental issues have not previously limited the scaling of transistors and r e p r e s e n t a considerable challenge for the s e m i c o n d u c t o r industry. There are currently no known solutions to these problems. To continue the performance trends of the past 20 years and maintain Moore's law of i m p r o v e m e n t will be the most difficult challenge t h e semiconductor industry has ever faced. 6.20.- The.Solar Cell In one way or the other, the Sun is responsible for most of the Earth's energy. Green plant (chlorophyll) photosynthesis has provided the basis of
344
conversion of light energy into coal and crude oil in past eons. Heat from the Sun is also responsible indirectly for other forms of energy used by Man. Examples are wave and wind power (Here, energy is converted into electrical c u r r e n t by use of generators that are rotated by either form of energy). Thus, solar power usage by Man has evolved into two distinct technologies: i) Direct use of the Sun's heat energy for supplying hot water for homes by special designs of rooftop units (Also known as Solar Thermal) 2) Photovoltaics,
defined
as the conversion of light energy into
electrical energy. It is the latter with which we will be concerned, a technology which has been touted as the answer to pollution abatement. Additionally, it has b e e n recognized that World crude oil supplies will dwindle to zero within t h e next 100 years, and that a suitable energy r e p l a c e m e n t will be r e q u i r e d . The Solar Energy industry traces its origin back about 150 years. Development of solar-cell technology stems from the work of the F r e n c h physicist Antoine-Cesar Becquerel in 1839. Becquerel discovered t h e photovoltaic effect while experimenting with a solid electrode in an electrolyte solution. He observed that voltage developed w h e n light tell upon the electrode. About 5 0 years later, Charles Fritts c o n s t r u c t e d t h e first true solar cell using junctions formed by coating the s e m i c o n d u c t o r , selenium, with an ultrathin, nearly t r a n s p a r e n t , layer of gold. Fritts' devices were very inefficient converters of energy as they t r a n s f o r m e d less t h a n 1% of the absorbed light-energy into electrical energy. T h o u g h inefficient by today's standards, these early solar cells fostered among some a view of abundant, clean power. In 1891, R. Appleyard wrote of "The blessed vision of the Sun, no longer pouring his energies u n r e q u i t e d into space, but by m e a n s of photoelectric cells which would cause t h e total extinction of s t e a m engines and smoke". ....... By 1927, another metal semiconductor junction solar-cell (In this case m a d e of copper and the semiconductor copper oxide), had b e e n
345
d e m o n s t r a t e d . By 1935, bot h the s e l e n i u m cell and the copper oxide cell were being employed in light-sensitive devices s u c h as p h o t o m e t e r s for use in photography. However, these early solar cells stiU had an e n e r g y conversion efficiency of less t h a n 1 percent. This i m p a s s e was finally overcome with the d e v e l o p m e n t 1941.
Thirteen
years later
of the silicon solar cell by Russell Ohl in
three
other
American
researchers,
G.L.
Pearson, Daryl Chapin, and Calvin Fuller, d e m o n s t r a t e d a silicon solar cell capable
of a 6%
energy-conversion
efficiency
when
used
in
direct
sunlight. By the late 1980's, silicon cells, as well as those m a d e of galliumarsenide, with efficiencies of m o r e t h a n 15% h a d been fabricated. In 1989, a c o n c e n t r a t o r solar-cell, a type of device in w hi ch sunlight is c o n c e n t r a t e d onto the cell surface by m e a n s of lenses achieved an efficiency of 37%, be c a us e of the i n c r e a s e d intensity of the c o l l e c t e d energy. In general, solar cells of widely varying efficiencies a n d cost are now available. At present, solar-energy voltaics are b a s e d u p o n m o n o c r y s t a n i n e silicon (Si) discs, similar to the i n t e g r a t e d - c i r c u i t industry. As a m a t t e r of fact, reject-discs from t h a t i n d u s t r y are u s e d to m a k e solar-cells w h e r e i n t h e discs are cleaned and the reject
IC circuits are removed
before
the
silicon-disc is p r o c e s s e d to m a k e a solar-cell. However, solar cells based on the III-V transition e l e m e n t s (such as GaAs alloys, where the valence state of the two m e t a l s is Ga 3+ and As 5+) can also be fabricated. But t hey are, at present,
too costly. Cost is a major c o n s i d e r a t i o n in solar-cell
technology since any electricity g e n e r a t e d by solar power m u s t be p r i c e d similar to the actual cost of us i ng coal or off to generate electrical p o w e r (what we call "electricity"). At present, solar-power electricity g e n e r a t e d from silicon discs costs approximately twice t h a t of coal- or off-based g en er atin g plants. (Factored into this is the cost of prevent i ng pollution from the g e n e r a t i n g plants). Since solar power is non-polluting, it has, potentially, a large advantage ff the actual energy efficiency can be rai sed from about 15% to higher values. Thus, the major factors t h a t m u s t be a d d r e s s e d by solar cell m a n u f a c t u r e r s are the efficiency and cost of conversion of light energy into electrical energy. Although other types of solar cells b a s e d u p o n transition e l e m e n t s s u c h as GaAs and the like exhibit higher efficiencies, the m u c h lower cost and availability of Si discs
346
m a k e it the m a t e r i a l of choice w h e n cost c o n s i d e r a t i o n s are t a k e n into account. A solar cell r e q u i r e s
a p-n junction
(positive
a n d negative)
which
is
activated w h e n p h o t o n s c o m e into c o n t a c t w i t h it. T h e p - n j u n c t i o n t h e n acts as a "diode" to g e n e r a t e a voltage a n d r e s u l t i n g electrical c u r r e n t . In solar cells b a s e d on crystalline silicon, the p - s t a t e is achieved by diffusing a trivalent ion s u c h as Ga 3+ into t e t r a v a l e n t silicon, Si 4+, while As 5+ c a n be u s e d to form the n-layer. C o n d u c t i o n in the p-layer involves t h e m o v e m e n t of "holes" t h r o u g h the electrically n e u t r a l silicon while t h e n - l a y e r c o n d u c t i v i t y involves e l e c t r o n s . Because Si 4+ h a s four b o n d s , it h a s a low conductivity
because
of
its
diamond-like
structure,
i.e.-
it
forms
t e t r a h e d r a l b o n d s t h r o u g h o u t the s t r u c t u r e . If a trivalent ion is diffused into the s t r u c t u r e , an electrical defect r e s u l t s in f o r m a t i o n of a "hole", i.e.lack of an electron. Likewise, t h e diffusion of a p e n t a v a l e n t ion r e s u l t s in an "extra" electron, r e s u l t i n g in a n-layer w i t h i n the b u l k of the silicon. A. C r y s t a l l i n e ~ ~ s t a l l i n e
a n d A m o r p h o u s Solar Cells
Solar cells b a s e d on crystalline silicon discs g e n e r a l l y have c o n v e r s i o n efficiencies
of about
15%,
or less,
depending
upon
the
manner
of
fabrication. The efficiency of silicon solar-cells is limited to about 2 0 % because
the
long-wave
emission,
i.e.-
near
infra-red
and
infra-red
radiation, from the S u n is not a b s o r b e d in the silicon m a t r i x , or is n o t a b s o r b e d in the silicon close e n o u g h to the p - n j u n c t i o n for the p h o t o g e n e r a t e d c h a r g e c a r r i e r s to be collected
by the j u n c t i o n . To d e c r e a s e
costs, s o m e m a n u f a c t u r e r s have t u r n e d to poly-crystalline silicon w h e r e melted
silicon is c a s t in a m o l d
correctly,
a large-grained
a n d cooled.
polycrystalline
If this is a c c o m p l i s h e d
silicon
results.
Another
less
obvious benefit results. The silicon c a n be c a s t in a s q u a r e m o l d a n d t h e resulting
square
discs will fit t o g e t h e r
more
tightly t h a t the
round
m o n o c r y s t a l l i n e discs, grown by the Czochralski c r y s t a l - p u l l i n g t e c h n i q u e . Efficiencies of about 16% have b e e n
achieved. A n o t h e r
i n n o v a t i o n has
b e e n the d e v e l o p m e n t of a m o r p h o u s , i.e.- glassy (not crystalline), silicon solar-cells. T h e s e are m a d e by e v a p o r a t i n g (or s p u t t e r i n g ) a thin-film of silicon u p o n a suitable s u b s t r a t e . Both p- a n d n-silicon c a n be e v a p o r a t e d
347
sequentially to form a suitable p - n j u n c t i o n . The advantage of t h i n - f i l m solar-cells lies in efficient u s e of silicon material. But, the d i s a d v a n t a g e lies in lower energy c o n v e r s i o n efficiency a n d m o s t a m o r p h o u s silicon solar cells only have a n efficiency of 11-12%. However, if the silicon is s u b j e c t e d to h y d r o g e n gas d u r i n g m a n u f a c t u r e , a h y d r o g e n a t e d film results, said to have i m p r o v e d efficiencies of u p to 16%. T h u s , t h r e e (3) types of silicon have b e e n u s e d to fabricate solar cells: m o n o c r y s t a l l i n e , polycrystalline a n d a m o r p h o u s films. Silicon solar-cells are fabricated u s i n g silicon discs in a m a n n e r similar to t h a t d e s c r i b e d previously for m a n u f a c t u r e of i n t e g r a t e d circuits. T h e basic external s t r u c t u r e u s e d in solar cells is s h o v m in the following diagram:
Several differences from t h a t of an i n t e g r a t e d circuit c a n be noted. First of all, two (2) electrical c o n t a c t s m u s t be e s t a b l i s h e d across the b u l k of t h e silicon wafer. %nnen light s t r i k e s the surface of the solar cell, its a b s o r p t i o n w i t h i n the silicon b u l k releases e l e c t r o n s w h i c h are c o l l e c t e d as a c u r r e n t . Also s h o w n is the p - n j u n c t i o n . However, the actual silicon disc is only about 3 5 0 vm. in t h i c k n e s s . Diffusion p r o c e s s e s are used, as a m a t t e r of practicality, to form b o t h the p-layer a n d the n-layer. T h u s , t h e
348
actual p h y s i c a l a n d electrical c o n f i g u r a t i o n is b e t t e r visualized as s h o w n in the following d i a g r a m :
Once the silicon disc is cleaned, the first step is diffuse ions into e i t h e r side of the silicon disc to first form e i t h e r the p-layer or the n-layer. S o m e m a n u f a c t u r e r s like to have the n-layer closer to the light source, as s h o w n in t h e above d i a g r a m , while o t h e r s prefer the opposite. At any r a t e , ions like B3+ a n d p5+ are generally u s e d to form the active electrical layers. A n u m b e r of differing p r o c e s s e s have b e e n developed to do this, t h e e x a c t n a t u r e of w h i c h d e p e n d i n g u p o n the specific m a n u f a c t u r e r of solar cells. Sputtering,
v a p o r - p h a s e a n d e v a p o r a t i o n are used. T h e
most
common
p r o c e s s u s e s a volatile b o r o n or p h o s p h o r o u s c o m p o u n d to c o n t a c t t h e surface. Obviously, the o t h e r side must be protected d u r i n g the p r o c e s s to f o r m one or the o t h e r active layer. Clearly, the silicon disc n e e d s to be h e a t e d as well d u r i n g the p r o c e s s to aid the diffusion p r o c e s s .
Note t h a t t h e
surface will be rich in diffusing species a n d t h a t t h e d e n s i t y of s p e c i e s declines w i t h i n t h e interior, forming a diffuse layer w h i c h is d e n s e n e a r t h e top a n d t h i n n e r in the i n t e r i o r of the silicon. W h a t h a p p e n s is t h a t
349
once t h e ion c o n t a c t s t h e silicon surface, it "hops" from site to site into the i n t e r i o r of the b u l k of t h e silicon m a t r i x . Since diffusion p r o c e s s e s are n o t o r i o u s l y slow, t h e e l e c t r i c a l - l a y e r s will be only a few m i c r o n s
(~M)
thick. The silicon disc is about 3 5 0 pM t h i c k so t h a t the b u l k of t h e silicon t h i c k n e s s is n o t electrically (but is optically) active. This h a s a beneficial effect on t h e solar-cell p e r f o r m a n c e since the t h i c k n e s s l a b e l e d "Absorber layer" is actually t h e p - n j u n c t i o n . The p h o t o n s s t r i k i n g t h e surface of t h e solar cell are a b s o r b e d w i t h i n t h e i n t e r i o r layer, having t r a v e r s e d t h e "anti-reflection" layer. The function of this layer is to t r a p the light falling u p o n t h e solar cell a n d to p r o m o t e the t r a n s m i s s i o n of p h o t o n s into t h e e n e r g y c o n v e r s i o n layers below. Materials s u c h a s silicon oxides a n d titanitu-n oxide are e m p l o y e d
as the a n t i - r e f l e c t i o n layer in
m o s t s i l i c o n - b a s e d solar cells. T h e t r i c k is to form an a n t i - r e f l e c t i o n layer w h o s e refractive i n d e x is e q u a l or j u s t slightly above t h e refractive i n d e x of the m a t r i x , h e r e the silicon disc. T h e b a s e c o n t a c t is a l m o s t always t h a t of a c o n d u c t i v e m e t a l like silver or a l u m i n u m . The top c o n t a c t is m a d e via m e t a l s t r i p e s or c o n t a c t fingers w h i c h are p a t t e r n e d a c r o s s the top of t h e silicon solar cell. A b u s b a r is u s e d to c o n n e c t all of t h e collection f i n g e r s to t h e electrical o u t p u t . T h e collection fingers allow m o s t of t h e surface a r e a of t h e disc to b e c o m e active. Only about 0.5% of t h e top surface is usually covered by the m e t a l stripes.
The
rear aluminum contact
also
serves as a highly reflective layer as well. In a c o n v e n t i o n a l solar cell b a s e d on a m o n o - c r y s t a U i n e disc, t h e s t r i p e s or c o n t a c t fingers are
screen-priated,
u s i n g a s i l v e r - b a s e d alloy, in a r e s i n -
b a s e d ink. ,after firing to r e m o v e t h e organic resin, t h e b u s b a r c o n t a c t s are s c r e e n - p r i n t e d
and
then
fired.
However,
some
of t h e
current-
g e n e r a t i n g surface is still s h a d e d b y t h e b u s b a r a n d a t t e n d a n t stripes. T h e m o s t r e c e n t i n n o v a t i o n h a s b e e n t h e u s e of a l a s e r to scribe t h e s e g r i d lines as grooves. T h e collection grid is t h u s b u r i e d in the surface of t h e disc,
reducing
cell
shading
and
making
possible
energy
conversion
efficiencies of u p to 18%. T h e top c o n d u c t o r is a l m o s t always in a g r i d - p a t t e r n to allow as m u c h a r e a as possible o p e n to c o n t a c t w i t h light p h o t o n s . Note t h a t m e t a l s are n o t light-transparent.
T h e b o t t o m c o n t a c t does n o t n e e d
to be p a t t e r n e d .
350
Hence the top grid p a t t e r n is usually widely spaced but not the extent t hat the electrical contact layer will have difficulty in collecting the c u r r e n t p r o d u c e d by the cell's ot her active layer. Clearly, the silicon disc n e e d s to be h e a t e d as well during the process to aid the diffusion process. Note t hat the surface will be rich in diffusing species and t h a t the density of species declines within the interior What h a p p e n s is t h a t once the ion c o n tacts the silicon surface, it "hops" from site to site into the interior of the b u lk of the silicon matrix. When different materials are placed in contact with another, an electrical field exists at the interface, or junction, between the materials. It is this fact t h a t allows the formation of an optical-diode s u c h as a solar ceil. T h e role of the n- and p-layers is to establish this built-in electrical field. T hi s field is n e e d e d since it dictates the direction of electrical current . W h e n light is absorbed within the absorber layer, free electrons result. In o t h e r words, specific Si a t o m s within the bul k layer are excited and e l e c t r o n s can move. The
absorption of light within the
interior
absorber layer
results in energetic free-electrons, causing a c u r r e n t w hi ch is collected by the c o n d u c t o r s for use in an external circuit to do useful work. Silicon is particularly advantageous since its absorption s p e c t r u m lies is st rong in the red an d near infrared portion of the Sun's s p e c t r u m , a region w h e r e m u c h of the Sun's energy lies. The latest innovation has been the use of "layered" solar-cells in w hi ch t h i n - t r a n s p a r e n t trims are t r a n s p o s e d u p o n the s ame substrate. The following shows the types of s e m i - c o n d u c t o r being used: 6.20.3Cell T y p e .
Spectral. Regio n
G e r m a n i u m , Ge
Near I n f r a r e d
Silicon, Si
Red or Near I n f r a r e d
Gallium Arsenide, GaAs
Orange and R e d
GaUimTi I n d i u m Phosphide, GaInP2
Green and Yellow
Gallium Nitride, GaN
Ultraviolet and Blue
or Gallium Phosphide, GaP Projected Efficiently
48.8%
351
In this Chart, the individual semi-conducting layers are p r e s e n t e d as well as the portion of the solar s p e c t r u m each one is supposed to absorb. Obviously, if each layer is not t r a n s p a r e n t , t h e n part of the Sun's energy is wasted. Thus, the 4 8 % efficient of such solar cells may not be achievable. Note that afire-layer solar-cell is proposed. However, c o s t - c o n s i d e r a t i o n s may m a k e this type of solar cell impractical since the cost of electricity will be too much. A three-layer type of solar-cell has been built which had an efficiency of about 39% (consisting of Si, GaAS and GaN). But until t h e price of other energy sources mount, or until the cost of gallium-based materials drops, a layered solar-ceU will not be economically feasible. B.-Thin Film Solar Cells We have already m e n t i o n e d a m o r p h o u s silicon solar cells. New p r o c e s s e s have been developed to m a n u f a c t u r e solar cells based upon deposition of very thin films of photosensitive materials. Such processes have a distinct cost advantage since once t h e films are deposited, little f u r t h e r processing is needed to form the final solar cell module. Amorphous silicon is the only thin film process used for m a s s p r o d u c t i o n of solar ceils. Initially, such cells possessed very low efficiencies of less t h a n 10%, due to their i n h e r e n t degradation problems. To overcome this deficiency, extra layers have been added. In some cases, a triple junction is formed to increase the internal electrical field and hence the collection efficiency. Additionally, extra layers w h i c h capture light at o t h e r wavelengths because of change in their bandgap energy have b e e n employed. All of this increases costs but improves conversion efficiency. As m e n t i o n e d above, one of these modifications has included formation of the silicon hydride, S i H x , which has a slightly modified absorption spectrum. A prime c o n t e n d e r for leading thin Fflrn technology as applied to solar cells is c a d m i u m telluride {CdTe). Its bandgap is almost ideal for use as a solar cell for energy conversion from the Sun's spectrum. Here, CdTe and c a d m i u m sulfide (CdS) are used to produce a low cost thin film solar cell
352
without the i n h e r e n t stability and degradation problems of a m o r p h o u s silicon. The process uses electrodeposition upon a substrate like glass. Obviously, a conductive coating like tin oxide is needed. Efficiencies over 25% are c o m m o n for the CdTe solar cell. In 1998, a full scale p r o d u c t i o n effort was started by British Petroleum Corp., using their "Apollo" process. 6.2 I.- Piezo-Electric Materials and T h e i r Uses Piezoelectricity involves the creation of an electric charge (or voltage) by applying p r e s s u r e to a material. Discovered by Pierre and J a c q u e s Curie in 1880, this p h e n o m e n o n occurs in m a n y non-metallic crystals with noncentrosymetric crystal s t r u c t u r e s and some degree of ionic bonding. Upon the application of stress, a polarization charge (P) per unit area is c r e a t e d which equals do, where o is an applied stress and d is the piezoelectric modulus. The constant, d, which defines piezoelectric behavior, is a t h i r d r a n k tensor (which m e a n s that the applied force generates voltage in varying degrees, depending upon the direction in the piezoelectric crystal structure).. Thus, piezoelectric behavior is highly d e p e n d e n t on the direction(s) along which a crystal is stressed. For example, in a quartz crystal, s t r e s s i n g along the [100] direction will cause polarization (a voltage), while stressing along the [001] will not. While some single crystal ceramics, such as quartz, are still used in piezoelectric devices, the emergence of polycrystalline barium titanates (BaTI03) in the 1940s, and lead zirconate titanates (PbZrTi03), known as PZT, in the 1950s, led to most m o d e r n applications of piezoceramics. Both materials (and modifications of t h e m ) have high values of d, and thus can create a relatively large voltage for a given Stress m called a d i r e c t piezoelectric effect. Alternatively, t h e materials produce a "large" strain if an electric field is applied--called a c o n - v e r s e piezoelectric effect. For polycrystaUine piezoceramics to work, the electrically charged dipoles within the entire piezoelectric c o m p o n e n t m u s t be aligned by placing t h e piezoceramic within a high electric field--a process known as poling. T h e ability of piezoceramics to almost instantaneously convert electrical
353
c u r r a n t to m e c h a n i c a l d i s p l a c e m e n t a n d vice v e r s a m a k e s t h e m useful t r a n s d u c e r s . The efficiency of conversion b e t w e e n m e c h a n i c a l and electrical energy (or the converse) is m e a s u r e d by a p a r a m e t e r called t h e coupling coefficient. PZT b a s e d materials are widely u s e d b e c a u s e of t h e i r high coupling coefficients. I. Applications Sonar: The use of piezoceramics (converse mode) to g e n e r a t e a pulsed under~vater acoustic wave and t h e n receive a reflect(~l e c h o (direct m o d e ) - - s o n a r - - w a s the first practical application of piezoelectrics. By the end of World War I, F r e n c h engineers could m e a s u r e the d e p t h of s u b m e r g e d objects using quartz t r a n s d u c e r s . C o n t e m p o r a r y s o n a r devices generally have a pulse emitter of PZT b a s e d material o p t i m i z e d for g e n e r a t i n g strong pulses. The "receiver" consists of arrays of h y d r o p h o n e s will ceramic compositions optimized to p r o d u c e t h e m a x i m u m electrical signal from a minimal echo. Modern h y d r o p h o n e t r a n s d u c e r s are composite s t r u c t u r e s with piezoceramic rods m o u n t e d in a polymer. This e n h a n c e s the o u t p u t voltage per unit u n d e r p r e s s u r e . Key to these systems are very sophisticated electronics t h a t can s e p a r a t e physical a n d i n s t r u m e n t a l noise from the actual r e t u r n e d signal. Medical Ultrasound: Many of us have first seen our u n b o r n c h i l d r e n or g r a n d c h i l d r e n t h a n k s to medical u l t r a s o u n d technology. This application is s o m e w h a t related to sonar in t h a t both use pulse e c h o m e t h o d s to send a n d receive signals. However, in this s h o r t - r a n g e application, t r a n s d u c e r arrays can be designed to form images. Micropositioning a n d M i c r o - m o t o r s . The converse p i e z o e l e c t r i c effect p r o d u c e s solid state motion. Piezoceramics are u s e d as actuators in m a n y micro-positioning applications, s u c h as fiber optic alignment, m i r r o r tilting for optical c o m m u n i c a t i o n a n d imaging, wafer m a s k alignment in the s e m i - c o n d u c t o r industry, a n d hydraulic servo valves. In exceptional cases, positioning can be controlled to a n a n o m e t e r or less. Piezoelectric . T r a n s f o r m e r s :
If a two-layer t r a n s d u c e r is designed so
354
that a low voltage applied to the first layer to produce a strain, a larger strain is imposed on the second layer. This causes the second layer to generate a higher voltage t h a n the one applied to the first layer. Thus, we have a step-up transformer. When operated at the a p p r o p r i a t e frequencies, voltage increases from 3 V to 1500 V are attainable. Such transformers (inverters) are used to power cold-cathode fluorescent lamps for notebook c o m p u t e r displays. Active noise and vibration damping: Noise and vibration are p r o d u c e d by waves pulsing through the air or through structural materials. Creating an "anti-wave" of the same frequency spectrum, but opposite in amplitude, will cancel out or at least decrease the objectionable noise or vibration. Piezoceramic t r a n s d u c e r s coupled with sophisticated signal detection and generation electronics are used for such d a m p i n g applications. Suggested Reading I. "The Growth of Single Crystals"- R.A. Laudise, Prentice-Hall, New York (1970). 2. "The Art and Science of Growing Crystals"- Ed. by J.J. Gilman, Wiley, New York (1963). 3. "Crystal Growth"- Ed. by S. Peiser, Pergamon, New York (I 967). 4. "Phase Diagrams-Materials Science & Technology"- Ed. by A.M. Alper, Academic Press, New York (1970). 5. "The Metal-Insulator Transition in Selected Zandt, Ann. Rev. Mat. Sci., 5 , 2 2 5 - 2 7 8 ( 197 5).
Oxides" - Honig & Van
R e f e r e n c e s on S i l i c o n D e v i c e s I. Gordon Moore, /EDM Tech. Dig. (1975), p. I I. 2. RH Denard et al, IEEE J. Solid-State Circuits SC-9 256 (I 9 7 4 ) 3. KS Jones, S Prussin & ER Weber, Appl. Phys., A45 1 (1.988)
355
4. J Maserjian & GP Peterson, Appl. Phys. Lett., 25 50 (I 9 7 4 ) 5. HS Momose et al,/E/~M 2"ech,/~g. (1994), p. 5 9 3 6. B Hoeneisen & CA Mead, Solid-State Electron., 15 819 ( 197 2) 7. S T h o m p s o n , P P a c k a n & M Bohr, Intel. Tech., Q3 1 ( 1 9 9 8 ) P r o b l e m s for Chapt.,er 6 I. From 6.2.1. "Elements of Furnace Design", p r e p a r e a drawing s h o w i n g how these
components
are c o n n e c t e d
together,
both
physically and
electrically, to form a furnace suitable for heat i ng a crucible containing a powder for solid state reaction in air, up to 1200 ~
Be sure to use t h e
right insulation, heat er and crucible. 2. Do the s ame for a furnace designed to heat a crucible in a r e d u c i n g a t m o s p h e r e , up to 1600 ~ 3. Design a furnace capable of m el t i ng AI203 in air; do the sam e for m e l t i n g YAG. Be sure to use the right crucible. 4. List the ways t h a t one can obtain a "seed" crystal. Is it possible to use one type of crystal-growth m e t h o d to obtain a seed crystal for Czochralski growth? 5. We wish to grow crystals of CaS and SrS, activated by 0.01 mol of Ce2S ~. These crystals will be u s e d to evaluate the l u m i n e s c e n t p r o c e s s e s w h i c h take place in the Ce ~+ activator center, particularly the polarized e m i s s i o n properties. Det e r m i ne which one (or more) crystal growing m e t h o d s is m o s t suitable for obtaining single crystals in this cubic system. Note t hat we wish to grow the crystal along the {1,1,1} plane since this is t h e direction of highest a t o m - d e n s i t y a nd will give the best crystals for our optical study. Note t h a t a trivalent cation is being situated u p o n a divalent lattice site. 6. MgO has a wide infra-red t r a n s m i s s i o n s p e c t r u m , s p a n n i n g 0.2 ~rn to 9.0 ~rn of usable range. Outline a crystal growing m e t h o d to obtain single crystal material suitable for this purpose. What m e t h o d s are not suitable?
356
7. Ti02 is a m a t e r i a l w h i c h Coatings
h a s f a r - r e a c h i n g u s e s as a UV m o d i f i e r .
on steel have b e e n s h o w n to inhibit bacterial g r o w t h a n d e v e n
kill b a c t e r i a on its surface. We w i s h to grow a single crystal in o r d e r to clarify a n d define this anti-bacterial action. Outline one or m o r e m e t h o d s for o b t a i n i n g a single crystal of TiO2. Since this action m a y be one of a defect-structure, obtaining
i.e.- oxygen vacancies, include at least one m e t h o d for
a controlled
defect
structure
of TiO2.x, w h e r e
x
can
be
controlled. 8. We w i s h to test a new type of c e r a m i c t u b e to the AI20s t u b e n o r m a l l y u s e d to fabricate h i g h - p r e s s u r e s o d i u m l a m p s in o r d e r to c o m p a r e l a m p qualities a n d life-time o p e r a t i o n . Select a m e t h o d w h i c h w o u l d p r o d u c e the d e s i r e d r e s u l t s a n d d e s c r i b e h o w this w o u l d be a c c o m p l i s h e d . N o t e t h a t the c e r a m i c t u b e r e q u i r e s b o t h s t r e n g t h a n d a high m e l t i n g p o i n t .
357
.......
Chapter 7
M e a s u r e m e n t of Solid State P h e n o m e n a W h e n solids react, we w o u l d like to k n o w at w h a t t e m p e r a t u r e the solid state reaction t a k e s place. If the solid d e c o m p o s e s to a different composition, or p h a s e , we would like to have this knowledge so t h a t we c a n predict a n d u s e t h a t knowledge in p r e p a r a t i o n of desired materials. Sometimes, i n t e r m e d i a t e c o m p o u n d s form before the final p h a s e . In this chapter, we will detail some of the m e a s u r e m e n t s u s e d to characterize the solid state a n d m e t h o d s u s e d to follow solid state reactions. This will consist of v a r i o u s t y p e s of t h e r m a l analysis (TA), including differential t h e r m a l analysis (DTA), t h e r m o g r a , ~ n e t r i c analysis (TGA) a n d m e a s u r e m e n t s of optical properties. 7.1.- Methods of M e a s u r e m e n t of Solid State Reactions If we wish to characterize a solid s t a t e reaction, from initial compound(s) to final product(s), there are only a few m e t h o d s we c a n use. Of p r i m a r y i m p o r t a n c e is x-ray identification since we m u s t k n o w w h a t we s t a r t e d with, a n d w h a t we e n d u p with. We have already d i s c u s s e d the x-ray m e t h o d in some detail in the s e c o n d c h a p t e r a n d how one goes a b o u t u s i n g t h a t m e t h o d . If a solid is stable at r o o m t e m p e r a t u r e , it will r e m a i n in t h a t state until s o m e form of energy is applied. In general, it is the application of h e a t t h a t c a u s e s s u c h change. We find t h a t two effects c a n occur s i m u l t a n e o u s l y , a t h e r m a l c h a n g e a n d a weight c h a n g e (but not always). As an example, consider CaC03. W h e n it is h e a t e d to a b o u t 8 4 0 ~ reaction, vis: 7. I . I . The arrow
CaC03
+ heat
it forms c a l c i u m oxide, CaO, b y solid state
~
CaO
+ C02
indicates t h a t a reaction h a s t a k e n place. The gas formed, C02, is
volatile a n d the final p r o d u c t h a s a lower m o l e c u l a r weight t h a n the star-ling material. T h u s , a w e i g h t l o s s occurs. The o r t h o r h o m b i e s t r u c t u r e of C a C 0 3
358
c h a n g e s to the cubic form of CaO. T h e r m a l energy is r e q u i r e d to r e a r r a n g e the atoms. W h a t h a s actually h a p p e n e d is t h a t we have exceeded the b o n d i n g energy of one c o m p o u n d (CaC03) b y i n c r e a s i n g the vibrational energy of the a t o m s to the point w h e r e chemical b o n d s are b r o k e n (by a d d i n g heat). This o c c u r s at a b o u t 8 4 0 ~ a n d C 0 2 gas is formed w h i c h is stable (and volatile). W h e n we cool the product, we find t h a t we have CaO. B e c a u s e this c h a n g e requires h e a t to be absorbed, the overall p r o c e s s is called e n d o t h e r m i c . If it h a d released h e a t d u r i n g the change, it would be called e x o t h e r m i c . M e a s u r e m e n t of the weight c h a n g e is called t h e r m o g r a v i m e t r i c a n a l y s i s (TGA) whereas
measurement
of the
thermal
change
accompanying
a structural
m e t a m o r p h o s i s is called t h e r m a l analysis (TA). Some c o m p o u n d s do not lose weight b u t m e r e l y c h a n g e their s t r u c t u r a l form. A good example of this involves zinc sulfide, ZnS. This m a t e r i a l is o b t a i n e d b y precipitation from solution a n d is cubic
at r o o m t e m p e r a t u r e .
When
heated
to a b o u t
1100 ~
cubic ZnS
(sphalerite) c h a n g e s to a h e x a g o n a l (wurtzite) form. If wurtzite is t h e n cooled to room t e m p e r a t u r e , it r e m a i n s hexagonal. Only ff wurtzite is cooled very slowly t h r o u g h the t r a n s i t i o n t e m p e r a t u r e does it revert to the cubic sphalerite form. AIk, CHANGES IN PHASE involve a release or a b s o r p t i o n of calories. One r e a s o n for this is t h a t e a c h s o l i d h a s its own h e a t c a p a c i t y . T h a t is, there is a c h a r a c t e r i s t i c h e a t c o n t e n t for e a c h m a t e r i a l w h i c h d e p e n d s u p o n the a t o m s c o m p o s i n g the solid, the n a t u r e of the lattice vibrations within it, a n d its s t r u c t u r e . The total h e a t content, or enthalpy, of each solid is defined by: 7.1.2.-
AH -- f Cp dT
, w h e r e - Cp -
(/~I/~r
w h e r e q is a h e a t quantity. T h u s , as we go from one solid to another, we see a c h a n g e in caloric content. One w a y to m e a s u r e this involves the u s e of DTA. A. DIFFERENTIAL THERMAL ANAI.YSIS (DTA) In 182 I, S e e b e c k discovered t h a t b y joining two different m e t a l wires together to
359
form a loop (two junctions), a direct c u r r e n t (DC) w o u l d flow in the circuit. A r e p r e s e n t a t i o n of this is given in the foUowing:
S e e b e c k u s e d a n t i m o n y a n d copper wires a n d found the c u r r e n t to be affected b y the m e a s u r i n g i n s t r u m e n t (ammeter). But, he also found t h a t the v o l t a g e
generated (EMF) w a s directly proportional to the d i f f e r e n c e in t e m p e r a t u r e of the two j u n c t i o n s . Peltier, in 1834, t h e n d e m o n s t r a t e d t h a t ff a c u r r e n t w a s i n d u c e d in the circuit of 7.1.3., it g e n e r a t e d h e a t at the j u n c t i o n s . In o t h e r words, the S E E B E C K E F F E C T w a s found to be reversible. F u r t h e r w o r k led to the development of the t h e r m o c o u p l e , w h i c h t o d a y r e m a i n s t h e p r i m a r y m e t h o d for m e a s u r e m e n t of t e m p e r a t u r e .
Nowadays, we k n o w t h a t the S E E B E C K
E F F E C T arises b e c a u s e of a difference in the electronic b a n d s t r u c t u r e of the two m e t a l s at the junction. This is illustrated as follows:
In this diagram, we s h o w the b a n d model s t r u c t u r e at the j u n c t u r e of two metals, e a c h of w h i c h h a s its own Ferrrd Level. The Ferrrd Level is the energy level of the electrons c o n t a i n e d in the metal. T h a t is- w h e n m e t a l a t o m s (each
360
having its own set of electrons) a s s e m b l e a n d / o r c o n d e n s e to form a metal, the electrons form a *cloud" a r o u n d all of the atoms. This cloud of electrons h a s a n average energy a n d the top of the energy level is called the Fermi Level. Using s u c h a concept helps one to m e n t a l l y conceive how electrons form energy b a n d s in a n y given solid. In c o n t r a s t to a metal, the electrons in m o s t inorganic solids form well defined energy b a n d s w h i c h are d e t e r m i n e d b y the atomic positions of the a t o m s c o m p o s i n g the s t r u c t u r e . The m a i n difference b e t w e e n inorganic solids a n d m e t a l s is t h a t the c o n s t i t u e n t electrons are confined to allowed energy zones, i.e.- Brillouin zones, in the former, b u t not in the latter. It is for this r e a s o n t h a t m o s t m e t a l s are conductive, w h e r e a s m o s t inorganic solids are not. Referring to the above diagram, flow of electrons is indicated b y the arrow. Since the height of the Fermi Level is proportional to t e m p e r a t u r e , t h e n the EMF g e n e r a t e d is a function of t e m p e r a t u r e also.
It is t h u s a p p a r e n t t h a t a
t h e r m o c o u p l e (TC) will consist of a negative a n d a positive "leg". The c o m m o n t h e r m o c o u p l e s in u s e t o d a y are listed in Table 5-1 along with the t e m p e r a t u r e range over w h i c h t h e y are useful. Also listed is the a p p r o x i m a t e EMF g e n e r a t e d over this range, as well as the n a t u r e of each "leg", i.e.- positive or negative. TABLE 7- I USEFUL TEMPERATURE RANGES FOR COMMON THERMOCOUPLE Composition
Code
O u t p u t Range
Useful Temp.
Useful
(millivolts)
Range, ~
Atm.*
(+)Copper-Constantan!-)
T
-5.28to 20.81
- 300 to 750
A,N, R
(+)Iron-Constantan(-)
J
-7.52to 50.05
-300 to 1600
R
(+)Chromel-Alumel(-)
K
-5.51 to 56.05
-300 to 2 3 0 0
A, N
(+)Chromel-Constantan(-)
E
0 to 75.12
32 to 1800
A,N, R
(-)Platinum-Pt(lO%Rh)(+),
S
0 to 15.979
32 to 2 9 0 0
A, N
0 to 18.636
32 to 3 1 0 0
A, N
0 to 38.45
32 to 5 0 0 0
N,R
(-) Pt- Pt (13% Rh)(+) (-)Tungsten(5%Re) -
R
C
W(26%Re) (+) * A = air or oxidizing; N = n e u t r a l 9R --- r e d u c i n g
361
The c o m p o s i t i o n s of the alloys u s e d to m a k e the t h e r m o c o u p l e s listed in Table 7-1 are given as follows: 7.1.5.- C o m p o s i t i o n s Used to Make T h e r m o c o u p l e s CHROMEL:
90% Ni - 10% Cr
ALUMEL:
95% Ni - 5% AI, S i , Mn
CONSTANTAN:
57% Cu - 43% Ni
In differential t h e r m a l analysis, i.e.- DTA, we u s e one t h e r m o c o u p l e 'q~ucked" a g a i n s t the voltage o u t p u t of a n o t h e r of the s a m e composition to p r o d u c e a "net" EMF. W h a t this m e a n s is t h a t either the positive (or negative) legs of b o t h t h e r m o c o u p l e s are electrically c o n n e c t e d so t h a t the n e t EMF at a n y given t e m p e r a t u r e of the two is zero. Only if one t h e r m o c o u p l e t e m p e r a t u r e differs from t h a t of the o t h e r does one o b t a i n an EMF r e s p o n s e . 7.1.6.- A Thermocouple Used for Differential T h e r m a l Analysis TC(I) = TC(2)
If we p u t a s a m p l e next to one t h e r m o c o u p l e a n d a "standard" or "reference" next to the other, we c a n follow a n y t h e r m a l c h a n g e s t h a t m a y take place as b o t h are h e a t e d since each TC g e n e r a t e s its own EMF as the t e m p e r a t u r e changes. T h u s , ff we p u t a reference material, R, directly in c o n t a c t with the "IE(1)" t h e r m o c o u p l e j u n c t i o n (hereinafter, we will refer to this t h e r m o c o u p l e j u n c t i o n as "R") a n d a sample, S, at TC(2), i.e.- "S", t h e n we c a n detect a n y t h e r m a l c h a n g e t h a t m a y o c c u r if either R or S u n d e r g o e s a t r a n s f o r m a t i o n as it is heated.
362
In this configuration, we can detect a n y t h e r m a l c h a n g e s t h a t o c c u r in the s a m p l e as c o m p a r e d to the reference. Note t h a t if b o t h TC-1 a n d TC-2 of 7.1.6. are at the s a m e t e m p e r a t u r e , n o EMF is g e n e r a t e d . Actually w h a t we are m e a s u r i n g are c h a n g e s in h e a t flow as related to Cp (see 7.1.2.). For inorganic materials, the b e s t reference material to u s e is r capacity r e m a i n s r
A1203. Its h e a t
even u p to its melting point (1930 ~
W h a t this
m e a n s is t h a t no t h e r m a l c h a n g e s o c c u r in R so t h a t a n y c h a n g e detected will be t h a t of the sample, S. In DTA, we w a n t to m e a s u r e n C p , b u t find t h a t this is actually: 7.1.7.-
[Cp(sf) - Cp(si} ]dTs
+ [ Cp ]dTR
w h e r e Si is the initial state a n d Sf is final state for a given solid state reaction of the sample, S (No reaction o c c u r s for R). It s h o u l d be a p p a r e n t t h a t we m u s t m a i n t a i n a n equal h e a t f l o w i n t o b o t h R & S s i m u l t a n e o u s l y ,
at a u n i f o r m
rate. If we raised the t e m p e r a t u r e b y steps, we would find t h a t the a c t u a l h e a t flow in b o t h R & S lags b e h i n d the furnace t e m p e r a t u r e considerably, as s h o w n in the following diagram: 7.1.8.-
Programmed (1)
Actual Temperature in Sample
E
CD
Time
IF-
363
The critical p a r a m e t e r s a s s o c i a t e d with the DTA Method have b e e n d e t e r m i n e d tobe: 7.1.9.-
FIVE PARAMETERS ASSOCIATED WI22-1 THE DTA ME22-IOD I. d T l d t = k 2. S a m p l e Size 3. Rate of Heating 4. Degree of Crystallinity of S a m p l e 5. Effects of E x t e r n a l A t m o s p h e r e
The rate of h e a t i n g generally u s e d for m o s t inorganic m a t e r i a l s r a n g e s b e t w e e n a b o u t 2 ~ to 20 ~ to 1 0 0 ~
in. while t h a t for organic c o m p o u n d s lies b e t w e e n a b o u t 15 ~
In the following diagram, a typical t h e r m o g r a m is shovm:
364
In this diagram, the a r r a n g e m e n t of the sample, S, a n d the reference, R, a c r o s s the differential TC is shown, a n d a typical DTA analysis is also given. Note t h a t at low t e m p e r a t u r e s , the DTA p e a k s are e n d o t h e r m i c . T h a t is, h e a t is absorbed. S u c h p e a k s are similar to t h o s e o b t a i n e d w h e n w a t e r - o f - h y d r a t i o n is lost, or w h e n the solid state reaction u n d e r g o e s a loss of water. The above DTA curve is similar to t h a t of the following reaction: 7. I. 1 I.-
CaHP04 - 2 H20 ~
CaHP04 + 2 H20
The first two p e a k s involve the loss of 2 w a t e r s of hydration. The broad e n d o t h e r m i c p e a k following in the above d i a g r a m is similar to t h a t we m i g h t see for a c h a n g e in composition s u c h as: 7.1.12.-
2 CaHPO4
~
Ca2 P2 0 7
+ H20
The e x o t h e r m l c p e a k m a y be a c h a n g e in s t r u c t u r e s u c h as: 7.1.13.-
~-Ca2P207
~
r
In general, solid s t a t e decomposition r e a c t i o n s o c c u r as e n d o t h e r m i c p e a k s (AH is negative a n d h e a t is absorbed) while p h a s e c h a n g e s , i.e.- c h a n g e s in s t r u c t u r e , o c c u r as exothermic p e a k s (AH is positive a n d h e a t is evolved). Note t h a t t e m p e r a t u r e c h a n g e is p r o g r a m m e d to be linear with time, in the above diagram. The c o m p o n e n t s
of a simple DTA A p p a r a t u s
are s h o w n in the
following diagram, given on the n e x t page as 7. I. 14. The first thing to note is t h a t the f u r n a c e s u r r o u n d s
the s a m p l e - h o l d e r
c o n t a i n i n g the differential t h e r m o c o u p l e s . A s e p a r a t e control t h e r m o c o u p l e controls the f u r n a c e t e m p e r a t u r e a n d s h o u l d be placed as close as possible to the position of the s a m p l e holder. Some c o m m e r c i a l m a n u f a c t u r e r s u s e the Reference leg of the differential t h e r m o c o u p l e
to control the t e m p e r a t u r e .
However, if you were to build a DTA u s i n g the c o m p o n e n t s as s h o w n in 7.1.14,
365
the separate furnace control thermocouple works j u s t as well (even t h o u g h it is not in exact juxtaposition with the sample a n d reference. A power supply is controUed by the t e m p e r a t u r e programmer. The temperature-prograrraner can be either mechanical or electrical in nature. A DC to DC amplifier is, in general, necessary to amplify the thermocouple signal to the recorder. It is possible to obtain a recorder with suI~cient sensitivity to directly record the TC signal. However, it is generally better to a m p l ~ j the TC signal in order to avoid s p u r i o u s electrical "noise" t h a t sometimes occurs. A two-pen recorder is
366
superior to a o n e - c h a n n e l recorder. In the latter case, it is n e c e s s a r y to switch from the differential TC signal to the t e m p e r a t u r e TC signal. However, in c a s e s w h e r e the 2 - c h a n n e l recorder is not available, a suitable DTA c h a r t be still be obtained. You will notice, on the above DTA g r a p h shown, t h a t the low t e m p e r a t u r e DTA p e a k s are endothermic. T h a t is, h e a t is absorbed. S u c h p e a k s are similar to t h o s e o b t a i n e d w h e n water-of-hydration is lost, or w h e n the solid state reaction u n d e r g o e s a loss of water. To u s e this a p p a r a t u s , one follows a simple procedure. The m e t h o d t h a t one follows to obtain a DTA r u n is given as follows: 7. I. 15.-
GENERAL PROCEDURE FOR OPERATING A DTA APP_ARATUS
a. Load b o t h s a m p l e a n d s t a n d a r d m a t e r i a l into the DTA holder. b. Put the DTA holder in place in the furnace. c. Set rate for t e m p e r a t u r e p r o g r a m m i n g . d. Set DC Amplifier gain. e, Set recorder gain a n d time drive f. Begin t e m p e r a t u r e program. g. Record T e m p e r a t u r e c h a n g e s The s a m p l e size (a function of its crystallinity) is u s u a l l y d e t e r m i n e d b y trial a n d error. About 500 milligrams is u s u a l l y sufficient. It h a s b e e n d e t e r m i n e d t h a t the p r o g r a m m e d t e m p e r a t u r e rate h a s a m a j o r effect u p o n the s h a p e of the p e a k s observed, as s h o w n in the following diagram, given as 7.1.16. on the next page. The r e a s o n for this is practical. One m u a t m a i n t a i n a c o n s t a n t h e a t flow a c r o s s the DTA head. For inorganics, a rate of 2 ~
s p r e a d s o u t the p e a k w h e r e a s a
rate of 20 ~ C. per m i n u t e s e e m s to be a b o u t correct for m o s t s y s t e m s .
367
7.1.16.-
] dT/dtl 2~ 5~ IO~
20 C o
One c a n p r o g r a m at higher rates, even u p to 100 o C./ rain. However, the inorganic s y s t e m c a n n o t a d j u s t fast e n o u g h to m a i n t a i n a c o n s t a n t h e a t flow. This is, of course, a m a t t e r of s y s t e m - d e s i g n . However, for organics, a rate of 100 ~
in. m a y be required. Most corranercial i n s t r u m e n t s have the correct
h e a t i n g r a t e p r o g r a m m e d into the control circuits a n d one u s u a l l y does not have to a d j u s t h e a t i n g - r a t e s . Only w h e n the DTA p e a k s are not s h a r p does one n e e d to a d j u s t h e a t i n g r a t e s to s e p a r a t e a n y near-lying p e a k s from one another. One c a n quantify the h e a t flow involved within the s y s t e m in t e r m s of the DTA p e a k p r o d u c e d . Consider the following, given as 7.1.17. on the next page. In this diagram, the sample, S, is within the f u r n a c e w h i c h is at a t e m p e r a t u r e , T S. The h e a t flow is d Q / d t a n d r is the t h e r m a l r e s i s t a n c e . The s a m p l e u n d e r g o e s a n ent_halpy c h a n g e , M-I, at its solid s t a t e reaction t e m p e r a t u r e .
368
T h u s , t h e h e a t flow is a f u n c t i o n of t h e differences in t e m p e r a t u r e of t h e s a m p l e a n d t h a t of t h e f u r n a c e , i.e.- T > T s . Then: 7.1.18.-
dQ/dt
= T-Ts/r
w h e r e t is t h e time. A n d t h e e n t h a l p y c h a n g e is t h e difference b e t w e e n t h a t of t h e s a m p l e a n d t h e h e a t flow is: 7.1.19..-
dH / dt = Cp(S) d T / dt - dQ / dt = Cp(S) d T / d t - [T- TS / r]
If we s e t u p t h e s a m e e q u a t i o n s for t h e reference m a t e r i a l , c o m b i n e t h e s e e q u a t i o n s a n d r e a r r a n g e , we o b t a i n : 7.1.20.-
I
II
HI
r[dH / dtl = [Ts - TR ] +[r{Cp(s) - Cp(R) )l dTR / d t + [rCp(S){d(Ts - TR) /dt}] Note t h a t we h a v e divided t h e e q u a t i o n into t h r e e (3) p a r t s , e a c h s u r r o u n d e d b y a b r a c k e t , i.e. []. This allows u s to i n t e r p r e t a DTA p e a k a s s h o w n in 7.1.2 I., given o n t h e n e x t page. T h e deviation f r o m t h e b a s e line (at 0) is a f u n c t i o n of b o t h I a n d II, t h a t is- t h e difference b e t w e e n s a m p l e a n d reference t e m p e r a t u r e s (I) a n d differences in h e a t c a p a c i t i e s of s a m p l e a n d reference.
369
T h u s , if the a p p a r a t u s is properly designed, I is not a problem, b u t II c a n n o t be controlled. It is II t h a t c a u s e s the deviation from linearity w h i c h r e s u l t s in a peak. The slopes are a function of the h e a t c a p a c i t y differences b e t w e e n ~ m p l e
plus reference and product plus reference. The slopes (III) o b t a i n e d are a function of differences b e t w e e n TS a n d T R . Note t h a t at the top of the peak, we still have a p p r o x i m a t e l y 1 / 2 s a m p l e (as r e a c t a n t ) a n d 1 / 2 product. Referring to 7.1.20. a n d 7.1.21., it would s e e m t h a t t h e a r e a of the DTA p e a k s h o u l d be proportional to z~I. This is indeed the case a n d a c o m p a r i s o n of p e a k a r e a s does yield a n e x p e r i m e n t a l value for ~-H(s), vis: 7.1.22.-
~-I(s)
= ~Std.
"i(s} /i(Std)
This e q u a t i o n a s s u m e s a relation b e t w e e n A a n d AH. Actually, this is not too h a r d to prove, as we c a n show in t h e followi_ng. Consider a h e a t s i n k as a block c o n t a i n i n g b o t h S a n d R (sample a n d reference). This is illustrated in t h e following diagram, given as 7.1.23. on the next page. In this diagram, we define t h r e e t e m p e r a t u r e s , TB , TS & T R , w h e r e e a c h s u b s c r i p t refers to block, s a m p l e a n d reference, respectively. We also have two h e a t capacities, C p ( s ) a n d Cp(R).
370
w h e r e a is t h e t h e r m a l d i f f u s i v i t y . For c o n v e n i e n c e , we define t h e total h e a t flow in t e r m s of h e a t flow b e t w e e n S & B, R & B, a n d R & S. We also u s e a STANDARD SAMPLE a n d r u n it a g a i n s t t h e reference, so t h a t we c a n d e t e r m i n e h o w m a n y calories p e r g r a m are r e q u i r e d for a given t r a n s i t i o n so a s to c a l i b r a t e the system. The following table, given o n n e x t page, s h o w s s o m e m a t e r i a l s s u i t a b l e for s u c h calibration, along w i t h t h e t e m p e r a t u r e at w h i c h t h e solid s t a t e c h a n g e o c c u r s . Note t h a t t h e reference m a t e r i a l , r 3, is t h e r m a l l y i n e r t w h e r e a s t h e s t a n d a r d reference m a t e r i a l s a r e n o t . A p p r o p r i a t e v a l u e s of ~
are available for
t h e s t a n d a r d reference m a t e r i a l s given in Table 5-2 o n t h e n e x t page. R e t u r n i n g to o u r d e s c r i p t i o n of a n a n a l y s i s of t h e h e a t flows p r e s e n t in DTA, as s h o w n in 7.1. 17., this gives u s t h e following e q u a t i o n s (Note t h a t -- is "defined as")
9
7.1.25.-
d T / d t -KS --
K (dQ/dt)sB
KR
--
(dQ / dt)RB
k
--
(dQ / dt)RS
371
TABLE 5 - 2 T H E R M O M E T R I C FIXED POINTS FIXED POINTS *
TEMPERATURE oC. o F.
B. P. of 0 2
- 183.0
- 297.3
S u b l i m a t i o n P o i n t of C O 2
- 87.4
- 109.2
F.P. - H g
- 38.9
- 38.0
Triple P o i n t of W a t e r
0.01
32.0
Ice P o i n t
0.00
B.P. - W a t e r
100.0
212.0
32.0
Trk)le P o i n t of B e n z e n e I B. P. of N a p h t h a l e n e
122.4
252.4
218
F.P. o f S n
231.9
B.P. of B e n z o p h e n o n e
305.9
582.6
F.P. of C d
321.1
610
F.P. o f Pb
~3 2 7 . 5
i 621.5
F.P. o f Z n
419.6
787.2
,
1424.3 449.4 [
il
B.P. o f S
.
444.7
i
832.4
F.P. o f S b
630.7
1167.3
F.P. of A1
660.4
1220.7
F.P. o f Ag
961.9
1763.5
F.P. o f A u
1064.4
1948
F.P. of C u
1084.5
1984.1
F.P. o f P d
1554
.
.
.
.
.
.
.
.
F.P. o f Pt
1772
i
2829 3222
* F.P. = F r e e z i n g Point, M.P. = M e l t i n g P o i n t , a n d B.P. = B o i l i n g P o i n t W e c a n i m m e d i a t e l y write( s e e 7 . 1 . 2 . , 7 . 1 . 1 8 . & 7 . 1 . 1 9 . ) 9 7.1.26.-
Cp(S) d T s [ d t = KS (TB - TS) + k {(TR- TS) + d ( A H ) / d t Cp(R) d T R / d t = KR (TsB- TR) + k (Ts - TR)
372
The e q u a t i o n for R is simplified b e c a u s e R is t h e r m a l l y i n e r t a n d t h e r e is no c h a n g e in e n t h a l p y involved. To simplify m a t t e r s f u r t h e r , we define: 7.1.27.-
(I)s
~
CptS) / KS
(I)R
~
Cp(R) / KR
HS
--
k/Ks
HR
--=
k/KR
M a k i n g t h e s e s u b s t i t u t i o n s , we get: 7.1.28. -
(I)s d T s / dt + ( 1+ Hs)Ts - HSTR = TB + ( 1 / KS) d(td-I} / d t
and: (I)R
dTR / dt + ( 1 +HR) TR - HR TS = TB
Now if k = 0, i.e.- t h e r e is no h e a t e x c h a n g e b e t w e e n R & S {as in a p r o p e r l y designed apparatus), and if7.1.29.-
TS = To + t {dT/dt)
i t will b e if we are p r o g r a m m i n g t h e t e m p e r a t u r e . T h e n we c a n define To a s b e i n g e q u a l to zero, so a s to o b t a i n t h e following e q u a t i o n s : 7.1.30.-
(I)s dTs / d t + T s = t (dT/dt) + ( 1 / Ks} d(AH) / d t
and:
(I)R
dTR / d t + TR = t (dT/dt)
If we are n o t in a region w h e r e a solid s t a t e r e a c t i o n is t a k i n g place, t h e n d(AH)/dt = 0. The e l u m g e in b a s e l i n e t e m p e r a t u r e (see above) is now: 7.1.31.-
ATB = d T / dt ((I)s - (I)R) = TS - TR
373
In o t h e r w o r d s , the c h a n g e in b a s e l i n e t e m p e r a t u r e is c a u s e d b y a difference in the relative t e m p e r a t u r e s of s a m p l e a n d reference, w h i c h is r e l a t e d to their relative h e a t capacities. T h u s , one n e e d s to c h o o s e the reference m a t e r i a l very carefully. If we s u b t r a c t t h e e q u a t i o n s in 7.1.30., we c a n get: 7.1.32.-
(I)s d{Ts - TR} / d t + (Ts - TR) - (dTR / dt) = ( 1 / KS) d(AH) / d t
This c a n be r e a r r a n g e d to: 7.1.33.-
r
d ATs I dt + AT - {dT/dt) = (I l KS) d(AH} I dt
AT is t h e difference in t e m p e r a t u r e b e t w e e n the reference a n d the sample. In o t h e r w o r d s , it is AT t h a t c r e a t e s the DTA peak. Since we are n o t m e a s u r i n g
a b s o l u t e v a l u e s of the t e m p e r a t u r e s , we c a n define a r ~ l a t i v e t e m p e r a t u r e : 7.1.34.-
ATRel = AT- ATB = AT- (Ts - T R)
Using t h i s relation, we get: 7.1.35.-
~ s d A T R e l / dt + ATR + { d T / d t - d T s / dt)(CI~s-CI)R} = (1/Ks) d{AH}/ dt
If we c h o o s e a s u i t a b l e reference m a t e r i a l ( s u c h as A1203 for inorgardcs), t h e n dTR / d t will be e q u a l to d T / d t . O u r e q u a t i o n is t h u s simplified to: 7.1.36.-
(I)s f (d ATRel / dt) + ATRel = (1 / K S ) f d All / d t
However, the first t e r m is e q u a l to zero, so: 7.1.37.-
f d td-I = KS f ATRel dt
This is w h a t we s t a r t e d o u t to prove, i.e.- AH e q u a l s the a r e a of the p e a k t i m e s the total h e a t flow to the sample.
374
B. DIFFERENTIAL SCANNING CAIX)RIME2~Y Since AH is proportional to the a r e a of the DTA peak, one o u g h t to be able to m e a s u r e h e a t s of reaction directly, u s i n g the equation: 7.1.22. Indeed we c a n and
such
is the b a s i s
of a related m e t h o d
called Differential S c a n n i n g
Calorimetry (DSC), b u t only ff the a p p a r a t u s is modified suitably. We find t h a t it is difficult to m e a s u r e the a r e a of the p e a k o b t a i n e d b y DTA accurately. Although one could u s e an integrating recorder to convert the p e a k to a n electrical signal, there is no w a y to u s e this signal in a control-loop feed-back to p r o d u c e the desired result. A m o r e practical w a y to do this is to control the rate of heating, i.e.- d T / d t , a n d provide a s e p a r a t e signal to o b t a i n a h e a t i n g differential. One s u c h w a y t h a t b e c a m e the b a s i s of DSC is s h o w n in the following diagram:
The a p p a r a t u s
c o n s i s t s of
a D S C - h e a d within a furnace,
like the DTA
a p p a r a t u s . However, there is also a silver block w h i c h encloses the DSC h e a d as well. This e n s u r e s complete a n d even h e a t dispersion. There are individual
375
heaters
for b o t h
measured
is t h e
the
reference
current
(R) a n d
required
sample
to k e e p
the
(S) p a n - h o l d e r s .
What
is
differential t h e r m o c o u p l e
b a l a n c e d , i.e. AT = 0. This signal cmn be amplified a n d r e c o r d e d . We u s e t h e s a m e a p p r o a c h for DSC a s we did for DTA. We s t a r t w i t h t h e t h e r m a l h e a t flow e q u a t i o n w h i c h is s i m i l a r to O h m ' s Law : 7.1.39.
d Q l d t = TB - TS I r
We c a n define t h e h e a t c h a n g e involved w i t h t h e s a m p l e a s d h / d t so a s to get the equation: 7.1.40.-
d h / (it = Cp (S) [dTs / dtl - dQ / dt = Cp {s) [dTs / d t l - ITs - TB] / r
We are u s i n g t h e s a m e t e r m i n o l o g y for DSC a s we did for DTA. Following t h e m e t h o d s given above, w e arrive at: 7.1.41.-
d q / d t = (Cp(s) - Cp(R}) d T B / d t + 1/r{dTB/dt - t}
We c a n t h u s "interpret" a DSC p e a k in t e r m s of t h i s e q u a t i o n , as we did for t h e DTA peak, as s h o w n in t h e following d i a g r a m :
376
As c a n be seen, the initial p a r t of the reaction u p to (dq/dt)max
is linear
w h e r e a s the curve b e c o m e s exponential p a s t the peak. This is d u e to the difference in Cp b e t w e e n the r e a c t a n t a n d product. T h u s , A I * A2. Actually, the reaction p e a k in 7.2.5. is an idealized curve since the baseline is a function of the d i f f e r e n c e in h e a t capacities between reference to s a m p l e a n d reference a n d product. Usually, we have a different baseline, vis:
This p r e s e n t s a p r o b l e m since it is difficult to estimate the a r e a of the peak. One c a n n o t simply extend the baseline as in Case I. A m u c h better solution is t h a t s h o w n in Case II, w h e r e i n the two very a s y m m e t r i c a l peaks, i.e.- the initial a n d final p a r t s of the overall t h e r m a l reaction t a k i n g place, are delineated. This p r o b l e m h a s not b e e n satisfactorily a n s w e r e d as yet a n d r e p r e s e n t s a challenge to a n y o n e u s i n g DCS m e t h o d s to characterize a solid state reaction. 7.2. - U22LIZATION OF I:YI'AAND DSC A. Applications o.f I:YI'A One of the m a j o r u s e s of DTA h a s b e e n to follow solid-state reactions as t h e y occur. All decomposition r e a c t i o n s floss of h y d r a t e s , w a t e r of constitution, decomposition of inorganic anions, e.g.- c a r b o n a t e to c a r b o n dioxide gas, etc.)
are endothem~ic a n d irreversible. Likewise are the s y n t h e s i s r e a c t i o n s s u c h as
377
CaO reacting with A1203 to form c a l c i u m a l u m i n a t e , CaAI204. P h a s e c h a n g e s , o n the o t h e r h a n d , are r e v e r s i b l e , b u t m a y be e n d o t h e r m i c or exothermic. Thus, if we follow a solid state reaction by DTA a n d o b t a i n a series of reaction p e a k s , it is e a s y to d e t e r m i n e w h i c h are p h a s e c h a n g e s b y recording the p e a k s o b t a i n e d d u r i n g t h e c o o l i n g cycle. W h e r e a s DTA d a t a are qualitative, t h o s e from DSC are q u a n t i t a t i v e a n d give information c o n c e r n i n g the h e a t c h a n g e (change in enthalpy) a c c o m p a n y i n g the exothermic or e n d o t h e r m i c reaction. For example, o n e c a n o b t a i n a value for melting of a solid state reaction p r o d u c t in t e r m s of calories / g r a m or Kcal. / mole. DTA is especially s u i t e d in t h e c o n s t r u c t i o n of unkno,ma p h a s e d i a g r a m s of b i n a r y c o m p o u n d s . A hypothetical p h a s e d i a g r a m a n d the DTA c u r v e s w h i c h w o u l d be u s e d to c o n s t r u c t it are s h o w n in the following diagram, given as 7.2.1. o n the next page. In this diagram, the endotherrrdc (Endo) p e a k s point to the fight while the exothermic (Exo) p e a k s point to t h e left. C o n s i d e r a s y s t e m with two c o m p o n e n t s , A a n d B (see 7.2.1.). They form a n incongruenfly melting c o m p o u n d , AB. The c o m p o u n d , AB, forms only a limited solid solution with A. Most of the c o m p o s i t i o n range is a taro-phase region, with a eutectic. The DTA r u n s are s u p e r i m p o s e d o n the specific c o m p o s i t i o n p o i n t s of the diagram. T h u s at (1) o n the d i a g r a m (about 10% A a n d 90% AB), we see o n e Exo a n d two E n d o peaks. The Exo p e a k is the point where the t w o - p h a s e mixture, A + AB, c h a n g e s to a single p h a s e , i.e. - a solid state solution of A in AB. F u r t h e r on, a n E n d o p e a k indicates the melting point of AB, a n d finally t h a t of A. At (2), we see only the two melting points, first t h a t o f A B a n d t h e n A. B u t at (3), only the melting point of t h e eutectic is seen, t h a t is, b o t h A a n d AB melt at the s a m e temperature. In o u r P h a s e Diagram, the c o m p o u n d , AB, m e l t s i n c o n g r u e n t l y , t h a t is - it d e c o m p o s e s at its melting point. Therefore. at (6), a double p e a k is seen r e p r e s e n t i n g the d e c o m p o s i t i o n of AB a n d the melting of A. However, B m e l t s at
378
a later time. Note t h a t one c a n pinpoint c h a n g e s in the p h a s e d i a g r a m quite accurately by r u n n i n g a DTA t h e r m o g r a m at specific composition points. For the most part, the thermal c h a n g e s observed are specific, b u t it is wise to cool reversibly, while observing the DTA p e a k s in cooling so as to be sure exactly w h a t the original p e a k represents.
379
Still a n o t h e r u s e to w h i c h DTA h a s b e e n employed is the c h a r a c t e r i z a t i o n of a m o r p h o u s materials. The following s h o w s a typical DTA t h e r m o g r a m o b t a i n e d w h e n a p o w d e r e d s a m p I e of glass is r u n as s h o w n in the following diagram: 7.2.2.-
IDiirentisiThermal
200
400
Analysis Of a Typical Glass I 600
1000
800
Tsp - 582 o C.
r
I
200
I
400
T M= 942 Oc. 600 -800 Teml~rature in ~
Note t h a t n e a r l y all of the c h a r a c t e r i s t i c "glass
1000
I
I
points" c a n be d e t e r m i n e d , i.e.-
Tg
= Glass transition temperature
TSp
= G l a s s softening p o i n t t e m p e r a t u r e
TD
= G l a s s devitrification t e m p e r a t u r e
TM
= Melting t e m p e r a t u r e of crystallized p r o d u c t
The o n l y o n e t h a t is not readily accessible b y DTA is the e x p a n s i o n coefficient. It is d e t e r m i n e d b y u s e of a t h e r m a l e x p a n s i o n a p p a r a t u s , i.e.- a dilatometer. Methods a n d u s e s of t h e r m a l e x p a n s i o n will be d e s c r i b e d in a s u c c e e d i n g section.
380
B. Uses of DSC The g r e a t e s t u s e for DSC h a s t u r n e d o u t to be for c h a r a c t e r i z a t i o n of organic polymers. It h a s b e e n found t h a t m o s t polymers are a m o r p h o u s a n d have a c h a r a c t e r i s t i c T g , i.e.- a "glass" t r a n s i t i o n t e m p e r a t u r e w h i c h leads to a "crystalline" p h a s e . O t h e r c o m m o n u s e s include d e t e r m i n a t i o n points, boiling points, T g , % crysta!linity a n d oxidative stability.
of melting
In obtaining boiling points b y DSC, it is n e c e s s a r y (14) to u s e a closed p a n having a n extremely small hole to allow the v a p o r to escape. The hole is m a d e b y u s e of a laser a n d s h o u l d not be m o r e t h a n 50-80 V in diameter. W h e n a semi-volatile m a t e r i a l is heated, a n e q u i l i b r i u m will be e s t a b l i s h e d b e t w e e n m a t e r i a l in the gas p h a s e a n d in the c o n d e n s e d p h a s e . As the m a t e r i a l is being heated, the p r e s s u r e exerted b y the volatile p h a s e , i.e.- the v a p o r p r e s s u r e , increases. The rate of h e a t i n g is i m p o r t a n t a n d s h o u l d be k e p t b e t w e e n a b o u t 6-10 ~
per m i n u t e . It is i m p o r t a n t to have the two p h a s e s in e q u i l i b r i u m as
the s a m p l e i n c r e a s e s in t e m p e r a t u r e , h e n c e the u s e of a n e s c a r p m e n t in the s a m p l e p a n to r e t a r d e s c a p e of the volatile material. This a r r a n g e m e n t allows the v a p o r p r o d u c e d to sweep o u t the air a n d replace it. At the t e m p e r a t u r e w h e r e the vapor p r e s s u r e of the s a m p l e exceeds the total p r e s s u r e of its s u r r o u n d i n g s , the m a t e r i a l boris. If the outside p r e s s u r e is kept c o n s t a n t , there will be a n e n d o t h e r m i c h e a t flow a s s o c i a t e d with c o n d e n s e d p h a s e m a t e r i a l entering the v a p o r p h a s e . As the t e m p e r a t u r e increases, the rate of boiling also increases. W h e n all of the m a t e r i a l is in the v a p o r stage, it r e m a i n s in t h a t s t a t e until all of the m a t e r i a l h a s boiled off. If the hole is not small enough, t h e n all of the m a t e r i a l will be evaporate a n d be lost before the e q u i l i b r i u m condition is attained. If a n equilibrium b e t w e e n v a p o r a n d m a t e r i a l is not achieved, t h e n the boiling point m e a s u r e d will not be the t r u e boiling point. As a n example of how the d a t a are obtained, the following d i a g r a m is p r e s e n t e d as 7.2.3. on the n e x t page. This d i a g r a m s h o w s the behavior of w a t e r at 1.0 a t m o s p h e r e w h e n it is s u b j e c t e d to the above conditions. Note the design of the p a n u s e d to h e a t the water. It c o n s i s t s of a n oval s h a p e , s o m e t h i n g like a n "egg"
381
7.2.3.-
[Boiling Point of Water by DSC[
i00
[Pan Usec~ Hole
6~ 4.5 mg.
80 -,-4
Onset = 100 ~
6o ID
m 40 IlililillliNNllimllli~iil
40
60 80 Temperature, ~
100
120
with a small hole on the top to limit the a m o u n t of water escaping at the boiling point. Keep in mind that the heat flow (which is related to the degree of vapor change achieved) is low in the beginning, b u t rises rather fast as the boiling point is reached. The fiat lead/rag edge of the endotherm represents the point where the sample temperature is constant at the boiling point. If one m e a s u r e s the boiling points at several pressures, including that of atmospheric pressure, one can then extrapolate to obtain the vapor pressure of a material at ambient temperature. This is done using the Clausius-Clapeyron equation, i.e.7.2.4.-
Eo -- RT 2 { d l n k l Eo = AH* + RT
/dt)
7.3.- Thermo_~ravimetry Thermogravimetric analysis fleA) m e a s u r e s changes in weight of a sample being heated. A typical Thermogravimetric analysis fleA) a p p a r a t u s is shown in the following diagram:
382
This i n s t r u m e n t c o n s i s t s of a n analytical b a l a n c e having a w e i g h t - c h a n g e detector on one side of the b a l a n c e . Although c u r r e n t c o m m e r c i a l TGA designs no longer u s e s u c h a balance, the original ones did so. C u r r e n t TGA designs employ
piezoelectric
crystals
or
similar
types
of
crystals
sensitive
to
gravitational force to m e a s u r e c h a n g e s in weight as the t e m p e r a t u r e is raised. As in the DTA design, a t e m p e r a t u r e p r o g r a m m e r is n e e d e d along with a f u r n a c e t e m p e r a t u r e TC. A power s u p p l y is controlled b y the t e m p e r a t u r e programmer.
The
temperature-programmer
can
be
either
mechanical
or
electrical in n a t u r e . It is possible to obtain a recorder with sufficient sensitivity
383
to directly record the TC signal. However, it is generally better to amplify the TC signal in order to avoid spurious electrical "noise" that sometimes occurs. A two-pen recorder is superior to a one-channel recorder where it would be necessary to switch from the differential TC signal to the temperature TC signal. However, in cases where the 2-channel recorder is not available, a suitable TGA chart be still be obtained. The actual weight is monitored in real time. Changes in weight, either gains or losses, are evident immediately. The a p p a r a t u s itself consists of the sample situated within a crucible, which is enclosed within a temperature-controlled furnace. The sample, plus crucible, is counterbalanced on a sensitive balance. Weight changes are directly plotted on a two-pen recorder. Weight readout is usually accomplished by one of two methods, a linear t r a n s d u c e r or a capacitance change between two fiat plates, one of which is free to move with the balance swing. A resistance-capacitance t a n k circuit completes the electronics, producing a readable voltage. We usually employ a crucible to hold the powder sample, although fiat p a n s are also suitable. Furnace temperature is controlled in a linear m a n n e r and recorded. In some cases, the TC is mounted directly at the sample position. It is important that sample and furnace temperatures be nearly equal, so as to record accurate weight losses and gains. Operational parameters for TGA are: 7.3.2.-
I. 2. 3. 4. 5.
Sample Size (buoyancy) Sample Closure Heating Rate Heating Mode External Atmosphere
The SAMPLE SIZE is important because most balances have a limited range of weighing, as well as a limited sensitivity, i.e.- milligrams per gram of weight detectable. Many balances feature automatic counter-weight loading. If a sample is fluffy and a large crucible is used, then the buoyancy factor m u s t be accounted for. At high temperatures, i.e.- > 800 ~ the density of air within
384
the furnace is sufficiently l o w e r t h a n t h a t of the outside, so t h a t the a p p a r e n t weight of the sample plus crucible appears lower t h a n it actually is. And, the larger the crucible, the more air is displaced within the furnace. For 10.000 g r a m s of total weight, the b u o y a n c y factor will be a b o u t 0.002, enough t h a t a correction needs to be m a d e for precision work. SAMPLE CLOSURE is i m p o r t a n t since it affects the rate of solid state reaction. Consider the following solid state reaction7.3.3 9-
CaC03
-7
CaO
+
C02
If the gas is restricted from escaping, t hen the equilibrium is shifted t o t h e left a n d the CaC03 does not decompose at its u s u a l temperature. A h i g h e r t e m p e r a t u r e is required to effect decomposition. atmosphere, s u c h as CO2 in the above reaction,
Likewise, a n external restricts the a p p a r e n t
t e m p e r a t u r e of decomposition, the rate of reaction, and sometimes, the mode of decomposition {depending u p o n the n a t u r e of the c o m p o u n d u n d e r investigation}. As an example, consider the following: CaCO3 normally decomposes at a b o u t 860 ~
In a 1.0 a t m o s p h e r e p r e s s u r e of C02, the
decomposition t e m p e r a t u r e is raised to a b o u t 1060 ~ HEATING RATE is i m p o r t a n t from a practical aspect. Usually, we are m e a s u r i n g furnace t e m p e r a t u r e a n d c a n n o t pr ogr a m the t e m p e r a t u r e too fast, for fear t h a t the sample t e m p e r a t u r e will lag the furnace t e m p e r a t u r e by too great a degree. It is also for this reason t h a t we us e as small a sample as is practical to obtain a weight loss or gain which the balance can discriminate. This again depends u p o n the sensitivity of the balance a nd the n a t u r e of the reaction we are examining. In general, weight gains (due to oxidation) require more sensitivity and larger sample sizes t h a n those of decomposition. Usually, we restrict heating rates to > 15 ~ and use a heating rate of a b o u t 6-8 ~ min. at most. The HEATING MODE to be u s e d depends u p o n the results we wish to achieve. A typical TGA r u n is given in the following diagram:
385
7.3.4.-
I A Typio l Thermogravimetrio
A n a l y a i s , Run
!
A ,i
o
w,
h
: olid S t a t e S Reaction
I I I
,,i.k
.......... J,,,.',
Weight Loaa
L
B
A -~B -~C
II ". ! ;
L.
a ]
C
IIIIiIII
IIIIngIIlII
!
;
I I ,
,: .:
I
.
.
gilman . .
I
T 1T~. Temperature,
!
"
I I ,
9
,,,
|
T8T4 ~
In the solid state reaction depicted, A begins to decompose to B at T1 a n d the reaction t e m p e r a t u r e for decomposition is T 2 , with a weight loss of WI. Likewise, the reaction of B to form C begins at T3 a n d the reaction t e m p e r a t u r e (where the rate of reaction is m a x i m u m ) is T4 . Note that the weight loss becomes c o n s t a n t as each reaction product is formed a n d the individual reactions are completed. If we p r o g r a m the t e m p e r a t u r e at 6 ~ in., we would obtain the results in 7.3.4. This is called dymamte t h e r m o g r a v i m e t r y . However, if we set the furnace t e m p e r a t u r e j u s t slightly greater t h a n T2 , we would obtain a reaction limited to t h a t of A - B, a n d t h u s could identify the intermediate reaction product, B. This technique is called i s o t h e r m a l t h e r m o g r a v i m e t r y , Thus, we can foUow a solid state reaction by first surveying via dynamic TGA. If there are a n y intermediate products, we can isolate each in turn, a n d after cooling (assuming each is stable at room temperature) can identify it by x-ray analysis. Note t h a t we can obtain an a ~ a y easily:
386
7.3.5.-
A s s a y =- final w e i g h t / original weight
If there is a g a s e o u s product, we c a n also identify it b y converting weight loss to m o l s / m o l of original reactant. In 7.3.3. above, 1.00 mol of C 0 2 is expected to be lost per mol of reacting C a C 0 3 .
The a c t u a l n u m b e r of mols lost d e p e n d s
u p o n the original s a m p l e size. The m o s t recent TGA a p p a r a t u s includes w h a t is called EGA, i.e.- effluent gas analysis. Most often, this c o n s i s t s of a small m a s s s p e c t r o g r a p h capable of identifying the v a r i o u s g a s s e s m o s t often e n c o u n t e r e d in TGA. G a s e o u s weight losses c a n be classified according to the n a t u r e of the effluent g a s e s detected. These include the following: 7.3.6.-
G a s e o u s P r o d u c t s = C02 , N 2 0 4 , H 2 0 , S 0 2 , S O 3 , CO. Water - of h y d r a t i o n - of c o n s t i t u t i o n
- adsorbed Regardless of how well a s a m p l e h a s b e e n dried, it will always have a n a d s o r b e d m o n o l a y e r of w a t e r on the surface of the particles. If we r u n the DTA carefully, we will see a small e n d o t h e r m i c p e a k a r o u n d 100 ~
Additionally, ff we r u n the
TGA properly, we will see a small loss p l a t e a u before the m a j o r losses begin. As a m a t t e r of fact, if w e
do
not
see
the
loss
of adsorbed
water,
either the
a p p a r a t u s is not o p e r a t i n g properly, or we do not have sufficient sensitivity to observe the reactions t a k i n g place. The different types of w a t e r w h i c h c a n be p r e s e n t d u r i n g a n y inorganic solid state reaction is easily illustrated by the following example. Dibasic calcium o r t h o p h o s p h a t e forms a dihydrate: 7.3.7.-
C a H P 0 4 - 2 H20
- brushite
CaHPO4
- monetite
B r u s h i t e r e a c t s to form m o n e t i t e w h i c h t h e n r e a c t s to form p y r o p h o s p h a t e : 7.3.8.-
2 CaHPO4- 2 H 2 0 = 2 C a H P 0 4 + 2 H20 2 CaHP04
= Ca2 P2 0 7 + H2 0
387
We c a n illustrate the type of calculations n e e d e d in order to determine the p a r a m e t e r s involved in TGA r u n s . In the foUowing discussion, we p r e s e n t how one confronts this p r o b l e m a n d the calculations needed to p r o d u c e the desired results. The following Table, p r e s e n t s a typical p r o b l e m t h a t one e n c o u n t e r s in TGA a n d the calculations n e e d e d to p r o d u c e the desired results. Tab!e 7- 3 A TYPICAL PROBLEM IN TGA FIRED PRODUCT ORIGINAL Ca2P207 brushite
METHOD X-ray Analysis: Weight:
17.311 g r a m
12.705 g r a m
Molecular Weight:.
172.09
254.11
.....
In this case, we s t a r t with a k n o w n material for which we have already u s e d xray analysis to determine the n a t u r e of the fired product. We s t a r t with the reactions given in 7.3.8. for the reactions of calcium p h o s p h a t e , since this also illustrates h o w a s s a y s are calculated. The s t e p s include: I. Determine a s s a y 2. By s u b t r a c t i n g actual a s s a y from theoretical assay, obtain a m o u n t of w a t e r actually a d s o r b e d on particle surfaces 3. Determine losses i n c u r r e d by stages, ff one w i s h e s to determine the actual reactions o c c u r r i n g d u r i n g the solid state reaction O u r first step is to mnalyze the solid state reaction by m e a n s of the values d e t e r m i n e d in the TGA analysis r u n . T h e reaction p r o d u c t s are given above, along with the requisite m o l e c u l a r weights. The next p a r t required in the TGA analysis is given as follows (this is a c o n t i n u a t i o n of Table 7-3):
388
OVERAIk, SOLID STATE REACTION: 2 CaHP04 - 2 H20 = Ca2 P2 0 7 + 3 H 2 0 Molecular Weight:
2(136.059) + 2(18.015)
254.11
WEIGHT:
17.311 g r a m
12.705 g r a m
+ 54.045
(Assay = 73.39%; Theor.--- 73.83%) ANALYSIS:
12.705 g r a m Ca2 P2 0 7
- 17.208 g r a m of 2 CaHPO4- 2 H20
By c a l c u l a t i o n , we find t h a t we h a v e 9 9 . 4 1 % of 2 CaHPO4 - 2 H 2 0 a n d 0 . 5 9 % a d s o r b e d w a t e r (by s u b t r a c t i o n ) . We c a n also d e t e r m i n e f r o m t h e TGA r u n t h e a m o u n t of w a t e r loss b y s t a g e s in t h e overall reaction: L o s s e s b y Stages:
I st loss = a d s o r b e d H 2 0 2 n d loss =
= 0.102 gram = 3 . 5 3 2 g r a m I~20
3 r d loss = m o n e t i t e to
= 3 . 9 2 tools = 0.972 gram H20
pyrophosphate
= 1.08 tools
Total wt. of w a t e r lost
= 4.606 gram
b r u s h i t e to m o n e t i t e
Note t h a t t h e s e c o n d loss c o r r e s p o n d s to 3 . 9 2 m o l of w a t e r p e r m o l of r e a c t a n t , w h e r e a s t h e 3 r d loss is 1.08 mol. T h i s i l l u s t r a t e s a s e r i o u s p r o b l e m t h a t c a n b e e n c o u n t e r e d in d y n a m i c TGA, If t h e
rate
of heating
is too
fast and not
e n o u g h t i m e o c c u r s d u r i n g p r o g r a m m i n g to achieve t r u e e q u i l i b r i u m b e t w e e n s u c c e s s i v e solid s t a t e r e a c t i o n s , t h e n t h e loss of w a t e r f r o m o n e r e a c t i o n c a r r i e s o v e r into t h e n e x t s u c c e e d i n g r e a c t i o n .
7.4.- D e t e r m i n a t i o n of R a t e P r o c e s s e s in Soh'd S t a t e R e a c t i o n s We h a v e p r e s e n t e d two m e t h o d s u s e f u l in following solid s t a t e r e a c t i o n s . In o r d e r to c o m p l e t e l y classify a r e a c t i o n , we n e e d to o b t a i n a n e s t i m a t e of t h e r e a c t i o n k i n e t i c s a n d o r d e r of t h e solid s t a t e reaction. B o t h DTA a n d TGA h a v e b e e n u s e d to o b t a i n r e a c t i o n r a t e kinetics. B u t first, we m u s t r e a x a m i n e kinetic
389
t h e o r y in light of solid s t a t e reactions, w h i c h differ from t h o s e involving g a s e o u s c o m p o n e n t s u s u a l l y q u o t e d in b o o k s dealing with reaction r a t e kinetics, the following d i s c u s s i o n r e i t e r a t e s w h a t we have already p r e s e n t e d , b u t is given again h e r e to r e e m p h a s i z e its i m p o r t a n c e in solid s t a t e chemistry. A. TYPES OF SOLID STATE REACTIONS In general, we c a n classify solid s t a t e r e a c t i o n s as being either h o m o g e n e o u s or h e t e r o g e n e o u s . The former involves r e a c t i o n s b y a single c o m p o u n d w h e r e a s the latter involves r e a c t i o n s b e t w e e n two different c o m p o u n d s . T h e r e are at least four (4) types of solid s t a t e r e a c t i o n s (as we have a l r e a d y p r e s e n t e d in a prior chapter): 7.4. i.-
Types of Solid S t a t e Reactions I. decomposition:
A ~B+C
2. s y n t h e s i s -
A+B~C
3. s u b s t i t u t i o n a l :
A+B~C+D
4. consecutive:
A~B~C
All four m a y be h e t e r o g e n e o u s ,
b u t only #1 (and s o m e t i m e s #4) will be
h o m o g e n e o u s . Rate p r o c e s s e s are defined in t e r m s of a rate, r , a n d a volume, V, u s u a l l y a m o l a r volume. T h u s , we have: 7.4.2.-
Homogeneous:
r = llVt - dnildt
Heterogeneous:
r = I/V f-
dVt/dt
w h e r e n i is initial mols, Vt is volume at time, t, a n d Vf is final volume. The fraction d e c o m p o s e d at a n y time is: 7.4.3.-
x ----" Vt / Vf
a n d this gives us:
390
7.4.4.-
d x / d t = k l {T}. f{x}
w h e r e kl is the rate c o n s t a n t for the reaction in 7.4.4. This e q u a t i o n is the general form for kinetics equations. F r o m the Kinetic Theory, w h e n a g a s e o u s s y s t e m goes from a n initial state to a final state, the r e a c t i n g species m u s t come close e n o u g h to react. At the m o m e n t of "joining", we have the "activated complex". By u s i n g this concept, we c a n obtain some general e q u a t i o n s useful to us. The c o n c e p t of the "activated complex" is illustrated in the following diagram:
The free e n e r g y of the activated complex, G*, is higher t h a n t h a t of the initial state. K* is the e q u i l i b r i u m c o n s t a n t of the activated complex, a n d k is the B o l t z m a n n c o n s t a n t , then, we c a n write t h e r m o d y n a m i c e q u a t i o n s as follows: 7.4.6.-
AG = RT In K* kl
= k T l h exp (-AG* IRT} = k T l h exp {AS* IR) exp (-AH*/RT)
w h e r e the s t a r (*) refers to the activated species. These e q u a t i o n s o u g h t to be familiar to Physical C h e m i s t r y s t u d e n t s .
391
F r o m t h e C l a u s i u s - C l a p y e r o n e q u a t i o n , we have: 7.4.7.-
Eo-
RT 2 d l n k l / d t
Eo
= AH*
+ RT
w h e r e Eo is a n i n t e r n a l energy. By defining a f r e q u e n c y factor as: 7.4.8.-
Z
= k T / h exp (-Eo*/RT)
we c a n s i m p l y b y m e a n s of 7.4.6. to: 7.4.9.-
kl
= Z exp (-Eo*/RT}
w h i c h is t h e AR_RHENIUS EQUATION for t h e r a t e t r a n s f o r m t h e above e q u a t i o n s into
general
constant,
k l. We c a n
e q u a t i o n s a s well, a n d u s e t h e m to
defme t h e v a r i o u s t y p e s of r e a c t i o n given above. This is given in t h e following table7.4. I0.-
RATE EQUATIONS FOR SOLID STATE REACTIONS
1. Simple n t h O r d e r kl nA ~
B+ C
2. Parallel R e a c t i o n s kl
Rate E q u a t i o n -dXA / d t = k l xn A Rate Equation..
A~B - d x A / d t = k lXA + k 2 XA
k2 {A~C} 3. C o n s e c u t i v e k~ k2 A~B
~C
-dxA/dt
= k l XA - k2 XB
392
These rate e q u a t i o n s c a n be u s e d for quite complicated reactions, b u t a specific m e t h o d or a p p r o a c h is needed. M a n y a u t h o r s have tried to devise m e t h o d s for o b t a i n i n g rate c o n s t a n t s a n d o r d e r s of reaction for given solid state reactions. None have b e e n wholly successful, except for F r e e m a n a n d Carroll (1948). The F r e e m a n a n d Carroll m e t h o d h a s b e e n s h o w n by F o n g a n d C h e n to be the only one w h i c h gives satisfactory a n s w e r s to k n o w n reactions, w h e t h e r zero order, 1st order, 2 n d order, or even higher. Even fractional o r d e r s of reaction m a y be determined. This m e t h o d c a n be u s e d with either DTA or TGA data. B. THE FREEMAN-CARROLL ME12-IOD APPLIED TO DTA DATA The following is a description of the F r e e m a n - C a r r o l l m e t h o d applied to DTA data. Consider the following DTA p e a k in which AT is plotted vs: time, t,
a
r e p r e s e n t a t i o n of w h i c h given as follows: 7.4.11.-
A DTA Peak
A
t
At a n y time, a
,,.
IF-
is the fraction d e c o m p o s e d while a 9 is the fraction w h i c h h a s
yet to react. We can set u p e q u a t i o n s as before: 7.4.12.-
da / d t
= k l (1- a )n
The first p a r t of the e q u a t i o n is the
= Z / + exp - E / R T (1- a )n
general
kinetic equation, from w h i c h it is
393
e a s y to o b t a i n t h e l a s t p a r t (as w e h a v e s h o w n ) . I f w e p e r f o r m t h e m a t h e m a t i c a l operations
of:
1) t a k e
the
naperian
log;
2) d i f f e r e n t i a t i o n ,
and
then
3)
i n t e g r a t i o n , w e o b t a i n t h e following e q u a t i o n : 7.4.13.-
=n(AIn(1-a)-E/RA(1/T)
Ainda/dt
If w e n o w set: A T / A = d(~ / d t a n d a 9 = A - a ( w h e r e A is t h e a r e a u n d e r t h e peak}, we can then obtain: 7.4.14.-
A(lnAT) = n(Alna,)
T h i s a l l o w s u s to plot:
- E/R
A(1/T)
A (In AT) / A (in a *)
vs: A ( 1 / T In a *) so a s to o b t a i n
a s t r a i g h t line. T h e s l o p e is E / R a n d t h e i n t e r c e p t is n ,
the o r d e r of reaction.
H a v i n g t h u s o b t a i n e d t h e a c t i v a t i o n e n e r g y a n d o r d e r directly, w e c a n t h e n c a l c u l a t e t h e r e a c t i o n rate. C. T H E F R E E M A N - C/~fl:(ROLL M E T H O D APPLIED TO TGA DATA In t h i s c a s e , w e d e f i n e o u r e q u a t i o n in t e r m s o f w e i g h t , w : 7.4.15.-
-dw/dt
= k l f(w)
As in t h e DTA m e t h o d , w e d e f i n e w e i g h t r e a c t e d i n t i m e , t, a s w t
a n d final
w e i g h t , w f . T h i s a l l o w s u s to d e f i n e w e i g h t t o b e r e a c t e d as: w = wt - wf . O u r w e i g h t f u n c t i o n is t h e n to b e d e f i n e d : 7 . 4 . 1 6 . - f(w) = w n w h e r e n is a s i m p l e i n t e g e r , r e p r e s e n t i n g t h e o r d e r of r e a c t i o n . T h u s , w e o b t a i n in t h e s a m e m a n n e r a s for t h e DTA d a t a : 7.4.17.-
- dw/dt
= Z e x p (-E/RT) w n
394
We now do the m a t h e m a t i c a l m a n i p u l a t i o n s in the order given above to obtain: 7.4.18.-
A (in (-dw/dt)) - E / R (A (l/T)) + n A In w
This allows u s to plot, as before:
A (In - d w / d t ) / A In w vs: A(I/T) / A In w .
However, in m a n y cases, it is easier to u s e a, the original weight, a n d calculate: (a - x) a n d d x / d t , w h e r e x is the fraction d e c o m p o s e d at time, t. T h e n we plot: 7.4.19.-
h (In dx/ht) / A {In {a-x)) vs: h (1 IT) / A In {a-x)
T h u s if we take a well defined curve from either DTA or TGA a n d find points on the curve, we can calculate all of the kinetic p a r a m e t e r s . Note t h a t the m a i n concept is to u s e the a m o u a t l e f t t o r e a c t at a n y given instant. In DTA, this w a s a* while in TGA, it w a s {a- x). Both t h e r m a l m e t h o d s give equally satisfactory results. 7.5.- DILATOME]~Y M e a s u r e m e n t of the t h e r m a l e x p a n s i o n of solids is called "dilatometry'. W h e n energy is applied to a solid, one of the r e s u l t s is t h a t the solid e x p a n d s in space. S u c h e x p a n s i o n r e s u l t s b e c a u s e the energy generally e n d s u p as "heat'. T h a t is- the lattice of the solid acquires i n c r e a s e d vibrational m o d e s w h i c h e x p a n d s the lattice. On a practical scale, dilatometry is u s u a l l y o b t a i n e d in linear fashion w h e r e i n the c h a n g e in u n i t length of a material c a u s e d b y one-degree c h a n g e in t e m p e r a t u r e is m e a s u r e d . Both volume c h a n g e a n d linear c h a n g e is e x p r e s s e d by: 7.5.1.-
(xv = I { 0 V / 0 T ) p
Vo
and
(XL = 1 { 0 L / 6 r ) p
Lo
where V is the volume a n d L is the length a n d V0 is the original volume a n d L0 is the original length. (~v is the volume t h e r m a l e x p a n s i o n coefficient a n d aL is
395
the linear thermal expansion coefficient. Obviously, 3 (1L = (IV (but only ff the material is cubic. That is, the s t r u c t u r e of the material is uniform in three dimensions). Both coefficients are ordinarily linear functions of temperature, t h a t is- a plot of expansion vs: t e m p e r a t u r e yields a straight line. By usi ng the average value of the linear coefficient of expansion, we get: 7.5.2.-
(IL = I .
L0
AT
where t~L an d AT are changes in length, L, a n d temperature, T, and L0 is the original length of the sample being m e a s u r e d . If a volume expansion is required, then m e a s u r e m e n t s in three s i m u l t a n e o u s dimensions are needed, a result experimentally difficult to achieve, to say the least. Even a slab of a single crystal does not completely solve the problem since thermal expansion in three dimensions is needed for the volume thermal expansion coefficient. The crystal h a s three (3) crystallographic axes and m a y have three (3) linear coefficients of expansion. Only if the crystal is cubic does one have the case where all three values of (1L are equal. Thus,
most
thermal
expansion m e a s u r e m e n t s
use
the
linear
expansion
coefficient method. This requires a rod of solid material and powders c a n n o t be m e a s u r e d by this method. Either the material is melted a n d cast into rod form or it is cut from a slab of material. Glass a n d metals are ideally suited to s u c h m e a s u r e m e n t , w h e r e a s inorganic and organic c o m p o u n d s are difficult to m e a s u r e at best. Single crystals of inorganic or organic c o m p o u n d s are required for the m o s t part, b u t the work of obtaining s u c h is sometimes a d a u n t i n g task. A suitable a p p a r a t u s is shown on the following following page as 7.5.3. Note t h a t only a m e a n s of holding one end of the sample b a r is needed while the sample is being heated. Most materials expand only a b o u t a small fraction of their actual dimensions. Because they expand less t h a n a micrometer, i.e.- one milh'onth of a meter, with a one-degree increase in temperature, m e a s u r e m e n t s
396
m u s t be m a d e by u s e of a highly sensitive device as the detector. Suitable m e a s u r e m e n t s are u s u a l l y m a d e by the following m e t h o d s : 7.5.4.- Suitable Detecting S y s t e m s for Dilametric M e a s u r e m e n t of Solids a. Microscope b. Dial gauge c. Telescope with Micrometer d. Strain gauge e. Interferometer f. Mirror reflection g. Lattice c o n s t a n t s via x-ray diffraction h. Sample density The MICROSCOPE m e t h o d {a) entails the u s e of a hot-stage w h i c h fits on the microscope. A calibrated eyepiece is needed
as well. By setting u p
and
controlling the t e m p e r a t u r e of the b a r u n d e r investigation, a series of lengths c a n be o b t a i n e d u s i n g the e q u a t i o n of 7.9.2. W h e n these p o i n t s are plotted a g a i n s t t e m p e r a t u r e , a straight line will be obtained. The slope of the line will be the linear coefficient of expansion, aLBoth the DIAL GAUGE {b) a n d TELESCOPE WI22-t MICROMETER (c) m e t h o d s are v a r i a n t s of the m i c r o s c o p e - m e t h o d {a). A t e m p e r a t u r e - c o n t r o l l e d furnace is needed a n d a physical s e t - u p where the DIAL-GAUGE or TELESCOPE WITH
397
MICROMETER can observe the change of length as a function of several settings of temperature. (~L is obtained as described before. Both the INTERFEROMETER m e t h o d (d) a n d the MIRROR REFLECTION (e) m e t h o d s use optical m e a n s to detect changes in linear expansion of the sample u n d e r test. The i n s t r u m e n t a t i o n is more complex a n d will not be described here. The other two methods, X-RAY LATI~CE CONSTANTS (f) a n d SAMPLE DENSITY (g) have not been employed to any great extent for determination of ~L a n d are only included for the sake of completeness. M o d e m commercial dilatometxic i n s t r u m e n t s use the electrical o u t p u t from a "strain-gauge". The he a r t of a strain gauge consists of a crystal (or sometimes a disc pressed from a powder) which is piezoelectric. The term, piezoelectric, is defined as the appearance of positive electric charge on one side of certain n o n c o n d u c t i n g crystals a n d negative charge on the opposite side w h e n the crystals are subjected to mechanical pressure. Piezoelectricity was discovered in 1880 by Pierre an d P a u l - J a c q u e s Curie, who found t h a t w h e n they c o m p r e s s e d certain types of crystals (including those of quartz, tourmaline, a n d Rochelle salt) along certain axes, a voltage w a s p r o d u c e d on the surface of the crystal. The next year, they observed the converse effect, the elongation of s u c h crystals u p o n the application of an electric current. Pressure on certain electrically ne ut r al crystals--those not having a center of s t r u c t u r a l symmetry- polarizes t h e m by slightly separating the center of positive charge from t h a t of the negative charge. Equal and unlike charges on opposite faces of the crystal result. This charge separation m a y be described as a r e s u l t a n t electric field a n d m a y be detected by an appropriate voltmeter as a potential difference, or voltage, between the opposite crystal faces. This p h e n o m e n o n , also called the piezoelectric effect, h a s a converse, i.e.- the production of a mechanical deformation in a crystal across which an electric field or a potential difference is applied. A reversal of the field reverses the direction of the mechanical deformation. This effect h a s been u s e d in microphones.
398
The advantage of us i ng a strain gauge w h e n m a k i n g thermal expansion m e a s u r e m e n t s lies in the fact t h a t a c o n t i n u o u s electrical signal can be obtained as the sample bar is being heated. A typical dilatometric r u n for a glass sample is shown in the following: 7.5.5.-
ii
200
I
400 ,ll
I
600 i
I
800
'--
1000
I
I
Glass Softening Point
L~I.~SS
Transition
Temperature
t
I
I
I
200
400
600
600
,
I I000
TEMPERATURE IN o C.
Note t h a t the linear coefficient of expansion, otL is obtained from the slope of the straight line. The glass softening point is also easily observed as is the glass transitional t e m p e r a t u r e (which is the point where the a m o r p h o u s glassy p h a s e begins its transition to a crystalline phase. These glass-points can also be u s e d to cross-check values obtained by the DTA method. It is possible for a glass to have more t h a n one linear coefficient of expansion. One s u c h case is shown in the following diagram, given as 7.5.6. on the next page.
399
7.5.6.-
1"4[ I
IThermal
!
Expansion of [Ba(PO 3 )2]n
1.2--
(-
~-0
1.0--
O .fi (J E
0.8
"-
0.6
--
LL .li, .1-:>.li
or) E EL X Ill
I~
0.4-0.2
- 115x
I 0 -7
in/in/~ C
I
--
I
0 0
I 100
i
I ZOO
I
I 300
i,,
i 400
!
i 500
I 600
Temperature in ~ This glass is polymeric a n d c o n s i s t s of b a r i u m m e t a - p h o s p h a t e units, i.e.[Ba(P03)2] n , polymerized to form long c h a i n s in the a m o r p h o u s state. Note t h a t three v a l u e s are shown. The first is the expected linear expansion, typical of m o s t glasses. In this case, there is a t e m p e r a t u r e r a n g e w h e r e the glass ceases to e x p a n d (between 3 0 0 a n d 3 8 0 ~ a n d is fiat. Above a b o u t 3 8 0 ~ a third value of ~L c a n be seen. Although this behavior is not typical for m o s t glasses, it does illustrate the fact t h a t a n a m o r p h o u s p h a s e c a n have m o r e t h a n one coefficient of expansion. Note also t h a t the softening point is not indicated in the diagram. Its value lies above 5 5 0 ~ well.
The s a m e is t r u e for o t h e r solids as
To illustrate this point, consider a typical metal. W h e n a b a r of s u c h m e t a l s are heated, t h e y e x p a n d in a linear m a n n e r , b u t m a y u n d e r g o a p h a s e t r a n s i t i o n as they r e a c h a critical t e m p e r a t u r e . This is s h o v m in the following diagram:
400
7.5.7.
IExpa,sio:O f various.MetalS withllTemperature,,, .... , ...... ] I
i
flll
l
I
aid
i
i
iii
i
i III
I i[11111
i i
Temperature i
i
ii
iiii
I
ii
i
ii
I
"
w-
In this case, a c h a n g e in s t r u c t u r e occurs. M a n y m e t a l s are elemental in n a t u r e a n d w h e n refined to a p u r e state have a cubic s t r u c t u r e . At s o m e criticai t e m p e r a t u r e (def'med b y the n u m b e r of m e t a l electrons per a t o m p r e s e n t a n d the type of metallic bonding), a c h a n g e to a hexagonal form occurs. This is s h o w n in the following diagram. Note t h a t a simple shift in u n i t cell d i m e n s i o n is all t h a t is required for the crystal s t r u c t u r e c h a n g e to take place. 7.5.8.-
ICubic 'to hexagonal Transformation I
401
Observe also that increased thermal energy is all that is required for the shift to take place. Such change occurs well below the melting point of the metal. Dilatometric m e a s u r e m e n t is the only way that such change was originally discovered and the use of x-ray analysis was needed to confirm the exact n a t u r e of the change measured. 7.6.- Th,ermometry Thermometry is the science of measuring the temperature of a system or the ability of a system to transfer heat to another system. Temperature m e a s u r e m e n t is important to a -,vide range of activities, including manufacturing, scientific research, and medical practice. Thermometry relates to the dilatrometric m e a s u r e m e n t in that the expansion of a gas, liquid or solid is used to determine temperature. The accurate m e a s u r e m e n t of temperature has developed relatively recently in h u m a n history. The invention of the thermometer is generally credited to Galileo. In his instrument, built about 1592, the changing temperature of an inverted glass vessel produced the expansion or contraction of the air within it, which in t u r n changed the level of the liquid with which the vessel's long, openmouthed neck was partially filled. This general principle was perfected in succeeding years by experimenting with liquids such as mercury and by providing a scale to m e a s u r e the expansion and contraction brought about in such liquids by rising and falling temperatures. By the early 18th century as m a n y as 35 different temperature scales had been devised. The German physicist, Daniel Gabriel Fahrenheit, in 1700-30 produced accurate mercury thermometers calibrated to a s t a n d a r d scale that ranged from 32, the melting point of ice, to 96 for body temperature. The unit of temperature (degree) on the Fahrenheit scale is 1 / 1 8 0 of the difference between the boiling (212) and freezing points of water. The first centigrade scale (made up of 100 degrees) is attributed to the Swedish astronomer Anders Celsius, who
402
developed it in 1742. Celsius u s e d 0 for the boiling point of w a t e r a n d 100 for the melting point of snow. This w a s later inverted to p u t 0 on the cold e n d a n d 100 on the hot end, a n d in t h a t form it g a i n e d w i d e s p r e a d use. It w a s k n o w n simply as the centigrade scale until in 1948 the n a m e w a s c h a n g e d to h o n o r Celsius. In 1848 the British physicist William T h o m p s o n (later Lord Kelvin) p r o p o s e d a s y s t e m t h a t u s e d the degrees t h a t Celsius u s e d , b u t w a s keyed to a b s o l u t e zero (-273.15 ~ i.e.- ~
the u n i t of this scale is now k n o w n as the kelvin,
The R a n k i n e scale employs the F a h r e n h e i t degree keyed to absolute
zero (-459.67 ~
i.e.- ~
Any s u b s t a n c e t h a t s o m e h o w c h a n g e s with alterations in its t e m p e r a t u r e c a n be u s e d as the basic c o m p o n e n t in a t h e r m o m e t e r . G a s t h e r m o m e t e r s w o r k b e s t at very low t e m p e r a t u r e s . Liquid t h e r m o m e t e r s are the m o s t c o m m o n type in use. T h e y are simple, inexpensive, long-lasting, a n d able to m e a s u r e a wide t e m p e r a t u r e span. The liquid is a l m o s t always m e r c u r y , sealed in a glass t u b e with nitrogen gas m a k i n g u p the rest of the volume of the tube. Electrical-resistance t h e r m o m e t e r s characteristically u s e p l a t i n u m a n d operate on the principle t h a t electrical r e s i s t a n c e varies with c h a n g e s in t e m p e r a t u r e . T h e r m o c o u p l e s are a m o n g the m o s t widely u s e d i n d u s t r i a l t h e r m o m e t e r s . T h e y are c o m p o s e d of two wires m a d e of different m a t e r i a l s joined together at one e n d a n d c o n n e c t e d to a v o l t a g e - m e a s u r i n g device at the other. A t e m p e r a t u r e difference b e t w e e n the two e n d s c r e a t e s a voltage t h a t c a n be m e a s u r e d a n d t r a n s l a t e d into a m e a s u r e of the t e m p e r a t u r e of the j u n c t i o n end. The bimetallic strip c o n s t i t u t e s one of the m o s t trouble-free a n d d u r a b l e t h e r m o m e t e r s . It is simply two strips of different m e t a l s b o n d e d together a n d held at one end. W h e n heated, the two strips e x p a n d at different rates, r e s u l t i n g in a b e n d i n g effect t h a t is u s e d to m e a s u r e the t e m p e r a t u r e change. O t h e r t h e r m o m e t e r s operate b y s e n s i n g s o u n d waves or m a g n e t i c conditions a s s o c i a t e d with t e m p e r a t u r e
changes.
Magnetic t h e r m o m e t e r s
increase
in
efficiency as t e m p e r a t u r e decreases, w h i c h m a k e s t h e m extremely useful in m e a s u r i n g very low t e m p e r a t u r e s with precision. T e m p e r a t u r e s c a n also be
403
mapped, u s i n g a technique called t h e r m o g r a p h y t h a t provides a graphic or visual representation of the t e m p e r a t u r e conditions on the surface of an object or land area. P h o s p h o r s are now being u s e d in this application. 7.7.- APPLICATION OF DILATOMETRY TO PLASTIC MATERIAI~ The ter m "plastic" refers to t h a t class of materials which is organic in nature. That is, plastics are composed of hydrogen, carbon, nitrogen and sometimes fluorine, i.e.- they are hydrocarbons. S u c h materials are actually "polymers" composed of monomeric u n i t s which are c a u s e d to join to form r a t h e r large uniform molecules having molecular weights as high as 100,000 or more. Plastics or polymers have found a variety of e n d - u s e s in our economy. In addition to containers s u c h as bottles for beverages, plastics are u s e d in all sorts of p r o d u c t s a n d polymers have been developed t h a t are stronger a n d more flexible t h a n m a n y metals. For the m o s t part, plastics are m a n - m a d e since very few plastics are natural, i.e.- n a t u r e - m a d e . Natural plastics include large molecular-weight proteins a n d similar molecules. Man-made plastics can be classified as either thermoplastic or thermosetting. Each class derives its physical properties from the effects of application of heat, the former becoming "plastic" (that is- it becomes soft a n d tends to flow) while the latter becomes less "plastic" and tends to remain in a softened state. This difference in change of state derives from the actual n a t u r e of the chemical b o n d s in the polymer. Thermoplastic pol:yzners generally consist of molecules composed of m a n y monomeric units. A good example is t h a t of polyethylene where the monomeric unit is: -(CH2-CH2)- . The molecule is linear a n d the polymer consists of m a n y units tied together in one long string. In contrast, thermosetting polymers consist of c r o s s - l i n k e d u n i t s where the crosslinking is three-dimensional. That is, the molecules are linked together in three dimensional-space:
-(CH-CH)I I -(CH-CH)-
404
This difference in spatial characteristics has a profound effect upon the polymer's physical and chemical properties. In thermoplastic polymers, application of heat causes a change from a solid or glassy (amorphous) state to a flowable liquid. In thermosetting polymers, the change of state occurs from a rigid solid to a soft, rubbery composition. The glass transition temperature, Tg, and the coefficient of expansion have a profound effect on the performance and reliability of m a n y polymer applications. Although Tg is usually quoted a n d accepted as a single value, the transition usually occurs within a range of temperatures. Factors such as intra-chain stiffness, polar electromagnetic forces and co-polymer compatibility (when two or more polymers are blended together to improve physical properties) can affect the size of the glasstransition region. As shown in the following diagram, property changes occur throughout a temperature region which depends upon the type of polymer(s):
It should be clear that the point where a polymer shifts from a glassy, hard state to a soft, rubbery one is not well defined but occurs within a b a n d of temperatures. In contrast, it is easy to define Tg as a single temperature point
405
for glasses a n d m o s t ceramic materials. We have already described how Tg is m e a s u r e d . Similar m e t h o d s are u s e d w h e n plastics or organic m a t e r i a l s are involved. DSC is the m e t h o d m o s t often employed since it gives b o t h e n t h a l p y a n d h e a t c a p a c i t y d a t a from the s a m e analysis. 7,8- OPTICAL MEASUREMENTS OF SOLIDS In t e r m s of their optical properties, all solids fall into one of two classes. Either t h e y are t r a n s p a r e n t to light (here we are restricting the t e r m "light" to visible radiation) or t h e y are opaque. In the latter case, all of the r a d i a t i o n m a y be reflected. However, m o s t solids reflect some w a v e l e n g t h s a n d a b s o r b others. This is the condition t h a t we call "color". If all visible w a v e l e n g t h s are absorbed, the solid is said to be "alack" while reflectance of all visible w a v e l e n g t h s r e s u l t s in a "white" solid. We i n t e n d to s h o w how "color" is m e a s u r e d b u t first m u s t define the n a t u r e of "light". A. DEFINING LIGHT Light is c o m p o s e d of p h o t o n s
(which are individual energy b u n d l e s ) t h a t
p r o p a g a t e t h r o u g h space. The correct t e r m for light is electromagnetic radiation. We u s e the t e r m "light" to refer to t h o s e p h o t o n s w h i c h we c a n see. "Dark" refers to the a b s e n c e of-visible p h o t o n s (You m a y be i n t e r e s t e d to k n o w t h a t a p h o t o n is now r e g a r d e d as a e n e r g y carrier b e t w e e n f u n d a m e n t a l particles, i.e.leptons s u c h as p r o t o n s a n d neutrons). Light travels at a c o n s t a n t speed, i.e.3.0 x10 I ~ m e t e r s / s e c o n d , t h r o u g h a v a c u u m (a s p a c e w h e r e no m a t t e r exists). W h e n m a t t e r is present, its speed is diminished, b u t is still c o n s t a n t . Since the speed of light is c o n s t a n t , individual p h o t o n s c a n v a r y only in energy, a s t a t e w h i c h r e s u l t s in differences in their wavelength. T h a t is, a p h o t o n ' s energy is m a n i f e s t e d as a specific wavelength. O u r m a i n c o n c e r n will be t h a t of "color", w h i c h is the science of m e a s u r i n g w h a t type of p h o t o n s are reflected a n d t h o s e t h a t are a b s o r b e d b y a solid. "What this m e a n s is t h a t color is d e t e r m i n e d b y w h i c h p h o t o n s , in a s t r e a m of p h o t o n s h a v i n g v a r i o u s energies, are either reflected or a b s o r b e d b y the solid. This m e c h a n i s m implies s o m e sort of
406
interaction between e a c h individual p h o t o n a n d the electrons c o m p o s i n g the solid. P h o t o n s (i.e.- electromagnetic energy) c a n vary in wavelength from: 7 - r a y s = 1 0 12 m e t e r s x-rays = 1 0 I 0 m e t e r s ultraviolet = 10 8 m e t e r s visible = 10 .6 m e t e r s infrared radiation = 10 -4 m e t e r s microwaves = 10 .2 m e t e r s radio - 102 to 104 m e t e r s where the values given are averages of the s p r e a d of wavelengths. Note t h a t radio waves can be several miles long. But, since light travels at 186,000 m i l e s / s e c . , t r a n s m i s s i o n to a n y point on E a r t h is nearly i n s t a n t a n e o u s . The frequency
varies
from
about
105
cycles/second
(radio
waves)
to
1020
cycles / s e c o n d (7 -rays). The relationship b e t w e e n
electromagnetic
radiation
and matter
(solids) is
intertwined in the so-called "space-time" p h e n o m e n o n . All solids em/t p h o t o n s , even yourself. The concept of "absolute zero" lies in the fact t h a t no p h o t o n s are emitted at 0 ~ K. As the t e m p e r a t u r e rises, a s p e c t r u m of p h o t o n energies is emitted, as s h o w n in the following diagram, given as 7.8.1. on the next page. This
diagram
shows
the
radiation
emitted
by
"black-bodies"
at
specific
t e m p e r a t u r e . A b l a c k - b o d y is one t h a t h a s a u n i f o r m t e m p e r a t u r e over all of its surface. One w a y to m a k e a b l a c k - b o d y is to form a n hollow e n c l o s u r e a n d to h e a t it to a given t e m p e r a t u r e . If a small hole is m a d e in the side of the enclosure, radiation characteristic of the t e m p e r a t u r e will be emitted. It s h o u l d be clear t h a t all bodies (even y o u r own) radiate p h o t o n s in the infrared r a n g e of energies. Yours is similar to t h a t of the e a r t h a n d p r o b a b l y p e a r s n e a r to 10.0 m i c r o n s or 10,000 A. If you place y o u r h a n d on y o u r face, you feel w a r m t h b e c a u s e the emitted p h o t o n s are r e a b s o r b e d b y y o u r h a n d .
407
Nonetheless, o u r p r i m a r y interest lies in the 0.4 to 0.7 m i c r o n range, w h i c h we call the visible p a r t of the electromagnetic s p e c t r u m . Note t h a t even bodies at liquid-air
temperatures
wavelength, i.e.-
emit
I00,000 and
t e m p e r a t u r e of 300 ~
photons
between
10
and
100
microns
in
106 A in wavelength. The e a r t h itself at a
h a s a n errdssion b e t w e e n a b o u t 2 0 , 0 0 0 a n d 3 0 0 , 0 0 0 A
408
in wavelength, i.e.- 2 p. a n d 3 0 0 p. Light itself h a s a specific wavelength m e a s u r e d in A n g s t r o m s (1]~ = 0 . 0 0 0 0 0 0 0 0 0 1 m e t e r s = 0 . 0 0 0 0 0 0 0 0 0 0 0 3 feet). Sir Isaac Newton first d e m o n s t r a t e d the s e p a r a t i o n of wavelengths (colors) of s u n l i g h t in 1675 b y u s e of a glass prism. The wavelengths to w h i c h the h u m a n eye r e s p o n d s is called the "visible spectrum". We see each of these wavelengths of light as a perceived color. Additionally, it w a s found t h a t "white" is a compilation of all of the colors while "black" is an a b s e n c e of said colors. P h o t o n s having the highest energy are violet in color while the lowest energy ones are those we call deep-red. The intensity, or "brightness" of light is simply the n u m b e r s of p h o t o n s r e a c h i n g the eye at a n y given m o m e n t . On either side of the visible s p e c t n u n are "ultraviolet" a n d "infrared" wavelengths. The S u n itself r a d i a t e s t h r o u g h o u t the visible spectaum~ a n d far into the ultraviolet a n d infrared r a n g e s as well. The
following diagram,
shows
the
Sun's
radiation,
including
the visible
s p e c t r u m which e n c o m p a s s e s the 4 0 0 0 A to 7 0 0 0 A range of wavelengths. 7.8.2.i00
IThe . Visible . Spectrum . .
and . the Sun's
RadiationI
Ultraviolet Violet Blue BluegreenGreenYellowOr~leRed DeepRed Infrared
~ r.----7--i i
75
~B
i I
i i i i i i l i..i
'~ 50 --,-.-4
25 0
--"
i i i
8000
I
:1
i i
..
Broadband Emission of the Sun Not Attenuated by the Earth's Atmosphere, i.e.- 10,000 ~ -
I
I
Visible Spectrum
l
I
I
I
~-' . I
I
4000 5000 6000 Wavelength of Photons in Angstroms
I
7000
I
8000
It is this range t h a t we u s u a l l y call "daylight". Note the progression of h u e s as
409
we move from violet to deep red colors. Although the S u n radiates wavelengths as small as 2 0 / i and as large as 25,000 A, most of the energy is concentrated between 3000 and 10,000 A. Attenuation by the Earth's atmosphere (ozone in particular) causes the energy to peak near to 6500/k. (What this m e a n s is that if we have a hot "oody" at 6500 ~ (~ = ~ + 273) it would look like the S u n at noon).The actual color temperature of the S u n is about 10,000 ~ but it appears to us to be about 6500 ~ due to scattering of light within the atmosphere. It is n o t h a p p e n s t a n c e that the h u m a n eye responds exactly to the same wavelength intensities as those of the noonday Sun. In other words, m a n k i n d was born, and has evolved, u n d e r sunlight and his eyes have adapted to sunlight intensity, also known as "Daylight". The relative response of the h u m a n eye is shown in the foUowing diagram: 7.8.3.IThe Human Eye Sensitivity Curve i i i
Ul.~tra~Jolet Violet Blue Bluegreen Green Yellow Orange Red Deep Red Infrared
100 75
-
50
" f
25
-
i i
I
TM
o
aooo
I
//
Spectrum .
~'
4000 5000 6000 7000 Wavelength of Photons in Angstroms
I
1
8000
Note that the eye response is greatest in the green and yellow regions of the spectrum, and that response to blue and red wavelengths is m u c h lower. B. MEASUREMENT OF COLOR In order to m e a s u r e color, we first need to define how color is perceived, what is
410
perceived, a n d the factors involved in perception of color. First of all, "color" is a result of p h o t o n s striking the h u m a n eyeball, specifically the retina, a n d c a u s i n g a r e s p o n s e which we interpret as color. Color arises b e c a u s e each p h o t o n h a s its own energy, i.e.- its own wavelength. Color is perceived w h e n p h o t o n s strike the r e t i n a of the eye a n d c a u s e electrical activity in the optic nerve. In order to define the n a t u r e of a photon, we need to consider exactly w h a t light is a n d how it interacts with matter. This p r o b l e m h a s been s t u d i e d for m a n y centuries by various investigators a n d c o n t i n u e s to be s t u d i e d by c o n t e m p o r a n e o u s scientists. C.-THE NATURE OF LIGHT Nowadays, we k n o w t h a t light is c o m p r i s e d of "photons", w h i c h are quantized waves having some of the properties of particles. The concept of p h o t o n s with wave properties h a s its roots in the s t u d y of optics a n d optical p h e n o m e n a . Until the middle of the 17th century, light w a s generally t h o u g h t to consist of a s t r e a m of some sort of particles or corpuscles e m a n a t i n g from light sources. Newton a n d m a n y other scientists of his day s u p p o r t e d the idea of the c o r p u s c u l a r theory of light. It w a s Newton in 1703 w h o s h o w e d t h a t "ordinary" s u n l i g h t could be dispersed into its c o n s t i t u e n t colors by a prism, b u t the p h e n o m e n o n w a s not clearly g r a s p e d at t h a t time. Significant e x p e r i m e n t s on the n a t u r e of light were carried o u t by: I) Fresnel a n d T h o m a s Young (1815) on interference a n d diffraction respectively 2) Maxwell in 1873 who p o s t u l a t e d t h a t an oscillating electrical circuit s h o u l d radiate electromagnetic waves 3) Heinrich Hertz in 1887 who u s e d a n oscillating circuit of small d i m e n s i o n s to p r o d u c e electromagnetic waves which h a d properties of light waves
all of the
4) Einstein in 1905 who explained the photoelectric effect (He did so by extending a n idea p r o p o s e d by Planck five years earlier to p o s t u l a t e t h a t the energy in a light b e a m w a s c o n c e n t r a t e d in "packets" or photons..
411
The wave picture w a s r e t a i n e d in t h a t a p h o t o n w a s c o n s i d e r e d to have a f r e q u e n c y a n d t h a t the energy of a p h o t o n w a s proportional to its frequency). We c a n s u m m a r i z e all of the above r e s e a r c h carried o u t over the last two c e n t u r i e s in t h a t a p h o t o n is a q u a n t u m of r a d i a t i o n a n d a carrier of force b e t w e e n particles, w h e r e a s a n electron is a q u a n t u m of m a t t e r . Now, let u s e x a m i n e the m o r e m u n d a n e
a s p e c t s of light m e a s u r e m e n t including color
measurement. D.- ABSORBANCE, REFLECTIVITY AND TRANSM!'ITANCE. W h e n a b e a m of p h o t o n s strikes a solid, specific i n t e r a c t i o n s t a k e place w h i c h c a n be related to the Q u a n t u m Theory. T h e s e i n t e r a c t i o n s have b e e n m e a s u r e d in the p a s t a n d certain f o r m u l a s have b e e n found to apply. According to HUYGHEN'S principle of electromagnetic r a d i a t i o n s c a t t e r i n g , w h e n p h o t o n s come into close c o n t a c t with a solid, the electric a n d m a g n e t i c field vectors of the incident p h o t o n s couple with those of the electrons a s s o c i a t e d with the a t o m s c o m p r i s i n g the solid. The following p r e s e n t s s o m e of t h e s e f o r m u l a s applicable to c o n c e p t s given here: 7.8.4.- TERMINOLOGY APPLICABLE TO OPTICAL PROPERTIES a. A b s o r b a n c e :
A = logl/T=
b. T r a n s m i t t a n c e :
T = I / Io
c. Absorptivity:
II -- A / bc (A is m e a s u r e d absorption; b is the
logIo/ I ( I is m e a s u r e d intensity; Io is original intensity) optical p a t h - l e n g t h ; c is the m o l a r concentration)
d. Reflection:
Reflectivity -- spectral reflection, i.e.- at specific angles Reflectance = diffuse reflection, i.e.- s c a t t e r e d radiation
412
e. Intensity:
I is defined as the energy / u n i t a r e a of a b e a m of electromagnetic radiation.
This interaction leads to at least four (4) c o m p o n e n t s , namely: R- the radiation
reflected, A- the radiation a b s o r b e d , T- the radiation t r a n s m i t t e d , a n d S - the radiation s c a t t e r e d . A depiction of these interactions is given in the following diagram:
The original intensity of the radiation is defined as Io. A p a r t of the intensity is absorbed, a n o t h e r p a r t is t r a n s m i t t e d , still a n o t h e r p a r t is scattered, a n d a p a r t of the total intensity is reflected. The c o m p o n e n t s , S a n d T, are p r o c e s s e s which are independent of the wavelength (frequency) of the incident p h o t o n s , w h e r e a s R a n d A are primarily wavelength dependent. It is here t h a t the factor of "color" arises. The e x a c t a m o u n t of energy extracted from Io by each process is a complex set of variables d e p e n d i n g u p o n the type a n d mrrm~gement of a t o m s c o m p o s i n g the solid.
413
To simplify t h e s e concepts, consider a n optically h o m o g e n e o u s thin film. By optically h o m o g e n e o u s , we m e a n one t h a t is thin e n o u g h so t h a t no s c a t t e r i n g c a n occur. If a b e a m of p h o t o n s is incident to the surface at a given angle (but less t h a n t h a t where all of the b e a m is t r a n s m i t t e d - the so-called Brewster angle), p a r t of the b e a m will be reflected a n d p a r t will be absorbed, as s h o w n in t h e following:
The reflectance, R, is a c o n s e q u e n c e of the difference in refractive indices of the two media, (1} - air, a n d (2}- the s e m i - t r a n s p a r e n t t h i n film. The a m o u n t of a b s o r p t i o n is a function of the n a t u r e of the solid. Obviously, the a m o u n t t r a n s m i t t e d , T, is d e t e r m i n e d b y b o t h R a n d A. In this case, A, the absorbmaee, is defined as: 7.8.7.-
A ~ {1- R} - T
a n d the original b e a m intensity, Io ~ 1.00, is d i m i n i s h e d according to the Beer-
Lambert law, vis7.8.8.-
A = lnlo / I = Ecl
414
w h e r e 1 is t h e p a t h l e n g t h (depth of film traversed), E is a m o l a r e x t i n c t i o n
coefficient
of t h e
absorbing
species,
and
c is t h e
concentration
of t h e
a b s o r b i n g species. A l t h o u g h we h a v e s h o w n b u t one reflection a t X, a n o t h e r is e q u a l l y likely to o c c u r a t Y a s well. T h i s p r o b l e m of m u l t i p l e reflections w a s w o r k e d o u t b y Bode (1954). We will s h o w o n l y t h e r e s u l t s of his w o r k a n d u s e it to prove t h e validity of t h e e q u a t i o n of 7.8.7. for t h e c a s e of t h e h o m o g e n e o u s t h i n film. Consider the energy interactions which occur when a p h o t o n
s t r i k e s a solid.
The t i m e f r a m e of i n t e r a c t i o n is a b o u t 10-18 s e c o n d s : 7.8.9.-
S p e e d of p h o t o n = v -- 1010 cm. / sec. D i s t a n c e b e t w e e n lattice p l a n e s = d = 10 -8 c m . = ~ 1 A Time for p h o t o n to t r a v e r s e lattice = d / v = ~ 10-18 s e c o n d s
The fact t h a t t h e p h o t o n does t r a v e r s e t h e lattice p l a n e s does n o t m e a n t h a t t h e p h o t o n will b e a b s o r b e d or even s c a t t e r e d b y t h e solid. T h e r e f l e c t a n c e of t h e photon
is a f u n c t i o n of t h e n a t u r e
of t h e c o m p o s i t i o n a l s u r f a c e , w h e r e a s
a b s o r p t i o n d e p e n d s u p o n t h e interior c o m p o s i t i o n of t h e solid. A " r e s o n a n c e " condition
must
exist before
the photon
can
transfer
e n e r g y to t h e solid
( a b s o r p t i o n of t h e photon). In t h e following, we s h o w t h i s r e s o n a n c e c o n d i t i o n in g e n e r a l t e r m s of b o t h R & A. 7.8. I0.- ENERGY TRANSFER TO A SOLID BY A PHOTON ENERGY EXAMPLES
R
A
High
Moderate
"Colored" solid
Low
High High
Very High
"Black" solid
High
Low
Nfl
"White" solid
Low
Low
Nil
TRANSFER .
.
.
.
.
Heat transfer
.
.
.
.
.
.
415
This r e s u l t
defines a b s o r p t i o n of light in t e r m s
of b o t h reflectance
and
absorption. It is well to note t h a t either one or the o t h e r (or both) are required p h e n o m e n a in order for a p h o t o n to interact with a solid. T h u s , w h e n b o t h R & A values are high, we s a y the solid is colored. If either R or A is high, a n d the o t h e r value is low, t h e n we have either a white solid or a b l a c k solid. As a n example of controlled absorption, consider the case of a pigment. It is quite c o m m o n to a d d controlled a m o u n t s of a t r a n s i t i o n m e t a l to a t r a n s p a r e n t solid to form a n inorganic pigment. In one s u c h case, we a d d ~ 1% of c h r o m i u m oxide to a l u m i n u m oxide to o b t a i n a p i n k solid, i.e.- "ruby". The Cr3+ ion in the A120 3 lattice a b s o r b s b l u e a n d green light a n d reflects or t r a n s m i t s m o s t l y the red wavelengths. It s h o u l d be clear, then, t h a t b o t h processes, R & A, are wavelength d e p e n d e n t . T h a t is, t h e y d e p e n d u p o n the energy of the photon(s) striking the solid. E.- MEASUREMErr
OF COLOR
Having defined the n a t u r e of a p h o t o n a n d how it i n t e r a c t s with m a t t e r , we c a n now proceed to describe a m e t h o d to m e a s u r e color. We find t h a t even t h o u g h o u r vision is sufficient to categorize color as a gross feature, we still n e e d to be able to m e a s u r e small differences of color. One m e t h o d , u s e d in the past, w a s to a s s e m b l e a series of s a m p l e s having small b u t observable differences in color, a n d t h e n c o m p a r e an u n k n o w n to these. B e c a u s e the h u m a n eye is a s u p e r b color i n s t r u m e n t , this a p p r o a c h w a s perfectly feasible. This m e t h o d u s e d the so-called the Munsell Color Tree as the s t a n d a r d samples. But, it w a s b a s e d on being able to provide reproducible color s w a t c h e s from reproducible pigments. You c a n imagine the p r o b l e m s a s s o c i a t e d in doing so. However, the r e t i n a does not r e s p o n d equally to all wavelengths. For equal energies, a yellow-green light p r o d u c e s a m u c h stronger r e s p o n s e in the h u m a n eye t h a n a red or blue light. T h u s , we s a y t h a t the yellow-green light is '"orighter" t h a n the red or blue lights. This is called the l u m i n o s i t y r e s p o n s e of the eye. However, the d a r k - a d a p t e d h u m a n eye does n o t r e s p o n d to light in the
416
s a m e w a y t h a t it does for bright light. The former is called "scotopic" a n d the latter, "photopic". The following d i a g r a m s h o w s b o t h the photopic a n d scotopic r e s p o n s e curves for the h u m a n eye7.8.11.-
I LUMINOSCITY RESPONSE
c-
= (1) 1 0 0 (1) :p-
~:
9 80
--
-
Q
r 0 r~
"v"
OF THE HUMAN EYEI
STANDARDI
PHOTOPIC
THE OBSERVER
60SCOTOPIC ~ - ~
4020-
rv
0 -
000
4500
5000
5500
6000
6500
Wavelength, Apparently, photopic vision relates to "sunlight", to w h i c h the h u m a n
had
a d a p t e d t h r o u g h evolution, while scotopic vision related to "moonlight", t h a t is, s u n l i g h t modified b y reflection from the Moon's surface. However, it w a s soon discovered t h a t the color r e s p o n s e s of individuals were not exactly the same. E a c h individual "sees" a color slightly differently from a n y o n e else. We have l e a r n e d to discriminate b e t w e e n colors b u t no one k n o w s exactly w h a t a n y o n e else actually sees. Once this fact w a s realized, it w a s u n d e r s t o o d t h a t a n average of w h a t e a c h p e r s o n s a w w o u l d have to be m a d e if a s t a n d a r d s y s t e m w a s to be formed a n d p r o m u l g a t e d . This led to the c o n c e p t of the " S t a n d a r d Observer". T h u s , the r e s e a r c h required to define a n d m e a s u r e color took a completely different p a t h from the original m e t h o d s s u c h as the Munsell Color Tree.
417
I. The S t a n d a r d Observer By m e a s u r i n g a n u m b e r of individual observers, we c a n obtain w h a t we call a " S t a n d a r d L u m i n o s i t y Curve". Photopic vision p e a k s at 5 5 0 0 A w h e r e a s scotopic vision p e a k s at 5 2 0 0 A. In this case, the relative r e s p o n s e of the o b s e r v e r s are s u m m e d into a r e s p o n s e called "I'HE STANDARD OBSERVER" a n d is normalized for easier usage. Now, let u s e x a m i n e the effects of colors (chroma) as perceived b y the h u m a n eye. Keep in m i n d t h a t e a c h p e r s o n perceives "color" s o m e w h a t differently from other persons.
II. The N a t u r e of C h r o m a The visible s p e c t r u m e x t e n d s from a b o u t 4 0 0 0 A to 7 0 0 0 A. We find t h a t the eye acts as a n i n t e g r a t i n g instlnament. T h u s , two colors m a y a p p e a r equal to the eye even t h o u g h
one is m o n o c h r o m a t i c
light a n d
the o t h e r h a s
a band
of
wavelengths. This is s h o w n in the following diagram: 7.8.12.-
Monochromatic Green Lines
.II=
C--
nV
4000
5000
6000
In this case, we have plotted a *spectxum" of colors w h i c h s h o w s the intensity, or n u m b e r s , of p h o t o n s p r e s e n t in a n y given "color" or wavelength (given in A). In the above diagram, we m a y see the s a m e color, b u t the p h o t o n w a v e l e n g t h s
418
are m u c h different. T h u s , we n e e d a m e t h o d t h a t c a n d i s c r i m i n a t e b e t w e e n s u c h cases. It w a s Newton, u s i n g a glass p r i s m plus slits, who first d e m o n s t r a t e d t h a t s u n l i g h t c o n s i s t e d of colors or c h r o m a . S u b s e q u e n t w o r k t h e n s h o w e d t h a t colors could be duplicated b y mixing the three primaries, red, green a n d blue to o b t a i n the v a r i o u s c h r o m a , including s h a d e s of "white". Actually, t h e s e s h a d e s involved the l u m i n o u s intensity, t h a t is- the a m o u n t of light falling u p o n a surface. Let u s first define s o m e of the t e r m s of m e a s u r e m e n t of l u m i n o s i t y a n d t h e n proceed to d e t e r m i n e how to m e a s u r e the c h r o m a , or chromaticity. The a c t u a l t h e o r y is complicated a n d long so t h a t we shall p r e s e n t only a simplified version of the whole theory. III. Intensity a n d S c a t t e r i n g Consider a t h i n fiat plate w h i c h h a s no absorption,
only reflectance a n d
t r a n s m i t t a n c e . We will find t h a t light falling u p o n its surface with a certain i n t e n s i t y h a s a l u m i n a n c e , L, while the l i g h t t r m a a m i t t e d is d e f i n e d a s H, the exittance, or emittance. H will e q u a l L if no a b s o r p t i o n t a k e s place or if there is no s c a t t e r i n g at the surface of the thin plate. distances, a certain a m o u n t of ~ a t t e r h a g
However, even at atomic
does take place. We fund t h a t two
types of s c a t t e r i n g are possible. If the surface is perfectly s m o o t h on a n atomic level, t h e n a light wave would be b a c k - s c a t t e r e d along the s a m e exact path, a n d we w o u l d have a p e r f e c t diffuser, w h i c h we call So . However, t h e r e is always a n angle a s s o c i a t e d with the scattering, w h i c h we call Sa (where (~ is defined as the s c a t t e r i n g angle), a n d we have a n imperfect diffuser. This is s h o w n in the following diagram, given as 7.8.13. on the next page. If we view the thin plate from the left w h e r e it is illuminated with intensity, L, w h a t we see is the b a c k - s c a t t e r e d light, or light diffusion from the surface. If the plate is a perfect diffuser, t h e n we will see a n exact a m o u n t of L s c a t t e r e d b a c k along the s a m e p l a n e as L as a diffuse c o m p o n e n t . Note t h a t we are not s p e a k i n g of reflection (which is a n entirely different m e c h a n i s m w h e r e the
419
wavelength of the light is affected) b u t of s c a t t e r i n g (where the light is a b s o r b e d , t h e n r e e m i t t e d at the s a m e wavelength). For s c a t t e r i n g b y a perfect diffuser, Lo s h o u l d equal Io / S o . However, this is never the case. W h a t we fund is t h a t there is a n a n g u l a r d e p e n d e n c e of scattering, a n d that: 7.8.14.-
I =
la/Sa
= I a / (So cosr
w h e r e r is the angle of scattering. Therefore, H, the light t r a n s m i t t e d , does n o t equal L. If we define ~ as the flux of light, i.e.- the n u m b e r of p h o t o n s incident per second, we Fund: 7.8.15.-
H=
r
Sa = r
coscz
where: ~ = 4n I (point source) = n I (fiat surface)
The i n t e n s i t y u n i t s for ~ are related to a p r i m a r y r a d i a t i o n source, the candela, Cd. The definition of a c a n d e l a is: 7.8.16.-
CANDELA: a unit of Itm~nous intensity, defined as 1 / 6 0 of the
luminous tnter~stty per square centimeter of a black-body radiator operating at the temperature of freezing platinum (1772 ~ Formerly k n o w n as a candle. The unit is abbreviated as: Cd
420
This gives u s the following i n t e n s i t y units: 7.8.17.-
INTENSITY UNITS
1.0 Cd (at a one-foot distance)
L/n
(foot-lamberts)
H / n (lumens) T h u s , we have two u n i t s of m e a s u r e m e n t
of intensity.
One is related to
s c a t t e r i n g from a surface, L, i.e.- in foot-lamberts a n d the o t h e r is related to emittance, H, i.e.- in l u m e n s per s q u a r e foot. Although we have a s s u m e d "white" light u p to now, either of t h e s e two c a n be wavelength d e p e n d e n t . If either is w a v e l e n g t h d e p e n d e n t , t h e n we have a p i g m e n t (reflective- b u t m o r e properly called scattering) with i n t e n s i t y in foot-lamberts, or a n emitter s u c h as a l a m p or p h o s p h o r (emittance) with i n t e n s i t y in l u m e n s . IV. Color P r o c e s s e s a n d Color M a t c h i n g S y s t e m s In t e r m s of color, we c a n have one of two processes: 1. Additive p r o c e s s e s (emittance) 2. S u b t r a c t i v e p r o c e s s e s (reflectance). If we w i s h to m a t c h colors, the p r i m a r y colors are q u i t e d i f f e r e n t , as s h o w n in the following: 7.8.18.-
ADDITIVE PRIMARIES
SUBTRACTIVE PRIMARIES
red
magenta
green
yellow
blue
cyan
Let u s now consider how to set u p a color m a t c h i n g system. One w a y to do so is to average the eye r e s p o n s e s of a large n u m b e r of individuals so as to eliminate
421
the individual "quirks" of the h u m a n eye (some people c a n "see" into the violet or ultraviolet region w h e r e a s o t h e r s cannot). The r e s u l t a n t average is t h a t we call "The S t a n d a r d Observer". F. The S t a n d a r d Observer a n d The First C o l o r - C o m p a r a t o r Since color m a t c h i n g is m e a n t for h u m a n s , it is n a t u r a l to define color in t e r m s of an average, or " S t a n d a r d Observer". O u r first step is to build a n i n s t r u m e n t which
contains
three
colored l a m p
sources,
a place
for the
individual
observer, i n t e n s i t y detectors, a n d a m o n o c h r o m a t o r , as s h o w n in 7.8.19. on the next page. Essentially, s u c h a n i n s t r u m e n t is called a color-comparator. The design is simple a n d w a s u s e d m a n y y e a r s ago to o b t a i n the experimental r e s u l t s n e e d e d to fully define the t r u e n a t u r e of color m e a s u r e m e n t s . In this i n s t r u m e n t , there are two (2) s o u r c e s of light to be compared. One is from a set of three l a m p s w h o s e emission is modified b y m e a n s of suitable Filters to give a red b e a m ,
a
green b e a m a n d a b l u e b e a m . T h e s e are mixed at the screen to form a single spot (although we have not illustrated it in t h a t way, so as to be m o r e discernible). The o t h e r source c o m e s from a m o n o c h r o m a t o r so as to o b t a i n a m o n o c h r o m a t i c b e a m of light. There are controls to a d j u s t the individual b e a m s of red, green a n d blue light, as well as t h a t of the m o n o c h r o m a t i c b e a m . In this way, the mixed b e a m s of light c a n be directly c o m p a r e d to the m o n o c h r o m a t i c spot. In the b a c k of the screen are photoelectric detectors to m e a s u r e the energy i n t e n s i t y of the b e a m s of light being c o m p a r e d . We n e e d a b o u t 5 0 0 0 observers to obtain a satisfactory average, b o t h for the d a r k - a d a p t e d a n d the light-adapted h u m a n eye. There are three (3) t h i n g s t h a t n e e d to accomplished: 1. Define eye r e s p o n s e in t e r m s of color at e q u a l energy 2. Define s h a d e s of '~r
in t e r m s of % red, % green a n d % blue,
at equal energies of t h o s e "whites". 3. Define "color" in t e r m s of % red, % green a n d % blue, as c o m p a r e d to m o n o c h r o m a t i c radiation
422
The difficulty in setting u p the initial s y s t e m for color c o m p a r i s o n s c a n n o t be u n d e r e s t i m a t e d . The p r o b l e m w ~ e n o r m o u s . Q u e s t i o n s as to the suitability of various lamp sources, the n a t u r e of the filters to be used, a n d the exact n a t u r e of the p r i m a r y colors to be def'med occupied m a n y years before the first a t t e m p t s to specify color in t e r m s of the s t a n d a r d observer were started. As we said previously, the S u n is a b l a c k - b o d y r a d i a t o r having a spectral t e m p e r a t u r e of a b o u t I 0 , 0 0 0 ~
(as viewed directly from space). Scattering a n d reflection
423
w i t h i n t h e E a r t h ' s a t m o s p h e r e is sufficient to lower t h e effective b l a c k - b o d y r a d i a t i o n perceived to 6 5 0 0 ~
T h u s , t h e S u n is a 6 5 0 0 ~
s o u r c e w h i c h we
call "daylight". The direct viewed b r i g h t n e s s of t h e S u n at t h e E a r t h ' s s u r f a c e is about 165,000 candela/crn 2
, t h a t of t h e Moon - 0 . 2 5 c a n d e l a / c m 2 , a n d a
clear s k y is a b o u t 0 . 8 c a n d e l a / c m
2.
For t h e s e r e a s o n s , DAYLIGHT h a s b e e n defined as: ' T h e n o r t h e r n skylight at 11:30 am. at G r e e n w i c h , E n g l a n d o n O c t o b e r 31, definition of ILLUMINANT- C.
1931". This is also t h e
The o t h e r s t a n d a r d i l l u m i n a n t t h a t w e u s e is
ILLUMINANT- A, w h i c h is t h e r a d i a t i o n e m i t t e d f r o m a n i n c a n d e s c e n t t u n g s t e n f i l a m e n t o p e r a t i n g at 3 2 5 0 ~
T h e s e are s h o w n in t h e following d i a g r a m :
7.8.20.-
ISpectral Distribution of Standard Illuminating 200
160 120
sources I
I]11uminant' A I.... Illuminant - C
80 40 0 4000
5000
6000
7000
Wave length, Referring b a c k to o u r Color C o m p a r a t o r of
7.8.19., we u s e t h e s e c o n c e p t s to
c a l i b r a t e o u r l a m p s in t e r m s of s p e c t r a a n d relative e n e r g y in t e r m s of t h e s e standard
s o u r c e s . I l l u m i n a n t - B , b y t h e way, w a s originally defined a s
424
"average sunlight" b u t it w a s soon d e t e r m i n e d t h a t "average" is not the s a m e at all p a r t s of the E a r t h ' s globe. O u r next step in u s i n g the Color C o m p a r a t o r is to set u p p r o p e r filters so as to obtain a n d u s e "primary" color l a m p sources. We find t h a t b y u s i n g the m o n o c h r o m a t o r of the Color C o m p a r a t o r , we c a n a p p r o x i m a t e the wavelength r e s p o n s e of
o u r so-called " S t a n d a r d Observer", in the red region, the green
region a n d the b l u e region of the visible s p e c t r u m . B u t we also find t h a t we n e e d a b a n d of w a v e l e n g t h s for e a c h color, since a m o n o c h r o m a t i c b e a m is not at all suitable. This is w h e r e the choice b e c o m e s subjective, since we are relying u p o n the perceived r e s p o n s e of individuals. We fund t h a t b y choosing a b l u e filter p e a k i n g at 4 4 0 0 A, a green filter p e ~ g
at 5 2 0 0 A, a n d a r e d filter
p e a k i n g at 6 2 0 0 A (but having a lesser p e a k in the blue), we have a "Blue" blue, a "Green"-green a n d a "Red"-red w h i c h wiU satisfy m o s t observers. Note t h a t the original single color w a s c h o s e n b y a p p r o x i m a t i n g the h u m a n
eye
r e s p o n s e in the three-color regions, u s i n g m o n o c h r o m a t i c light to obtain a brightness
response,
and
then
properties of the three filters of the
adjusting
the
broad-band
transmission
l a m p s to obtain the p r o p e r colors. A final
c h e c k of t h e s e l a m p filters w o u l d be to m i x all t h r e e colors additively, a n d t h e n to evaluate the "white" t h e r e b y produced. We c a n t h e n s u b s t i t u t e a S t a n d a r d L a m p for the m o n o c h r o m a t o r a n d see if we c a n r e p r o d u c e its exact color t e m p e r a t u r e . If not, t h e n we n e e d to modify the t r a n s m i s s i o n c h a r a c t e r i s t i c s of o u r Filters u s e d on the s o u r c e l a m p s . Once we have done this, we now have o u r three p r i m a r y colors in the form of s t a n d a r d l a m p s , a n d c a n proceed to d e t e r m i n e Items 1,2 & 3, given above on page 421. To do this, we v a r y the wavelength of the m o n o c h r o m a t i c light, a n d d e t e r m i n e relative a m o u n t s of red, green a n d blue light required to m a t c h the m o n o c h r o m a t i c color. This is done, as s t a t e d before, for a b o u t 5 0 0 0 observers. The r e s u l t is finalized r e s p o n s e c u r v e s for the S t a n d a r d Observer, also called "Tristimulus R e s p o n s e curves", a n d is s h o w n as follows:
425
7.8.21.-
i
of the H u m a n Eye l
fill
fill
R-- Red respons'e ' g -Green response -Blue response
1.5 -~>
I
1.0
I
0.5
0
i 4000
5000 6000 Wavelength,
7000
We finally arrive at t h e r e s u l t we w a n t , since w e c a n n o w set u p ' T r i s t i m u l u s Filters" to u s e in defining colors. We c a n n o w define -Y as o u r s t a n d a r d l u m i n o s i t y c u r v e for t h e h u m a n eye (photopic vision). Note t h a t ~ , t h e r e d t r i s t i m u l u s value, h a s a c e r t a i n a m o u n t of b l u e in it in o r d e r to d u p l i c a t e t h e r e s p o n s e of t h e r e d p r e c e p t o r in t h e retina. I. T r i s t i m u l u s Coefficients O u r n e x t s t e p is to define colors in t e r m s of t r i s t i m u l u s r e s p o n s e s . We k n o w t h a t we c a n define t h e e n e r g y of a n y s p e c t r a l c u r v e a s a s u m m a t i o n of i n t e n s i t i e s t i m e s w a v e l e n g t h s , i.e.7.8.22.-
ER
= Z (IdX)R
EG
= Z (IdX)G
EB
= Z (Id~)B
426
Therefore ff w e t a k e t h e s p e c t r a l curve, a n d m u l t i p l y it b y t h e o v e r l a p of e a c h t r i s t i m u l u s r e s p o n s e curve, we get TRISTIMULUS VALUES, i.e.7.8.23.-
Reflective {scattering]
Emittance
(subtractive)
(additive)
x= ~ EIR dX Y =Y ZIGdX
X =~ Y
= -~ ~ I G R G
Z
Z
=z" ~ IBRB dX
= ~ EIBdk
However, we find t h a t t h e s e v a l u e s
EIR RRdX dX
are difficult to u s e since e a c h color give a
set of t r i s t i m u l u s v a l u e s , b u t e a c h set does n o t h a v e a specific r e l a t i o n to a n y other. T h e r e a s o n for t h i s is t h a t t h e i n t e n s i t y of IR ~ IG ~ IB . Therefore, we define a s e t of c h r o m a t i c i t y c o o r d i n a t e s , a s s h o w n in t h e following, w h e r e t h e tristhnulus
values
are
used
to
defme
what
we
now
call
"Chromaticity
z =
Z /X+Y+Z
Coordinates". 7.8.24.-
CHROMATICITY COORDINATF_~: x + y + z--
x =
X/X+Y+Z
1.00
y =Y/X+Y+Z
Note t h a t we n o w h a v e t h r e e
(3) different s e t s of v a l u e s r e l a t e d to color
specification, a n d t h r e e different t y p e s of s y m b o l s . In o r d e r n o t to get c o n f u s e d , we r e i t e r a t e t h e m again. T h e y are: 7.8.25.-
VALUES RELATED TO COLOR SPECIFICATION
Color T r i s t i m u l u s R e s p o n s e
Tr_-i. " s t i m u l u s Value.s
Chromaticity Coordinates
red:
~
X
X
green:
Y
Y
Y
blue:
~
Z
Z
427
T h e a d v a n t a g e of c h r o m a t i c i t y c o o r d i n a t e s is t h a t we n o w h a v e a set of normalized
v a l u e s w h i c h w e c a n u s e to c o m p a r e colors h a v i n g different
i n t e n s i t y v a l u e s (and t h u s different e n e r g y v a l u e s a s well). F u r t h e r m o r e , we n e e d o n l y specify • a n d y s i n c e x + y monochromatic
+
z = 1.00. T h i s allows u s to specify
r a d i a t i o n in t e r m s of o u r c h r o m a t i c i t y c o o r d i n a t e s . Actually,
w e c a n plot a t h r e e - d i m e n s i o n a l v a l u e o n a fiat ( 2 - d i m e n s i o n a l ) s u r f a c e . !I. Cb_romati'city C o o r d i n a t e Diagram.s S i n c e m o n o c h r o m a t i c r a d i a t i o n is a b o u n d a r y of color-mLMng, t h e n w e c a n c o n s t r u c t a CHROMATICITY COORDINATE DIAGRAM in t e r m s of x a n d y7.8.26.-
O.Y ,4.,m
=
mlmI
L 0
0.8
0.7
o
0.6
.~
0.5
tIE chromaticiiyl.. Diagram I
s30 540
510
oo. ....
;i~i~5.60.:Iby Kelly
Green
(1940) _
500
580"".......
mmIm
E
0.4
ca
0.3
0 L J=
m.
600
Green
Green
White
0.2
700 ~
d~S'-"
".
9
0.I
0.I
0.2 0.3 0.4 Chromaticity
0.5 0.6 0.7 Coordinate
.
9
428
Note t h a t the d i a g r a m is b o u n d e d , as we have already stated, b y the v a l u e s of m o n o c h r o m a t i c light. T h u s , we c a n find a n y color, be it m o n o c h r o m a t i c or polychromatic, in t e r m s of its • a n d y coordinates. We have delved into the m e t h o d s u s e d b y previous investigators in a n effort to quanticize color m e a s u r e m e n t a n d u s e d the s a m e m e t h o d s t h a t t h e y did. Once this w a s done, color specifications b e c a m e s t a n d a r d i z e d a n d were n o t subject to vagaries of the color-method u s e d or the deviations c a u s e d b y the h u m a n eye. It would be m o r e d r a m a t i c to p r i n t the v a r i o u s h u e a r e a s in color b u t it is difficult to a c c u r a t e l y p r i n t reflectance h u e s . It is b e t t e r to n a m e the colors directly. This w a s done b y Kelly (1940). Note also t h a t we do not u s e the t e r m "color" a n y m o r e b u t u s e the t e r m "hue". Any h u e c a n be specified by x a n d y. For example, we c a n specify the locus of b l a c k - b o d y h u e s a n d even I l l u m i n a n t s A, B & C. This is s u m m a r i z e d as follows: 7.8.27.-
xan.d y C h r o m a t i c i t y C o o r d i n a t e s x
_y._.
6000 A
0.640
0.372
5200
0.080
0.850
4800
0.140
0.150
Illuminant A (3250 A}
0.420
0.395
I l l u m i n a n t B (4500 A}
0.360
0.360
I l l u m i n a n t C (6500 A}
0.315
0.320
T h e s e points on the c h r o m a t i c i t y d i a g r a m are s h o w n in the following diagram, given as 7.8.28. on the next page. Nonetheless, while d e t e r m i n i n g color b y the color- c o m p a r a t o r m o d e w a s a distinct i m p r o v e m e n t over prior m e t h o d s of color c o m p a r i s o n , the m e t h o d w a s
429
slow a n d not e a s y to accomplish. W h a t w a s n e e d e d w a s an i n s t n n n e n t a l m e t h o d of color m e a s u r e m e n t a n d m a t c h i n g .
The r e q u i r e m e n t s for a n i n s t r u m e n t a l m e t h o d of specifying reflected color include a light source, the colored object a n d a detector. W h a t this m e a n s is t h a t all we need is a source, a n object a n d a detector. However, since the r e s p o n s e c h a r a c t e r i s t i c s of t h e s e optical c o m p o n e n t s are n o t linear, nor flat, we n e e d a n a n a l o g u e s y s t e m in o r d e r to be able to m e a s u r e color. The analogue s y s t e m simply corrects for the non-linearity of the s o u r c e a n d detector. The reflectance a n a l o g u e system, given as 7.8.29. on the next page,
430
s h o w s s c h e m a t i c a l l y how the s p e c t r a l power d i s t r i b u t i o n of a CIE source, the spectral reflectance, R, of a n object, a n d the spectral c o l o r - m a t c h i n g functions, x, y a n d z, combine b y multiplication (each wavelength b y e a c h wavelength), followed b y s u m m a t i o n a c r o s s the s p e c t r u m , to give the CIE t r i s t i m u l u s values.
However, t h e s e a n a l o g u e s are actually hypothetical. The r e a s o n for this is t h a t it is n e a r l y impossible to obtain optical m e a s u r e m e n t c o m p o n e n t s , s u c h as the s o u r c e a n d the detector, w h o s e r e s p o n s e to light a c r o s s the visible s p e c t r u m is fiat (or n e a r l y so). However, this is not a n impossible t a s k a n d we f'md t h a t a n excellent m a t c h c a n be o b t a i n e d to the t r a n s m i s s i o n functions of 7.8.21., i.e.those of the S t a n d a r d Observer. This is typical for commercially available i n s t r u m e n t s . Now, we have a n i n s t r u m e n t , called a Colorimeter, capable of m e a s u r i n g reflective color. The a c t u a l a n a l o g u e v a l u e s we n e e d to m e a s u r e reflectance are given on the next page as 7.8.30. as follows. Note t h a t the optical r e s p o n s e c u r v e s of the m e a s u r i n g parts, i.e.- the n o n - l i n e a r i t y of the s o u r c e a n d detector, are now corrected in the r e s p o n s e of the overall i n s t r u m e n t .
431
7.8.30.-
We find t h a t a n excellent m a t c h c a n be o b t a i n e d to the t r a n s m i s s i o n f u n c t i o n s of 7.8.20. This is typical for commercially available i n s t r u m e n t s . Now, we have a n i n s t r u m e n t , called a Colorimeter, capable of m e a s u r i n g reflective color. A s y s t e m for e m i t t a n c e color m a t c h i n g is given in the following :
This d i a g r a m s h o w s the energy s p e c t r u m of a given source, coupled with a triter of defined t r a n s m i t t a n c e , w h i c h is e s t a b l i s h e d b y a detector of k n o w n spectral response, as modified b y a s t a n d a r d s o u r c e a n d modified to t h a t of a S t a n d a r d Observer. Once a n i n s t r u m e n t h a s b e e n set u p properly with the p r o p e r optical
432
r e s p o n s e modifications, it will p r o d u c e c h r o m a t i c i t y coordinates t h a t a c c u r a t e l y reflect t h o s e n e e d e d to define the "color" of the emitter or reflector being measured. The p r o c e s s for actually m e a s u r i n g emissive color is s o m e w h a t different arid m o r e challenging. First, we m u s t obtain a n emission s p e c t r u m b y m e a n s of a spectrofluorimeter. We c a n now integrate I dk to o b t a i n the energy a n d t h e n specify this in t e r m s of x a n d y. There are special m e t h o d s w h i c h have b e e n developed to do so w h e r e i n selected w a v e l e n g t h s are used, d e p e n d i n g u p o n the n a t u r e of the emission s p e c t r u m . We will not delve f u r t h e r into this m e t h o d o t h e r t h a n to state t h a t it does exist. 7-9 C O ~ R
SPACES
If we have a certain color, a c h a n g e in i n t e n s i t y h a s a m a j o r effect on w h a t we see (in b o t h reflectance a n d emittance). For example, if we have a blue, at low i n t e n s i t y we see a b l u i s h - b l a c k , while at high i n t e n s i t y we see a bluish-white. Yet, the h u e h a s not c h a n g e d , only the intensity. This effect is p a r t i c u l a r l y significant in reflectance since we c a n have a "light-blue" a n d a "dark-blue", w i t h o u t a c h a n g e in c h r o m a t i c i t y coordinates. The concept of "lightness" involves the reflective power of m a t e r i a l s . If the reflectance a p p r o a c h e s 100%, we s a y the m a t e r i a l is "white", w h e r e a s complete a b s o r p t i o n (0.00% reflectance) p r o d u c e s a "black" material. Let u s e x a m i n e exactly w h a t is m e a n t b y t h e s e terms, p a r t i c u l a r l y those of s u b t r a c t i v e color mixing. W h e n colors are p r e p a r e d b y mixing dyes or p i g m e n t s , the r e s u l t a n t reflective h u e is controlled b y a s u b t r a c t i v e p r o c e s s of the three (3) primaries, w h o s e reflectance s p e c t r u m is given above. W h e n t h e s e are mixed, the r e s u l t i n g h u e is t h a t w h e r e the curves o v e r l a p ,
as is easily s e e n in 7.9.1.,
given on the next page. W h e n we mix t h e s e p r i m a r y colors, their reflectances remove m o r e of the incident light, a n d we see the p a r t w h e r e the reflectances are reinforced. T h u s ,
433
we c a n get red, green a n d blue, b u t t h e y are not p r i m a r y colors in the s u b t r a c t i v e system. I n t e r m e d i a t e h u e s c a n be o b t a i n e d also in this p r o c e s s w h e n the s u b t r a c t i v e p r i m a r i e s are u s e d in less t h a n full c o n c e n t r a t i o n . T h a t is, they
are
"lightened".
Although
we
can
explain
this
effect
on
a
s p e c t r o p h o t o m e t r i c basis, we do not have a w a y of specii~ying h u e s in t e r m s of
saturation, u s i n g the CIE s y s t e m . A....The MunseU Color Tree One of t h e first a t t e m p t s to specify reflective colors a n d color mixing w a s a c c o m p l i s h e d b y Munsell (1903). He devised a color s y s t e m b a s e d on factors he
434
called
hue,
ehroma
mad
value.
MunseU
set
up
a
three-dimensional
a r r a n g e m e n t b a s e d u p o n m/n/mum perceptual color difference steps. He b a s e d these u p o n direct observation since he did not have the i n s t r u m e n t a l m e a n s to do so. Therefore, his r e s u l t s are not the s a m e as the s y s t e m t h a t we u s e today. The a d v a n t a g e of the MunseU s y s t e m w a s t h a t in addition to being able to specify hue, we could also specify C h r o m a , w h i c h is the degree of s a t u r a t i o n of a specific hue. Value is the relative a m o u n t of "blackness" or "whiteness" (equal p a r t s of b l a c k a n d white p r o d u c e gray) in the p a r t i c u l a r reflective color being specified. It is this s y s t e m t h a t gives u s access to the degree of "grayness" a n d / o r s a t u r a t i o n of a n y hue. On a practical basis, if we wish to set u p this system, we w o u l d a s s e m b l e a set of "color-chips". E a c h color-chip w o u l d be specified b y two factors, H = hue, a n d V/C, w h i c h is value (grayness) modified b y c h r o m a (saturation). The actual n u m b e r of layers in the MunseU Color Tree w a s d e t e r m i n e d b y " m i n i m u m p e r c e p t u a l difference". T h a t is, the m i n i m u m c h a n g e t h a t p r o d u c e s a visual perceptible difference. This a r r a n g e m e n t specifies all light colors as well as the d a r k ones. To u s e s u c h a system, one would choose the color-chip closest to the h u e a n d s a t u r a t i o n of the test color a n d t h u s obtain v a l u e s for H a n d V/C. However, it w a s s o o n discovered t h a t the s y s t e m w a s not perfect. R e a s o n s for this include the facts t h a t the h u e s defined b y Munsell are not t h o s e of the p r i m a r i e s of the h u m a n eye. F u r t h e r m o r e , MunseU w a s s o m e w h a t subjective in his definitions of h u e s . In 1920, Priest s h o w e d t h a t if the Munsell-Chips were viewed on a whiteb a c k g r o u n d , the "brighmess", i.e.- lightness as viewed b y the h u m a n eye, could be related to the MunseU s y s t e m by: 7.9.3.-
V = 10 Y I/2
w h e r e Y w a s defined as "brighmess" or eye response. Over the years, the Munsell S y s t e m h a s b e e n modified to agree with actual h u m a n perception,
435
using a "middle-gray" b a c k g r o u n d . Nevertheless, it is well to note t h a t it was the subjective observation of the lack of correction for luminosity in the Munsell Syst em t h a t gave i m p e t u s to the development of the CIE Color System. The major problem with the Munsell system was t h a t each person attempting to m a t c h colors did not produce the exact same result. So color m a t c h i n g became dependent u p o n the person. B. Color Matching a n d MacAdam Space When MunseU devised his color space, he did so on the basis of m i n i m u m observable color perception steps. But the problem with the MunseU System_ w a s one of reproducibility, which the CIE S t a n d a r d Observer cured. In formulating a color match, one w a n t s to be able to predict the correct concentration of colorants required, whose scattering a n d absorption properties are known, i.e.- the lightness, so as to m a t c h the sample submitted, starting with their spectrophotometric curves. In practice, this is not so simple, since two colors m u s t have identical spectrophotometric curves to be e x a c t l y equal. It t u r n s out t h a t the h u m a n eye will identify the two colors to be equal ff their spectrophotometric reflectances are reasonably close. Two colors m a y appear to be equal u n d e r Daylight illumination, b u t quite different u n d e r i n c a n d e s c e n t lamp illumination. These colors are know n as "metamers" a n d the p h e n o m e n o n "metamerism". It was soon determined t h a t the 1931 CIE chromaticity diagram, and l u m i n a n c e function, Y, are not representative of e q u a l visual spacing, t h a t is, equal changes in Y do not represent equal changes in visual perception for all values of Y. Nor do equal increments of x a n d y represent the s a m e visual effect for all locations on the chromaticity diagram. In other words, there is a m i n i m u m perceptual difference on b o t h x a n d y (i.e.- Ax and Ay). But, the size of Ax a n d Ay is not the s a m e at all p a r t s of the chromaticity diagram. This is the same problem t h a t Munsell encountered a n d is due to the fact t h a t the h u m a n eye is
436
a n i n t e g r a t i n g i n s t n m l e n t , n o t a dispersive one. M a c A d a m (1942) s t u d i e d t h i s problem
and
established
limits
of M i n i m u m
Perceptual
Difference
steps
(MPD) in t h e form of ellipses o n t h e CIE d i a g r a m . This is s h o w n a s follows:
It t u r n s o u t t h a t a l i n e a r t r a n s f o r m a t i o n of x a n d y c o o r d i n a t e s to a n e w set of c o o r d i n a t e s , u a n d v, is sufficient to do t h e job. M a c A d a m ' s t r a n s f o r m a t i o n e q u a t i o n s were:
437
7.9.5.-
u v
=
4 x / (-2x+ 1 2 y + 3 )
= 6y / ( - 2 x + 1 2 y + 3 )
Plotting t h e s e v a l u e s gave the following c h r o m a t i c i t y diagram:
The t r u e test is how well the Munsell h u e s plot o u t on the CIE diagram. As c a n be s e e n on the right h a n d side of the diagram, the Value 5 - C h r o m a 8 h u e s do c o n s t r u c t a n e a r l y perfect circle. T h u s , the M a c A d a m t r a n s f o r m a t i o n is a definite i m p r o v e m e n t over the 1931 CIE system. In 1960, the CIE a d o p t e d the MacAdam System, h a v i n g defined t h e e q u a t i o n s (with MacAdam's help): 7.9.7.-
u= v=
4 X / (X+ 15Y+ 3Z) 6Y/
(X+ 1 5 Y + 3Z)
438
The following diagram, shows MacAdam's Uniform Chromaticity Scale, a n d h a s Minimum Perceptible Color Difference steps plotted as ellipses:
It should be clear that the CIE Color Chromaticity diagram, adopted in 1960 is a superior m e t h o d for delineating color differences. Indeed, it is the one specified for j u s t s u c h usage. Recommended Reading v
1. Robert E. Reed-Hill, "Physical Metallurgy Principles"Princeton, New J e r s e y (1964). 2. A.J. Dekker, "Solid State Physics" J e r s e y (1958).
Van Nostrand,
Prentice-Hall, Englewood Cliffs, New
3. Perelomova & Tagieva, "Problems in Crystal Physics"Eng. Transl. - (I 983).
MIR Publ., Moscow,
439
4. W.W. W e n d l a n d t , Thermal Methods of Analysis, Interscience-Wiley, New York (1964). 5. P.D. Garn, Thermoanalytical Methods of Investigation, Academic Press, New York (1965). 6. W.J. S m o t h e r s a n d Y Chiang, Handbook of Differential Thermal Analysis, Chemical Publishing Co., New York (1966). 7. E.M. Barral a n d J.F. J o h n s o n , in Techniques and Methods of Polymer Evaluation, P. Slade & L. J e n j i n s - Ed., Dekker, New York (1966). 8. W.W. Wendlandt, Thermochirra Acta 1 , (1970) 9. D.T.Y. Chem, J. ThermaIAnal., 6 109 (1974) - Part I 10. C h e n & Fong, loc. cit. 7 295 (1975) - Part II. 11. Fong & C h e n , loc. cit., 8 305 (1975) - Part III 12. C. Duval, Inorganic Thermogravimetric Analysis, A m s t e r d a m (1963).
2nd
Ed.,
Elsevier,
13. C. Keatch, An Introduction to Thermogravimetnj, Heydon, L o n d o n (1969). 14. "Vapor P r e s s u r e D e t e r m i n a t i o n u s i n g DSC", A. Brozens, R.B. Cassel, C.W. S c h a u m a n n & R. Seyler, Proceeding. N. Am. Therrra Analysis Soc. 2 2 n d Conf. Denver, Colo. (1993). Problems for Cha~)ter 7 _
1. You have a d d e d a solution of c a l c i u m chloride to a solution of s o d i u m metaborate. A crystalline precipitate resulted. In a t t e m p t i n g to analyze y o u r product,
440
an u n k n o w n x-ray pattern w a s obtained. You then u s e d DTA and TGA to attempt to characterize this product. Using the following DTA and TGA data,
--J........ 2 rrla.loss 54 mg loss
Iso=!,
o~
E L
r 100
m.l
109 mg loss
pi.
c~
co 200
go
0 ..J
|TGA Thermogram of Unknown j
.C:
I
I
200
,
I
,
400
,I
600
,,
I
8OO
,I , ,I
~ooo
J E
L a)
e--
o x LIJ
unI(now nl I-DTATherm-ogra ....... ~ o'f .....
a) e-
e-
200
400
600
Temperature in ~
800
1000
1200
441
identi_t~y all of the p r o d u c t s formed d u r i n g the r e a c t i o n s b y writing the r e a c t i o n s w h i c h o c c u r d u r i n g heating. Be s u r e to characterize b o t h the initial a n d final product. Write also the precipitation reaction. As a n aid, x-ray diffraction analysis w a s able to identify a p r o d u c t o b t a i n e d b y calcination at 1000 ~ as r c a l c i u m m e t a b o r a t e . Be s u r e to identify all of the p e a k s in the t h e r m o g r a m s . 2. C o n s t r u c t y o u r own DTA a p p a r a t u s , u s i n g a '%uilding-block" a p p r o a c h . The desired p a r a m e t e r s for y o u r DTA are: m a x t e m p = 1200 ~
Atm = A, N & R. Be
s u r e to specify the p a r t i c u l a r s of y o u r a p p a r a t u s : e.g.- t e m p p r o g r a m m e r = 1 to 30 ~ per m i n u t e , etc. 3. Using y o u r DTA, d r a w the expected curve for decomposition of:
a. SrHPO4 b. CaCOa C. Y(NOa)a 9 H20 You m a y w i s h to look u p decomposition t e m p e r a t u r e s in a H a n d b o o k of Chemistry. 4. Draw a n expected TGA curve for all 3 c o m p o u n d s , u s i n g the t e m p e r a t u r e s t h a t y o u u s e d in y o u r DTA curves. 5. Given the color c o o r d i n a t e s of: x = 0.34 & y = 0.5 I. Identify the color having this property. If x = 0 . 3 4 & y = 0.61, i d e n t ~ / t h e difference b e t w e e n t h e s e two colors. Identify the a m o u n t s of red, green a n d blue in e a c h of these. 6.
Do
the
same
for
the
following chromaticity
c o m b i n a t i o n s possible}: X = 0 . 2 5 , 0 . 4 5 , 0.65 y = 0 . 2 0 , 0 . 4 0 , 0.60
coordinates
(use
all
6
442
T h e r e are n i n e c o m b i n a t i o n s to be m a d e . Identify e a c h of t h e t h r e e at a time in t e r m s of i n c r e a s i n g green, or red.
SUBJECT INDEX
443
Abrams Eq. Absorbance Activated c o m p l e x Additive p r i m a r i e s Agglomerates Aggregates
188 413 390 420 196 195
Charged vacancies Charged vacancy
152 173
Charged vacancy Chem. Planarization Chromaticity diagram CIE c h r o m a t i c i t y
90 326 427 435
Amorphous solar cells Andreasen p i p e t t e Anion sub-lattice Anion vacancy Anti-Frenkel Anti-structure Arrhenius equation
351 239 78 81 94 110 140
Assay of materials Associated defects Avagadro's n u m b e r Balck and white color
386 102 12 408 41 344 413 245 226
CIS(1960) Color Clean r o o m CMOS design Color c e n t e r s Color Comparator Color m a t c h i n g Color spaces Color specification Common TC's Conductivity in solids Congruently m e l t i n g Coulter C o u n t e r TM
438 315 324 93 422 431 432 426 360 304 296 242
Critical radius Crucibles Cpjstallites Cumulative f r e q u e n c y
183 257 251 219
Czrochralski m e t h o d D - defects in silicon Damascene Defect equilibria Defect m o v e m e n t Defect reactions Defect symbolism Defect t h e r m o d y n a m i c s Defect types Defined vapor p r e s s u r e Degrees of f r e e d o m Diameter control Dice Differential TC
260 336 325 101 152 148 98 102 73 13 9 262 318 361
Band m o d e l s Becqueral Beer-Lambert law BET m e t h o d Bimodal distribution Binomial t h e o r e m Black body Bragg equation Bravais lattices Bridgeman m e t h o d BriUoin zones Buoyancy factor in TGA Calorie Candela Cation sub-lattice Cation vacancy Changes of state Charge c o m p e n s a t i o n Charged interstitials
209 406 35 46 271 40 383 4,5 419 78 81 1,3 79 91
444 SUBJECT INDEX
Diffraction file Diffusion b a r r i e r Diffusion g r o w t h Diffusion in spinel Diffusion r e a c t i o n s Dilatometric d e t e c t i o n Dflatometry Discontinuous limit Dislocation line Dispersion and m i x i n g Doping IKSC DTA DTA heating rate DTA t h e r m o g r a m DTA-glass points DTA-phase d i a g r a m Dynamic TGA Dystectic c o m p o s i t i o n Edge defined g r o w t h Embryo formation E m i t t a n c e analogue Enantiomorphs Encapsulating agent Endothermic Entropy effect Epitaxial g r o w t h Eukaryotic cells Eutectic Eutectic p o i n t Evacuated capsule Evaporation Ewald s p h e r e Exothermic E x t r e m e UV Extrinsic d e f e c t
58 332 144 159 154 396 394 224 87 132 93 374 361 367 363 379 367 385 299 295 142 430 300 270 358 71 288 63 66 25 293 13 38 358 339 86
Eye r e s p o n s e - l i g h t Eye sensitivity curve Eye sensitivity curve
416 408 409
F-Center Fermi level in solids Fick's first law Fine p a r t i c l e s Flame fusion Floating zone Flux Formation of nuclei Freeman-CarroU Frenkel d e f e c t Frenkel pairs Frequency plot Furnace d e s i g n Gas adsorbtion m e t h o d Gaussian distribution Gibbs-Thompson Glass expansion Glass points Globars TM Grades of purity Grain b o u n d a r i e s Growth d e f e c t s Growth limits Halophosphate Hancock a n d S h a r p e Heat Heat capacity Heat factors Heating e l e m e n t s H e r m a n n - Mauguin Heterotype Homotype Hopping m e c h a n i s m
94 359 149 171 282 275 170 191 392 80 161 217 253 245 210 144 398 379 255 111 251 266 222 197 156 4 3 3 254 52 96 96 134
SUBJECT INDEX
Hostogram 217 Huyghen's principle 411 Hydrothermal g r o w t h 2 9 0 IC m a c h i n e s 327 Impingment 192 Impurity distribution 277 Impurity doping 329 Impurity effect 72 Impurity leveling effect 2 7 8 Interface angle 264 Interface energy 186 Interface s t r u c t u r e 180 Internal heat 6,7 Interstice 22 Interstitial sites 90 Intrinsic defect 86 Inversion s y m m e t r y 50 Ionic defects in ice 307 Isothermal TGA 385 J o h n s o n - M e h l Eq. 188 Kirchendall effect 153 Kyropoulos m e t h o d 273 Laser r e f r a c t o m e t r y 247 Lattice angles 44 Lattice Directions 33 Lattice i n t e r c e p t s 44 Lattice points 32 Lattice tension 83 Line defect 82 Lithographic p a t t e r n s 3 3 0 Lithographic p r o c e s s 314 Log normal distribution 2 1 2 Log normal plot 220 M-center 95 MacAdam color space 4 3 6 Martin's d i a m e t e r 235
Mean free p a t h Metal carbonyls Metal expansion Metasilicate Metrology Mie m e t h o d Miller indices Molten flux Monolayer Muncell color MunceU Color Tr e e MXS binary c o m p o u n d
445
11 294 400 168 328 247 37 286 245 434 415 104
n-type 95 Negative bonding defect 3 0 5 Negative p h o t o r e s i s t 317 Newton and colors 408 Nitrides 325 Nuclear g r o w t h 145 Nucleation 141 Octahedron 21 Optical lithography 338 Optical p r o p e r t i e s 411 Ostwald r i p e n i n g 192 P-n-p transitor 312 p-type 95 Pairs of defects 105 , Parabolic law 147 Particle orienation 235 Particle p r o p e r t i e s 207 Peltier effect 359 Permeability 245 Phase boundary 133 Phase boundary g r o w t h 144 Phase relationships 64 Phonon m o d e s 16 Phosphors 100
153
446 SUBJECT INDEX
Photomask Photon s c a t t e r i n g Photon wavelengths
316 418 406
Photons in solids 414 Photopic r e s p o n s e 416 Photresist 316 Piezoelectricity 352 Point defect 74 Point groups 49 Polystructure 302 Polytypes 301 Pore g r o w t h 194 Positive bonding defect 3 0 5 Positive hole 92 Positive p h o t o r e s i s t 317 Propagation m o d e l s 17 Pure silicon 310 Quartz g r o w t h 291 Radiation interactions 4 1 2 Rate equations 138 Rate equations-solids 3 8 8 Rate of particle fall 239 Reciproval lattice 38 Reflectance 413 Reflectance analogue 4 3 0 Reliability factor 57 RF g e n e r a t o r 263 ROntgen x-rays 34 Rotaional s y m m e t r y 49 Schoenflies 51 Schottky defect 80 Scotopic r e s p o n s e 416 Screw dislocation 85 Sealed autoclave 289 Sedimentation balance 2 3 8 Sedimentation tube 241
Seebeck effect 358 Seed crystal 258 Self interstial 75 Shrinkage 194 Shrinkage 202 Silicon crystal g r o w t h 311 Silicon hydride cells 351 Silicon voids 336 Sintering 193 Sintering m e c h a n i s m s 201 Sintering T h e r m o . 198 Size range-particles 205 Slow nucleation 188 Solar cell 347 Solid solution 23 Solid state m e c h a n i s m s 130 Solid s y m m e t r y 35 Sonar 353 Space groups 51 Space lattices 47 Spinel 157 Spiral g r o w t h 87 Stacking faults 299 S t a n d a r d Observer 417 Standard sources 423 Static crucible 268 Stirling's approximation 125 237 Stoke's Law 57 Structure factor Subtractive p r i m a r i e s 4 2 0 Surface energy 198 Surface nucleation 142 Surface sites 90 Symmetry distribution 61 Symmetry e l e m e n t s 36 Symmetry operations 50
SUBJECT INDEX
T e m p e r a t u r e Scales Tetrahedron TGA
2 21 382
TGA-sample closure The plane n e t Thermal analysis Thermal capacity Thermal r e s i s t a n c e T h e r m o m e t r i c points
384 89 357 3 367 371
Thermometry Thin film p r o c e s s Translation vectors Tristimulus coefficient Tristimulus r e s p o n s e Twinning defects Tyler s c r e e n s U.S. s c r e e n s Unit cell volume Unit vector Vacancies Vacancy Vacancy-structure Vapor phase g r o w t h Verneuil g r o w t h Visual counting Volume defect Volume nucleation Wafer fabrication Wafer operations Wafer s t e p s Zone m e l t i n g Zone refining
401 316 34 426 425 300 213 213 33 33 90 75 110 292 282 233 74, 85 143 323 320 322 275 276
447
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