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UC-NRLF
272 BED
2w.s
REESE LIBRARY .
\
OF THE
UNIVERSITY OF CALIFORNIA.
-r
r
f
THE CHEMISTRY OF
PHOTOGRAPHY.
NATURE SERIES
THE CHEMISTRY OF
PHOTOGRAPHY
BY
RAPHAEL MELDOLA,
F.R.S,
&c
PROFESSOR OF CHEMISTRY IN THE FINSBURY TECHNICAL COLLEGE, CITY AND GUILDS OF LONDON INSTITUTE FOR THE ADVANCEMENT OF TECHNICAL EDUCATION.
MACMILLAN AND AND NEW YORK 1889
CO.
RICHARD CLAY AND SONS, LIMITED, LONDON AND BUNG AY.
PREFACE. THE
lectures
forming the subject of
this little
volume were delivered during the spring term of last
year as a special course
at
the
Finsbury
Technical College, and were addressed to a mixed audience,
of
composed
students
and
In selecting the present
practical photographers. topic, there has
chemical
been no attempt to impart instruc-
tion in the manipulative details of Photography,
since there are already before the public a large
number of
excellent
branch of the
art.
It
works is
mode
with
this
only with the chemical
principles underlying the
tures attempt to deal,
dealing
subject that these lec-
and
of treatment adopted
it
is
may
of convincing photographers
hoped that the
serve the purpose
how
essential
is
some
PREFACE.
vi
knowledge of Chemistry
for the successful carrying
on of
With
their operations.
of technical science,
is
it
intellectual discipline to
respect to students
always a most useful
have presented
in a sys-
tematic form the application of the general scientific
principles
which form the subjects of
every-day studies to
The
technology.
some
their
particular branch
of
interest evinced in the lectures,
both by students and practitioners, has encouraged
me
to offer
them
substantially the
in the present form,
which
same as that adopted
for
In the lecture theatre,
livery.
it
is
de-
of course, im-
is
possible to give authorities for all the statements
made, and such a
series of references
hampered the text
to an extent quite out of pro-
portion with the scope of the work. seen, however, that possible, to
whom
do
I
It
will
have endeavoured, as
be
far as
justice to all those investigators to
the subject
coveries.
would have
is
indebted
for
leading dis-
Free use has been made of the writings
of the late Robert Hunt, of Dr.
J.
M. Eder, Capt.
PREFACE. and
Abney,
Hauptmann
Pizzighelli.
acknowledge the assistance which
I
gladly
have derived
I
from the published works of these well-known authorities.
The
claim of Photography to be recognized as
a branch of Chemical Technology
is
now
generally
admitted, and systematic courses of instruction in this subject are given in
out the country. as though
it
The
this,
institutions through-
operator
who
treats his art
consisted simply of a miscellaneous
collection of recipes in
many
is
bound
to
become superseded
as in all other departments of scientific
industry, unless he has sufficient training in general principles to enable
changing conditions.
him It
to is
meet new and everto
be regretted that
purely scientific chemists have of late years shown a tendency
to neglect the Chemistry of Photo-
graphy as being an uninviting branch of science.
I
their
venture to hope that the present work
may
contribute towards convincing such workers
that
there
are
many
important problems
still
PREFACE.
viii
awaiting solution in this scientific interest
high
is
of research.
field
Its
by a
forcibly expressed
saying of the late Col. Russell's, that Photography
would be a most interesting subject were for the
it
not
pictures.
In order to facilitate the teaching of the scientific
number of ex-
principles of Photography, a
been introduced, hints
have
periments
performance of which are given
in the
for
the
appendix
to each lecture, the bracketed capitals in the text referring to these demonstrations.
that
the
directions
enable
to
explicit
possessed
of
manipulation large to
be
instructions
somewhat
any
to
as
described have
believed
sufficiently
demonstrator
in
photographic
successfully.
A
these experiments are believed
lecture
greater
found
is
lecture
them
repeat
have
be
skill
ordinary
number of
new
will
It
in
demonstrations,
and the
these cases been given
detail.
All
the
in
experiments
been repeatedly performed, and
they have been devised with the object of
illus-
PREFACE. trating the various points
ix
which they are intended
to elucidate with the simplest
the
readiest
great delicacy requiring
have
for this reason
arc light
All
way.
possible
appliances and in
much
experiments of
previous preparation
An
been excluded.
and lantern are indispensable
for
all
many
now such
of the demonstrations, but these are
very general accessories in
electric
properly-equipped
lecture-rooms that their existence has been taken for granted. I
have great pleasure
skilful assistance
out the
which
I
in
acknowledging the
have received
experiments from
Mr.
H.
T.
Lecture Demonstrator, and from Mr.
in carrying
J.
Norris,
M. Smith,
one of the Students of the Chemical Department,
who
kindly volunteered his services
illustrate the lectures.
FINSBURY TECHNICAL COLLEGE, February, 1889.
in
helping to
CONTENTS. LECTURE
I.
I. Photo-physical and Photo-chemical Photo-chemistry of Iron Salts, 12 ; of Copper, 17; Mercury, 18 ; Uranium, 19; Gold and Platinum Salts,
Definition
of
Change, 20.
Subject,
7.
Photo-reduction of
and Oxidation,
Appendix
to
Chromates,
Lecture
I.,
Dissociation,
24
;
30.
LECTURE v
21.
25.
II.
Photo- chemistry of the Silver Compounds, 35. Historical, 36. The Chloride ; Loss of Chlorine on exposure to Light, 38.
Composition of Darkened Product, 39. Analogy of Silver Haloids with Cuprous, Mercurous, and Thallous Haloids, 45.
The Bromide and
Iodide, 57.
the Photo-salts, 58.
Appendix
to Lecture II., 64.
Carey Lea's Experiments on
CONTENTS.
Theory of the Action of
LECTURE
III.
Sensitizers,
71.
The Colour Change
of
Haloids not a Quantitative Indication of their Relative Sensitiveness to Light, 74. Foundation of Modern
the
Silver
Photography, 82. Wedgwood, Davy, and Fox Talbot, 82. Joseph Nicephore Niepce, and Daguerre, 85. The Collodion
Wet
Collodion
Plate Process, 92.
Appendix
Emulsion Photography,
Collodion Emulsions, 105.
103.
The
IV.
113.
of
Sensitiveness
of
Gelatino-bromide Plates,
Recent Applications of Modern Dry
Appendix
Gelatine
Process of
Different Ripening, 121. Physical Aggregation of Silver Bromide, 127.
Emulsions, States
Plates, 95.
to Lecture III., 100.
LECTURE
Extreme
Dry
to
Lecture IV., 139.
LECTURE
V.
General notions of Development, 142.
Image, 146.
131.
Plates, 132.
The
The Latent
or Invisible
action of Sensitizers in different Processes,
150. Theory of Developers and Restrainers, 153. Development by Vapours, 156. Acid Development by Ferrous Sul-
Alkaline Development by Ammonium Pyrogallate, and by Ferrous Oxalate, 166. phate, 158.
Appendix
to Lecture V.,
177.
CONTENTS.
LECTURE
VI.
Rapidity of Emulsion Plates partly due to Developer, 134. Ferrous Oxalate Development, 186. Collateral Phenomena of Develop-
The Developer a Quantitative Microchemical Test, Development of Chemical Reduction Product and of
ment, 189. 189.
Pressure Marks,
Relative
191.
Sensitiveness
Haloids in Different Processes, 192.
Image due the
Image
one,
to Reversed
Chemical Change,
or Solarisation, 208.
of the
Silver
Relapse of the Invisible 197.
Reversal of
The Phenomenon a Recurrent
Theory of the Process, and the Function of the
214.
Sensitizer, 219.
Appendix
to Lecture VI., 231.
LECTURE Composition of \Vhite Light, 236. Intensity
and Photographic
Objects, 246.
VII.
The Spectrum,
Intensity, 243.
238.
Visual
Colours of Natural
Graphic RepreAction of the Spectrum on the Concurrent Reversal in Mixtures, 259.
Spectrum Photography, 250.
sentation of Intensity, 252. Silver Haloids, 253.
Reversal in the Spectrum under various Conditions, 267. Solutions of Oxidizing Substances and other
Reversal in
Reversing Agents, 272.
Appendix
to Lecture VII., 285.
LECTURE
VIII.
and Absorption Relationship between Photochemical Decomposition of Light, 288. Draper's Law, 290 Effect of Molecular AggrePhotogation upon Sensitiveness of Silver Haloids, 293. graphy of Red and Infra-red Rays, 294.
Physical Analogy
CONTENTS. between Emission Spectra and Photographed Spectra, 300.
f I
^photochemical Action probably Intramolecular, 302. Effects^ of Dyes on Local Sensitiveness, 305. Orthochromatic PhotoI
Appendix
to Lecture VIII., 327.
LECTURE J^ost-developmental Processes, 330.
/
^/
Photochromy, 321.
graph y, 309.
Weakening of the
fication, 333.
IX.
Fixing Agents, 331.
Intensi-
Silver Image, 339.
Printing
Albumenized Paper Process, 342. Emulsion Reduction Products of Organic Silver Compounds, Image Transference, 349. Toning of Silver Prints with
Processes, 342. Prints, 345.
348.
Gold, 352. Process,
359.
Theory of the Operation, 353. The Platinotype Chromatized Gelatine and Pigment Printing
Processes, 364.
Appendix
to Lecture IX., 369.
ERRATUM. The formulae assigned to the soluble and insoluble silver sodium The thiosulphate have been erroneously transformed on p. 332. soluble salt has the formula Ag2 Na 4 (S 2 3 )3 and the equation should
O
be:
2AgBr + 3 Na 2 S 2 O 3 = Ag 2 Na4(S 2 O 3 8 + 2NaBr The insoluble salt is AgNaS 2 O 3 A similar correction must be made on p. 358. )
.
THE CHEMISTRY OF
PHOTOGRAPHY.
THE CHEMISTRY OF PHOTOGRAPHY LECTURE Definition of Subject.
Change
I.
Photo-physical and Photo-chemical
Photo-chemistry of Iron
Salts
Mercury, Uranium, Gold, and Platinum reduction of Chromates.
THE
of
Copper,
Photo
-
and Oxidation.
Photography, which
of
subject
Dissociation
;
Salts.
has
been
chosen for this session's course of special lectures, appeals to us both as an art and as a science.
The
of
applications
photography
to
the
pro-
duction of pictures, either landscapes or portraits,
and
its
uses
lithographer
in
the service of the engraver or
may
be
branches of technical the subject
e
it
is
regarded art.
With
not proposed
to
as
so
this
aspect of
deal
many on the
B
THE CHEMISTRY OF PHOTOGRAPHY.
2
present occasion.
It
more with the
is
photography that
principles underlying
engage your attention during in
the
first
place these
scientific
wish to
I
because
this course,
principles
our
concern
Chemical Department as constituting a branch of technical chemistry, I
am
disposed
and because
to
believe
in the
that 'the
art
in
is
This
danger of outstripping the science. state of affairs
next place
is
a
which we often witness when a
discovery of immediate practical utility
is
made.
There are many branches of industry which arc
now
suffering in this country because they have
been allowed to go on from the time of their foundation without any attention being paid to the scientific principles underlying them.
It
has
been found by a long course of experience that certain
results
way and
that
can be obtained
mode
in
of procedure
a
has
stereotyped into a kind of article of
such cases no trouble the
particular
desired results science.
mode
is
of
particular
become
faith.
taken to ascertain operation
leads
to
In
why the
the art has here outstripped the
NECESSITY FOR INVESTIGA TION. But
we
if
thus allow a useful discovery to de-
we
generate into a purely empirical industry,
gave us the discovery are
and not only
;
taken
scientific
competitors
investigate
hands
our
of
out
who have no
who have taken
and
formula
why and
the
moment wish you is
graphy
an
there
has
suffered
no
be
in
forgotten
that
subject
countrymen. state
the art going
condition to
some
of
have
been
When
of affairs
Neither
devotees.
in
the
I
which there
danger,
imbue you with that
subject
de-
must
be
it
advances
made by our own
therefore
with
discovery,
this
greatest
allude is
beyond the science
fraught
a
experimenting of
velopment by the haphazard unscientific
dif-
photo-
scientific
its
to
for
that
English
doubt that
considerably
of the
do not
I
understand
to
more
by
trouble
wherefore
particularly
can
but
the
but
this,
stereotyped
the
ferent steps in their processes.
in
first
running into the danger of seeing the
industry
its
are
science which
neglecting our duty to that
we
3
spirit
I
of
a as
to
that
chance of being
simply
a
wish
investigation
B 2
THE CHEMISTRY OF PHOTOGRAPHY.
4
which
the
is
and soul of advancement
life'
every department of
we
in
this
not
may
country
order that
in
knowledge,
short
fall
in
our
in
the future development of the
contributions to subject.
On
considering the the
in
adopted
mode
of treatment to be
course
present
culty of selection presented
the
usual It
itself.
diffi-
obvious
is
a
wide
field
photography but
little
information of value
that
such
in
be given
dismissed
even in paths
as
which
beyond
our
in
used
of
well
lectures
by can
work,
present
many
lenses
the
proper
subject
form
the
the
and
inviting
Thus
optics
the
for
object,
of
of
etc.,
the
theory various
and
arrangement
subjects
but
scope,
directions.
of
once
at
offers
it
its
subject
may be
aspects
of
on
the
narrow
by photographers, the
construction
Illumination
very
side,
opening
kinds
has
only
scientific
its
apparatus
and
not
artistic
purely
offered
somewhat
to
restricted
is
For
limits.
that
a short series of lectures unless the
in
treatment
as
might
course
of
photography
a
a
DEFINITION OF SUBJECT. branch into which
on
this
occasion.
of photography in
several
make a
is
ways,
it
5
not proposed to
is
Then
the
again
enter
chemistry
capable of being dealt with
which we
between
have
to
choice.
The photographer in the course of his practice has necessarily to make use of various chemicals which he generally procures ready prepared and of a purity guaranteed sufficient for his purpose. these days,
when photography has been
by the introduction of dry is
baggage of the
addition
camera to
the
the requirements of the
tourist,
amateur can be met
so simplified
plates that the
becoming quite a common
In
at
every stage, and
the
practical manipulative details are thus reduced to
Both professionals and
the extreme of simplicity.
amateurs would however derive benefit from a
knowledge of the chemistry of the materials which they so constantly employ
that
is
to say from a
knowledge of the methods of preparation, the characteristic
properties
and
modes of valuation of these words,
reactions,
materials.
we may have a branch of the
and
the
In other
science dealing
THE CHEMISTRY OF PHOTOGRAPHY.
6
with the chemistry of photographic materials
But inasmuch as
kind of materia photographica.
although of undoubted
this sort of information,
not absolutely essential to successful work
is
value,
photography, and since those
in
find
in
it
a
many
who
require
of the published manuals,
can more profitably occupy both
my own
I
it
can
think
I
time and
yours by dealing with the subject from a somewhat higher point of view.
The all
future
advancement of photography, as
other branches
proper
recognition It will
principles.
make
clear to
you
of
science,
depends upon a
and application of be
my
of
scientific
endeavour therefore to
in the course of these lectures
our present position with respect to the chemistry of photographic processes, so that you
may
see on
the one hand what principles are involved in these processes, realize
what
how much we have
yet
to learn
may
and
in
directions further advance seems necessary.
From that
and on the other hand that you
this
it is
no part of
in practical
of plan
declaration
my
scheme to
photography
;
it
will
be seen
offer instruction
the details of processes
PHOTO-PHYSICAL CHANGES. will
only be given
you
to understand the principles underlying them.
I
have decided upon
may add it
in GO far as
mode
this
much
after
necessary to enable
of treatment
consideration
I
because, as
seems to me, our knowledge of the chemistry
of photographic reactions obscurity,
be
to
and a wide
is still
field
before
explored
much
involved in
of investigation has yet the
be
can
subject
established on a truly scientific basis.
The
we
action of light with which
concerned
in
photography
action resulting
compounds
in
is
a
are
chiefly
photo-chemical
the decomposition of certain
usually salts of silver
and the sub-
sequent completion of the reaction by the plication of appropriate chemicals.
By
ap-
a photo-
chemical action must be understood a chemical
change produced by the action of essential
to
bear in
mind
that
we
It
light.
are
is
mainly
concerned with actions of this kind because the influence of light does not always induce changes
of
a
purely
chemical
nature.
We may
physical changes, in matter produced it
is
sometimes
difficult to
by
light,
have
and
decide in any particular
8
THE CHEMISTRY OF PHOTOGRAPHY.
case
how much
and how much
may
of the effect
is
due to physical
That
to chemical change.
light
induce purely physical change will be evident
on reference to the numerous recorded instances, a few of which It
light
is
well
may
known
be here mentioned.
under the influence of
that
such elements as sulphur and phosphorus
gradually become transformed into their so-called "
"
allotropic
modifications,
ordinary
phosphorus
becoming red or amorphous and a strong solution of sulphur in carbon disulphide slowly depositing the insoluble modification
when exposed
light in a sealed tube [A].
So
salts,
to sun-
also certain metallic
such as the crystalline chloride or iodide of
silver, nickel
sulphate and zinc selenate, experience
a change in crystalline form under tha influence of light.
These are a few examples of photo-physical changes requiring more completion.
produce selenium,
an
In
some
or
less
time
instances light
instantaneous
change.
for
is
their
known
Crystalline
which under ordinary circumstances
a very bad
conductor of
electricity,
to
is
becomes a
PHOTO-DECOMPOSITION AND COMBINATION. much
better conductor
conductivity again
when
light falls
upon
the dark
falling off in
it,
;
9
the this
property of selenium, discovered by Willoughby
Smith in 1873, has been
utilised in Bell's
photophone.
All these instances are illustrations of physical
changes
induced
by
the
light
chemical
position of the substances referred to altered: white
and red phosphorus
is
and
modifications of sulphur, and the
same
the
are
no way
are. chemically
soluble
so
identical,
in
com-
insoluble is
true of
the different crystalline forms assumed by a salt
such as nickel sulphate or zinc selenate.
Regarded produce
both
although
it
any
a
as
is
chemical
agent
and
combination
light
may
decomposition,
often very difficult to say whether
particular
effect
other or of both
is
the result of one or the
modes of
action.
Consider for
instance one of the most familiar cases, the action
of light upon a mixture of chlorine and hydrogen.
These gases, as
is
well known, react explosively
under the influence of a strong
hydrogen chloride
[B].
This
as a case of combination, but
is
light
to
form
usually spoken of
it is
highly probable
THE CHEMISTRY OF PHOTOGRAPHY.
io
that a decomposition of the molecule of chlorine
precedes
its
The reason
union with the hydrogen.
for believing in
such preliminary decomposition
is
that the rays which are most active in bringing
about the reaction are the blue and those
rays
which
absorbed
are
violet,
i.e.
just
chlorine. 1
by
Without attempting therefore to draw any hard
and
fast line
bination,
let
between us pass
decomposition
on to the consideration of
some of
the photo-chemical
likely to
be of
advisable
to
reactions
which are
interest, either directly or indirectly,
connection with
in
and com-
our
approach
present
subject.
photography
from
It
is
this
broad point of view because we have now become' so accustomed to associate photographic processes
with the
salts
of silver that there
forgetting the fact that other
is
a danger of
compounds
are also
possessed of photo-susceptibility.
As examples by
of reactions promoted or caused
light let us first consider
1
some of the more
According to some researches recently published by Pringsheim (Ann. Phys. Chem. Ser. 2, vol. xxxii. p. 384), water vapour is essential to the reaction.
u
PHOTO-CHEMICAL REACTIONS. which
familiar cases
may be
said almost to obtrude
themselves under the notice of chemists in
exposed to water
of
habit
the
keeping
under
known
It is well
light.
the
on
reagents
of
influence
who
are
shelves
that chlorine
gradually
light
becomes acid from the formation of hydrochloric acid, whilst
oxygen
to
this
compare
is
liberated.
It
is
instructive
change with the same reaction
brought about by heat.
By
passing steam and
chlorine through a red hot tube hydrogen chloride
and oxygen are formed equation
[C]
according
is
brown from the is
view because resolution its
liberation
of interest
or
it
but
acid
also
and becomes
of iodine.
This
re-
from our present point of not
a
dissociation
constituents,
oxygen of the
is
.
of hydriodic
solution
aqueous
gradually decomposed by light
action
the
:
2C1 2 +2H 2 O=4HC1 + O 2
An
to
a
case
simple of a
compound
into
which
the
reaction
air takes a part
of the
in
:
4 HI+0 2 =2H 2 0+2l 2
.
THE CHEMISTRY OF PHOTOGRAPHY.
12
The proof of occur when air air
this is
that the change does not
is
In
excluded.
the presence of
an aqueous solution of hydrogen iodide under-
goes the same decomposition
more
in
the dark, only
slowly, so that in this case light acts as an
accelerator of a chemical change which takes place less rapidly in the dark.
The
upon metallic compounds
action of light
such as the oxides and
salts
is,
speaking
terms, a reducing action, so that
remember
that
show the most are
the
metallic
it
compounds
Among
which
photo-chemical changes
striking
very generally those
oxidation.
general
important to
is
which are capable of
being reduced from a higher to of
in
the
a
lower state
metallic
compounds
which chemical students are
in the habit
of re-
garding as typical of those capable of forming two such
classes, the salts of iron will at
themselves.
It is well
known
once suggest
that ferric salts in
the presence of reducing agents lose
some of
their
oxygen or other negative constituent and become converted
into
ferrous
This
compounds.
duction can also be effected by
light.
It
re-
must be
PHOTO-CHEMISTRY OF IRON COMPOUNDS.
13
understood however that the photo-chemical change in the
can only take place
presence of oxidizable
matter, so that the reduction of the ferric salt and
the oxidation of the associated substance proceed simultaneously.
The
photo-sensitiveness of ferric
long been known, having been
examined by graphy was
Sir
in
John
its
compounds has
first
Herschel, to
systematically
whom
photo-
early days indebted for
many
important contributions.
As
chemical change
be instructive to enter
somewhat
it
will
a
type
of photo-
further into these reactions on the pre-
Let us
sent occasion.
considerations
Reducing
start
from purely chemical
:
agents
such
as
nascent
hydrogen,
sulphurous acid, &c., immediately reduced
compounds [D] of light
ferric
either in the presence or absence
:
+ SO + 2H O = 2FeSO 4 + 2H SO 2
2
2
Here
the
4
Ferrous sulphate.
Ferric sulphate.
reducing
becomes oxidized
agent,
sulphur
dioxide,
into sulphuric acid at the ex-
THE CHEMISTRY OF PHOTOGRAPHY.
H
pense of the oxygen of the light
falls
salt
say
because
Now when
ferric salt.
upon an aqueous solution of a
ferric
no reduction takes
place,
ferric chloride
under
circumstances
these
the
water does not act as a reducing agent the
easily
;
but
in
organic compounds which are
of
presence
solvent
which
and
oxidized,
absorb
therefore
oxygen or other negative elements,
or,
in
other
words, which act as reducing agents, ferrous chloride
Thus an
formed.
is
of ferric chloride
ethereal or alcoholic solution
reduced by light
is
[E].
In the
case of alcohol the change might be represented
thus
:
Fe 2 Cl 6
+ C H6 2
= Fe 2 Cl 4 + C 2 H 4 O +
Alcohol.
Ferric
Ferrous
2HC1.
Aldehyde,
chloride.
chloride.
If therefore
we have a
ferric salt in
contact with
something that will act as a reducing agent, we can insure the formation of a ferrous salt on exposure to light.
You must
because
the whole
action
is
involved
substance that does
notice the expression will secret of the therein. act,
We
act,
photo-chemical
do not want a
such as sulphurous acid,
PHOTO-CHEMISTRY OF IRON COMPOUNDS.
15
but a compound ready to act when, under the stimulus of light, the substance with which associated
decomposed
is
it
is
we must have a system
:
ready to undergo rearrangement, but waiting the application of
some external energy
to set
it off.
In order to utilize the photo-reducibility of a
we may
for the production of a picture
ferric salt
spread the
salt
over a surface of paper because
being an organic substance, acts as the re-
this,
Of
ducing agent. thing
if
we
course
it
comes to the same
use an organic ferric
salt.
By
exposing
such a sheet of ferric-coated paper to the electric light for a short
time under a design cut out in
black paper, the portion exposed to the influence of
light,
ferrous
i.e.
salt,
the
and
because of the
becomes delineated
design,
thus lighter
becomes colour of
visible,
faintly
the
compared with the yellow
ferric
contrast can of course be
made more
in
latter
compound.
as
The
striking
by
washing over the exposed paper with a solution of
some substance which forms a coloured compound with one salt and not with the other. chemists
know
Thus
all
that potassium ferricyanide gives
THE CHEMISTRY OF PHOTOGRAPHY.
16
only a dark colouration and no precipitate with ferric
salts,
whilst
with ferrous salts
it
forms a
blue precipitate of ferrous ferricyanide (Turnbull's" blue)
:-
3 Fe 2 Cl 4
-!-
2K 6 Fe 2 Cy 12 = 2Fe3 (Fe 2 Cy12) +
By washing
I2KC1.
the exposed surface with a solution
of ferricyanide the pattern therefore becomes revealed
or,
as photographers
would
say, developed in
Turnbull's blue [F].
The photo-reduction
of the ferric salt
is
some-
times accompanied by the visible evolution of a
This
product of oxidation. solution of ferric oxalate
dioxide and deposits
:
Fe 2 (C 2
The
the case with a
which under the influence
of light gives off carbon ferrous oxalate
is
4) 3
= Fe
2
(C 2
4) 2
+ 2CO 2
.
organic acid of the ferric salt here plays
the part of the reducing agent, the reaction being sufficiently definite to
enable
it
to be
employed as
a method of chemical photometry.
This behaviour of the iron
salts
under the
in-
COPPER SALTS.
17
fluence of light will serve as a useful introduction
We
to the photo-chemistry of other metallic salts.
may
look upon these reactions as typical cases of a salt from a higher
of the photo-reduction
to a lower state of oxidation in the presence of
The development by
organic reducing agents.
means of
ferricyanide
may from
our present point
of view be put into the background as being only of
The one
secondary importance.
conveyed by the action
reducing
illustrations
of
always mean a removal negative elements
by the
reducing
chlorine
when
may
is
not
that the
necessarily
of oxygen, but
also
agent,
chosen
does
light
great lesson
other
be removed and fixed
such,
ferric chloride
example, as
for
oxidizes alcohol or
ether under the influence of light.
Without
in
any way attempting a complete
treatment of the photo-chemistry of all the metallic salts
which are influenced by
interest to consider here
light, it
some of the
will
better
be of
known
instances.
In the case of copper
becomes reduced
it
to cuprous
is
known
that cupric
compounds, such C
for
1
THE CHEMISTRY OF PHOTOGRAPHY.
8
example
an alcoholic or ethereal solution of
as
cupric chloride, which becomes reduced to cuprous chloride under the influence of light. is
The
action
here analogous to the photo-reduction of ferric
and requires no
salts
to
respect shall
special explanation.
reduction
the
of
With
cuprous chloride
I
have to say more hereafter.
Mercuric chloride in aqueous solution
by
decomposed
manner
bright
the
in
light
is
slowly
following
:
4HgCl 2
-f
2H 2 O = 2Hg
As oxygen
is
2
Cl 2
+ 4HC1 + O 2
Mercurous
Mercuric chloride.
.
chloride.
here liberated you will readily
understand that in accordance with the principles previously laid
down
the reaction would be pro-
moted by the presence of some oxygen-absorbing, i.e.
oxidizable substance.
It
has accordingly been
found that the addition of organic substances, such
and
other
acids, sugar, &c. hastens the decomposition.
Thus
as
formic,
oxalic,
succinic,
a mixture of mercuric
oxalate under
the
tartaric,
chloride
influence
of
and ammonium light
gives off
MERCURY AND URANIUM carbon dioxide and chloride [G]
rapidly
deposits
19
mercurous
:
2HgCl 2 + (NH 4 ) 2 C.,0 4 = Hg,Cl 2 + This
SALTS.
decomposition,
change undergone by
the
like
:
.
corresponding proceeds at
ferric oxalate,
and has been
a measurable rate
2NH 4 C1 + 2CO
for the
utilized
quantitative determination of the intensity of light.
Other
mercuric
such
salts,
sulphate, carbonate,
the
as
chromate, &c.,
nitrate,
when spread
over the surface of a sheet of paper and exposed to light, also undergo reduction accompanied
by a
change of colour [H]. Uranic
salts in contact
with organic substances,,
such as alcohol, ether, glycerol, paper, &c., behave, like the ferric
compounds and undergo reduction
on exposure to
doubt have
result
not
chemical
light.
from
been side
Uranous compounds no
this reduction,
sufficiently
to
enable
but the reactions
studied
us
to
represent
changes satisfactorily by equations. borne
in
mind
from
It
their
the
must be
that the so-called uranic salts are
really salts of the
oxygenated radical
UO
2,
C 2
uranyl,
THE CHEMISTRY OF PHOTOGRAPHY.
20
so that in the photo-reduction this radical
with
its
Thus,
oxygen.
the
in
case
may
part
of uranyl
sulphate dissolved in alcohol and exposed to light,
uranous sulphate
is
deposited
:
2UO SO = U(SO 4) + UO + O 4
2
2
The oxygen
is
2
2 (absorbed).
of course not liberated, but
is
used up in oxidizing the alcohol, probably with the formation of acetic acid. It
must
suffice for the present to
the sensitiveness of the uranic salts
mention that is
sufficient to
enable these compounds to be used for photographic purposes
Good
[I].
illustrations
are furnished
by the
of auric chloride, substances
is
of photo-chemical reduction salts of gold.
AuCl 3
reduced
,
Thus a
in contact
first
to
solution
with organic
aurous chloride,
AuCl, and then to metallic gold.
The photo-
graphic importance of the easy reducibility of gold salts will
be seen subsequently when we come to
consider the chemistry of the process of toning.
The photo-reduction
of the platinum salts takes
place readily in the presence of organic substances,
CHROMIUM COMPOUNDS. especially
when as
reduction,
21
the platinous salts are used. of
case
the
in
The
compounds,
gold
proceeds to the extreme, metallic platinum being deposited in an extremely fine state of division.
The two
classes of platinum salts are typified
platinic chloride, PtCl 4
and
,
platinous
PtCl 2 both of which form double
salts
,
chlorides of the alkali metals
PtCl 4 ,2KCl
=K
2
PtCl 6
,
known
are
those
among
to chemists as
are easily reducible
= K 2 PtCl 4
.
Potassium chloroplatinite.
Potassium chloroplatinate.
The chromates
chloride,
with the
:
PtCl 2 2KC1
.
by
salts,
well
powerful oxidizers, which
by
in
light
the presence of
organic or other oxidizable substances and which are of great
importance
in
The
photography.
general character of the change which takes place
when a chromate
is
reduced
may
be exemplified
by the well-known reduction of potassium dichromate by means of sulphuric acid and alcohol :
K
2
Cr,O 7
+ 4H SO + 2
Potassium dichromate.
Cr2 (S0 4) 3 Chromium
2
3C 2 H 6 O = Alcohol.
+ K S0 +
sulphate.
4
4
3C 2 H 4 O Aldehyde.
+ ;H
2
O.
THE CHEMISTRY OF PHOTOGRAPHY.
22
It
is
be observed
to
dichromate, which oxide,
is
in
this reaction that the
a salt of the acid chromic
CrO 3 becomes reduced ,
oxide Cr2 O 3
to a salt of the basic
[J].
This reaction
will serve to
illustrate
eral nature of the photo-reduction.
potassium or
the gen-
A solution
ammonium dichromate
of
spread over
paper and exposed to light becomes brown on the
exposed portions [K]. size)
(or its contained
here plays the part of the reducing agent,
just in the
same manner that
of ferric chloride. as
The paper
sugar, glycerol,
it
does in the case
Other organic substances, such albumen, gums, gelatine, &c.,
exert a similar influence.
No
free acid is neces-
sary in these cases of photo-reduction
;
it
appears
indeed probable that the oxygen of the dichromate is
used up
in
forming acid products of oxidation
from the organic substances, so that the alkali
would be thus neutralized. for is
example
among
it
In the case of gelatine
has been proved that formic acid
the products of
its
photo-oxidation by
The dichromates moreover
are themselves acid
dichromate.
CHROMIUM COMPOUNDS. salts,
23
containing an excess of acid oxide, and
has been shown that the
it
step in their photo-
first
reduction in the presence of an organic substance is
in
many
instances, if not generally, the
chromate, Cr 2 O 3 is
,
CrO 3
Cr3 O 6 which compound ,
capable of further reduction
4 Cr 3
The is
or
6
= 6Cr 2
action of light
chromium
:
+ 3 O2
3
.
upon chromatized gelatine
the foundation of several important printing pro-
cesses.
By
this action not
reduced, but the gelatine
rendered insoluble. insoluble
compound
chromium
It
only at
is
is
the dichromate
same time
the
seems probable that the
thus formed contains oxide of
as an essential constituent.
interest here to
remark that
It will
in this case
be of
we have
another reaction in which light acts as an accelerator of chemical change,
gelatine
since
becomes gradually insoluble
chromatized in the dark>
especially in a moist atmosphere.
We have
now
considered a sufficient
number of
more
clearly the
instances to enable us to realize
THE CHEMISTRY OF PHOTOGRAPHY.
24
general
when
nature of the change which takes place
light acts
upon reducible
of oxidizable substances.
salts in the
either a liberation
of oxygen or of
negative element, such as chlorine
we must expand our
Although
in the cases given
essential to the reaction, all
to say
it
i.e.
a*s
deoxida-
an oxygen or
a reducing agent,
must not be supposed
photo-chemical changes are of this charac-
It will
ter.
is
ideas of photo-reduction so
chlorine-absorbing substance,
that
some other
that
as to include dehalogenization as well
is
be well
mind that photo-reduction may mean
to bear in
tion.
presence
It will in future
serve to broaden our views
if
we now
consider a few other typical illustrations. In
some instances
light, like heat,
can produce
changes of the nature of pure dissociation, such for
example
as
when mercurous oxide becomes
converted into mercuric oxide and mercury, or
mercurous chloride into the mercuric metal [L]
salt
and the
:
Hg = HgO + Hg Hg Cl = HgCl + Hg 2
2
So
2
also certain metallic
2
oxides, such
as those
PHOTO-DISSOCIATION AND OXIDATION. of gold and residue
silver,
give
containing
the
All
light.
such
oft"
25
oxygen and leave a
metal
on
exposure
decompositions as
these
to
may
be regarded as cases of photo-dissociation. 1
Under tion
and
the influence of light the rate of oxida-
by atmospheric oxygen it
is
is
often accelerated,
probable that this photo-oxidation plays
an important part
in
many
photographic phenom-
ena which we shall have to deal with hereafter.
may remind you
I
of one illustration of this kind
of action given in the early part of this lecture, viz.,
the oxidation
an
of
aqueous
solution
of
hydriodic acid with the liberation of iodine (see p.
In
11).
in a
manner potassium
similar
stable
although alkaline
a
when
dry,
moist
becomes
gradually
and discoloured when exposed
iodide,
~to
chemical oxidation by atmospheric oxygen
4KI 1
%
+ 2H O + 2
Gaseous hydrogen iodide
sure for a
summer month
found to be decomposed.
O, is
- 4KOH +
2 :
2 1.,
decomposed by light ; after expo80 per cent, of the gas was
to daylight
G. Lemoine, Ann. Chim. Phys.
vol. xii. p. 145. 2
light
state, the change being due to photo-
Vidan, Pharm. Jaurn. Trans. 3rd
ser. vol. v. p. 383.
ser. 5,
THE CHEMISTRY OF PHOTOGRAPHY.
26
In
case
this
the
potassium iodide
may
itself
play the part of the reducing agent, since
known
is
it
that this salt combines with two atoms of
iodine to form the unstable triiodide,
KI 3
.
Other examples of oxidation are furnished by lead compounds, moist litharge
becoming gradually
deeper coloured and a thin film of lead sulphide
becoming bleached on exposure
So
[M].
far as the
and
to light
air
chemistry of these changes
concerned the reactions are simple enough
is
:
6PbO + O 2 Pb 3 O 4 + Oo - 3PbO 2 In the case of litharge the lead
and the
final
is
red
product the brown peroxide.
In
first
product
the case of the sulphide the sulphate
is
formed
:
PbS + 2O 2 = PbSO 4 Certain
resinous
when exposed in and air become other
oils
and
bitumenous
substances
thin films to the action of light
insoluble
which
dissolve
in
hydrocarbons and
them
freely
before
BLEACHING ACTION OF LIGHT. The
such exposure. to
action since
photo-oxidation,
air
here probably due is
historically interesting as
the
in
first
This
essential.
oxidation
kind of photo-chemical
particular
employed
is
27
is
having been the method
successful attempt to fix a
photographic image by Joseph Nicephore Niepce
about the year 1824.
This inventor
who, with
Daguerre, must be considered as the founder of coated a metallic plate with bitumen
photography
some hours
and exposed
for
with a
The image was
lens.
by immersion
in a
afterwards developed
in oil of lavender,
which dissolved the
portions of the film unacted upon
a picture in insoluble bitumen. of
this,
the
first
camera provided
by
light
The
and
left
discovery
truly photographic process, laid
the foundation of a printing process which
is
still
in use.
Among
other instances of the photo-chemical
oxidation of carbon the well certain
Here
by
compounds may be mentioned
known bleaching
natural and
for instance are
the action
action of light
artificial
colouring
upon
matters.
examples of designs formed
of light upon
papers dyed with
THE CHEMISTRY OF PHOTOGRAPHY.
28
and
eosin
methylene
fading on
to
exposure
sunlight
The
ten
for
typical cases of photo-chemical action
have now been considered illustrative of a special
or
termed
be
may be
regarded as
photo-chemistry, in
and
of
action
effected
many by
other
light
way have been graphic
directly
kinds
if
of
which
upon
have been tempted to dwell
There
chemical I
should
they could in any
connected with photo-
Thus the decomposition
processes.
this
sense here dealt
the
with must be looked upon as an offshoot. of course
which
branch of our science which
photographic chemistry
are
being
amount
minutes [N].
fifteen
may
former
enough to show a perceptible
sensitive
of
the
blue,
of
carbon dioxide by the green leaves of plants, the photo-decomposition of the vapours of organic
compounds such etc.,
of
investigated liquids
like
as
amyl
part
attacked
isopropyl iodide,
by Tyndall, the polymerisation vinyl
markable influence of precise
nitrite,
bromide, light
in
and
the
re-
determining the
of the molecule of a hydrocarbon
by chlorine or bromine
recently
in-
OTHER PHOTO-CHEMICAL CHANGES. vestigated
by
Schramm,
1
are
all
types
29
of
photo-chemical action which would lead us too far
astray
if
followed
up
in
the present course
of lectures. 1
Ber. Deutsch. Chem. Gesell. 1885, vol.
1,272; Ibid. 1886, vol. xix. p. 212.
xviii.
pp. 350, 606, and
APPENDIX TO LECTURE
A
(p.
hibited
8).
Two
sealed
glass
I.
tubes were
ex-
both containing a portion of the same
saturated solution of sulphur in carbon disulphide. One tube had been exposed to light for a week or
two and contained a deposit of
crystalline sulphur
incrusting the side of the glass, while the other, which had been kept in the dark, was perfectly clear.
B
(p.
mental
9).
For
details
concerning the experi-
explosion of hydrogen and chlorine under the influence of light see Roscoe illustration of the
and Schorlemmer's Treatise p.
011
Chemistry, vol.
i.
125.
C
(p.
1
1).
Chlorine
is
containing boiling water
passed through a flask
and the mixed gas and
water vapour passed though a porcelain strongly heated in a gas combustion furnace. escaping gas
is
tube
The
received over dilute caustic soda
APPENDIX TO LECTURE
I.
solution to absorb excess of chlorine, to be
D
oxygen by 13).
(p.
divided
into
side
by
solution
portions,
or
an
each,
iron
salt
chloride
ferric
to
aqueous
one
is
which
of
of
solution
The two beakers
ferricyanide
into
of
a
are placed
on white paper and a few drops of
side
potassium
A two
added.
is
sulphite
and shown
the usual tests.
acid
sulphurous
31
the
solution
allowed to
beaker
the
fall
reduced
containing giving a blue precipitate and the unreduced solution a brown colouration.
E
14).
(p.
A
solution
of
ferric
chloride
in
alcohol
(methylated spirit answers the purpose) divided into two portions in two large test tubes, one of which is placed on the table is
away
from the influence of light and the other in a beaker of water (to keep it cool) and exposed for five or ten minutes to the electric beam from an arc
lamp concentrated by means of a lens. After exposure the two tubes are placed side by side and ferricyanide
added to each, when the solution
in the
exposed tube gives a deep blue precipitate and the other the usual brown colouration.
F
(p.
1
6).
Paper
is
coated with a 10 per cent,
solution of ammonio-ferric citrate by floating on the liquid for a few minutes and then
to dry in a dark room.
allowing it After exposure for about
THE CHEMISTRY OF PHOTOGRAPHY.
32
ten minutes to the electric light under a design cut
out in black paper, the sheet is withdrawn and developed by brushing a solution of potassium ferricyanide over the surface.
G
(p.
The mixture
19).
of mercuric
and ammonium oxalate used oxalate photometer" can
experiment.
No.
I
The
5
c.c.
as follows
ammonium
this
in
employed
made
is
4 grams crystallized IOO
No. 2
solution
be
chloride
Eder's " mercury-
in
:
oxalate.
distilled water.
grams mercuric chloride. IOO c.c. distilled water.
Before use two volumes of No.
I
are added to
one volume of No. 2 and the clear solution placed in a flask in the electric beam. The separation of the shining white crystalline mercurous salt soon
commences, and
forms a
very
striking
lecture
demonstration.
H
(p.
19).
Dark mercurous oxide prepared by
precipitating mercurous nitrate with caustic potash is collected on a filter, washed with water, and
A
allowed to dry in the air in the dark. test tube is filled with the and dry powder exposed to light for
some days, when the
becomes
ochreous
owing
side towards the light
to
the
formation
mercuric oxide, the other side remaining
of
dark.
APPENDIX. This tube was exhibited and also old specimens of various mercurial preparations which had been kept for a long time in a cupboard with glass doors, the sides of the bottles towards the light showing in many cases discoloration. Signs of decomposition were particularly noticeable in the case of a specimen of calomel. I
Paper solution of uranium (p.
20).
is
floated
on a 15
nitrate in distilled
per.
cent
water for
about ten minutes and then allowed to dry in the The paper is exposed under a design for dark. minutes to the electric light and then developed with ferricyanide, as in the case of the It saves time if ammonio-ferrous citrate paper.
about
fifteen
the paper
given a preliminary exposure before
is
the lecture. J
22).
(p.
A
hot solution
of potassium di-
chromate of & distinct orange colour is placed in a beam of electric light in a flask and alcohol
dropped
in
till
by transmitted
the colour changes to green (red The oxidizing action of light).
chromic oxide was also shown by the familiar experiment of dropping alcohol on to the solid crystals,
to take
K
when the heat produced causes the
alcohol
fire.
A
design was exhibited produced by a sheet of paper coated with potassium exposing (p.
22).
D
THE CHEMISTRY OF PHOTOGRAPHY.
34
dichromate under a pattern cut out portions are brown.
in
black paper.
The exposed
L
(p.
The specimens
24).
referred to in exp.
H
illustrate these reactions.
M
A
design can be printed on paper coated with lead sulphide by floating on a solution (p. 26).
of the acetate and then exposing to sulphuretted hydrogen till a brown surface is produced and
drying to
in
the dark.
bright
light
the
After some days' exposure
exposed
portions
become
lighter.
N (p. 28). Papers were coloured by floating on a solution of eosin ('25 grm. per litre) and methylene blue ('25 grm. per litre) and then exposed under a design in the usual way. In the course of about a week the exposed portions have faded
sufficiently to render the design
spicuous, and
after three
con-
weeks the blue and red
patterns appear on almost a white background. Many other coal tar colouring matters, such as
the methyl violets, iodine green, susceptible of photo-oxidation.
etc.,
are equally
LECTURE
II.
i
Photo-chemistry of the Silver Compounds.
The
Chloride
;
loss of Chlorine
Historical.
on exposure
to Light.
Darkened Product.
Analogy of Silver Haloids with Cuprous, Mercurous, and Thallous Haloids. The Bromide and Iodide. Carey Lea's Experiments Composition of
on the Photo-salts.
AMONG silver
the photo-reducible metallic salts those of
occupy such an important place
in all
photo-
graphic processes that their consideration has been deferred in order that they might receive their due
share
of attention
in
Not
the present lecture.
only are these salts of great practical importance at
the
present
time,
but
they are historically
interesting as having been the
compounds
in
which
a change of colour on exposure to light was
observed and recorded.
I
regret
much
D
first
that the 2
THE CHEMISTRY OF PHOTOGRAPHY.
36
scope of the present lectures will not admit of
lengthy historical digressions, and
it
must
suffice
here to mention that the darkening of the skin
when touched by Albertus
silver
nitrate
was known
The
in the thirteenth century.
Magnus
darkening of native
to
silver chloride (horn silver)
on
removal from the mine was described by Fabricius century, and in the seventeenth
in the sixteenth
century Glauber and Robert Boyle speak of the discoloration of silver
compounds, although none
of these earlier writers appear to have suspected the darkening
that light.
The
was due to
the
action
of
distinct statement as to the dark-
first
ening of a silver compound being the result of the influence of light J.
was made by a German physician,
H. Schulze, who
in
1727 observed that when a
solution of silver in nitric_acid
was poured on
to
chalk the precipitate darkened on the side exposed to light,
and he
clearly proved
that this effect was produced
by
by experiment light
and not
1 by heat
All the salts of silver, both inorganic and organic, 1
Eder's
Handbuch der Photographie,
1884, Part L, p.
2.
DARKENING OF SILVER CHLORIDE. are
more or
less
decomposed by
and sometimes only substances. nitrate
is
in
37
especially
light,
the presence of oxidizable
Thus an aqueous
not 'acted upon
solution of silver
light unless organic
by
matter or some other form of reducing agent present.
But although
offer for consideration
photo-chemical action,
the various silver salts
many it
instructive
importance
in
photography,
bromide, and iodide, g^n^ral
The finally
dpsig^Hon
known
of
cases of
be better to limit our
will
attention to those which are of -tical
is
paramount pracviz.
:
the chloride,
to chemists under the
the"spvpr h^lnjHg^/'
fact that silver chloride
becomes
violet
and
brownish violet on exposure to light has
been known since the middle of the eighteenth century, the earliest statement with respect to the precipitated chloride (as distinguished from native "
horn
Baptist
silver ")
being attributed to Prof. Johann
Beccarius of
Turin.
This property, so
familiar to all students of chemistry,
is,
I
need
hardly remind you, utilized at the present time in
our silver printing processes.
The
cases of photo-
chemical decomposition which have been considered
THE CHEMISTRY OF PHOTOGRAPHY.
38
in the last lecture will
you
for
the
first
we must now
chemical change does the
of silver chloride indicate
discoloration
a chemical change, or if
sure have prepared
questions which
What
put to ourselves.
am
I
is
it
?
purely physical
?
Is
it
Is
it,
chemical, a process -of dissociation, of double
decomposition, or of oxidation
?
chemists to consider
esting to us as
be
inter-
how
these
It will
questions have been answered. It
has been held by some authorities that the
change
is
a physical one
;
that violet silver chloride
has the same chemical composition as the unaltered
But
compound. once, because chlorine on
this is
it
view
may
be dismissed at
certain that the chloride loses
exposure to
light,
a fact
Scheele so far back as the year 1777.
shown by numerous analyses chloride chloride.
is
poorer
This
in
may be
that the change
is
It
that the
chlorine
known
to
has been
darkened
than the white
regarded as a direct proof
a chemical one, and there are
moreover several methods by which the liberation of chlorine, or at any rate some chlorine containing gas, can
be directly demonstrated [A]. Then we
LOSS OF CHLORINE
BY
have indirect proof that chlorine fact that chlorine absorbents,
CHLORIDE. is
39
given off in the
such as silver
nitrate,
stannous chloride, or organic substances, accelerate the photo-chemical decomposition, thus reminding us of the action of alcohol
under the influence of
light.
On
chloride
ferric
upon
the other
hand
oxidizing agents which tend to prevent the absorption of chlorine, such as mercuric or stannic chloride, ferric salts,
or chlorine
decomposition,
or, if
prevent
it
itself,
retard the photo-
present in sufficient quantity,
altogether [B].
Taking
it
as established that the discoloration
of silver chloride on exposure to light
is
a photo-
chemical and not a photo-physical action,
we have
next to push our inquiries farther and to ask what chemical difference exists between the violet and white chloride.
Beyond the
chloride contains less chlorine
that our chemical It
may be
knowledge
of service
if I
fact that it
the violet
must be confessed
is still
very deficient.
here point out exactly
what we know and what we do not know with respect to this fundamental photo-chemical position.
You will
find
it
decom-
generally stated in books
THE CHEMISTRY OF PHOTOGRAPHY.
40
that the change
is
due to the formation of a sub-
chloride of -silver according to the equation
4 AgCl
= 2Ag
Now, whatever may be
Cl
+
C1 2
.
the plausibility of this
must not be forgotten that the ex-
it
reaction,
2
:
istence of the
subchloride
is
only inferred from
the analogy of silver with the metals of the copper
group, and
is
not the result of the analysis of the
Amongst the work published by chemists who have studied these com-
pure compound. the various
can find no satisfactory proof that the
pounds
I
subsalt,
Ag
2 Cl,
has ever been isolated
form as to establish
The
in
such a
chemical individuality.
its
notion that the subchloride
is
the product of
the photo-decomposition of the normal chloride
was
first
suggested
reiterated in
why
1814 by Fischer, and was
1834 by Wetzlar, and has since
ceived general see
in
acceptance.
this suggestion
the books as though
chemical truth.
I
be admitted that
it
It
is
not
has found
difficult
its
way
to
into
expressed an established
have already said that silver
re-
chloride loses
it
must
chlorine
SUPPOSED SILVER SUBCHLORIDE. on exposure
to light
that only one of
that the salt
must be reduced to the metallic
the
in
has been assumed
it
two things could happen,
On
or to a sub-salt.
have
hence
;
41
first
viz.
state,
assumption we should
this
mixture of metal
instance a
with unaltered chloride, and in the second case a
Now
mixture of chloride and subchloride.
known
it is
well
that the darkening of silver chloride takes
place under nitric acid, and
it
has also been found
that this acid does not dissolve out
any appreci-
able quantity of silver from the darkened chloride,
so that
it
has been concluded that the latter does
not contain any free metal.
reasoning
known
as exclusion
By it
that process of
has therefore been
assumed that the other alternative holds good that the darkening
is
due to the formation of sub-
chloride.
What
has
modern
chemistry
to
respect to the existence of the subchloride
an d priori point of view stated, the
we
with
say ?
From
have, as already
analogy suggested by the relationship
of silver to copper and
metals form subchlorides.
mercury, both of which
But we
all
know
that
THE CHEMISTRY OF PHOTOGRAPHY.
42
analogy, although at times a very useful guide,
apt to lead us into
to a
much
in the first
safer principle,
work has done of
trusted too im-
difficulties if
Let us turn
plicitly.
is
place therefore
and see what laboratory
late years
towards the solution
of the problem. It
must be confessed that the
direction have been
somewhat unsettling
concerns the sub-salts of
ment
in
always
results in
One
silver.
this
as far as
strong argu-
favour of the existence of these salts has
been
the
suboxide,
supposed
Ag
4
O,
obtained in 1839 by Wohler by reducing the citrate
a current of hydrogen at iooC.
in
2 1 by Muthmann, by Friedheim, and
investigations
by Bailey and Fowler to
me
to
But recent
at
Owens College 3 appear
render the existence of Worrier's, sub-
oxide extremely doubtful, thereby making
all
the
statements about the subchloride being formed by 1
Ber. Deut. Chem. Gescll. 1887, p. 983.
2
Ibid.
1887,
2554 and
p.
Fillitz (Zeitschrift fur
1 888,
p.
307.
See also papers by
Analyt. Chemie. vol. xxi. pp. 27 and 496), by
Spencer Newbury (Amer. Chem. Journ. vol. viii. p. 196) and by der Pfordten (Ber. Deut. Chem. Gesell. 1887, pp. 1458 and 3375
v.
;
and 1888, 3
p. 2288).
Jcurn. C/icm,
Soc. Trans. 1887, p. 416.
SUPPOSED SILVER SUBCHLORIDE. the action of hydrochloric acid upon
43
sub-
this
oxide equally doubtful. 1
Such being the outcome of recent work upon
we may now come back
the suboxide,
main
and
question
the
to
ask whether the darkened
chloride has ever been submitted to such an ex-
amination at the hands of chemists as to have furnished
the
subchloride
of the existence of
evidence
distinct
therein.
In
answer
to
must be admitted that the evidence thus tained
goes
it
far ob-
no farther than to show that the
darkened chloride contains unaltered chloride. cases
this
less chlorine
than the
This result has in nearly
all
been arrived at by determining one con-
stituent only, either the silver or the chlorine,
and
then representing the loss of chlorine as corre-
sponding to the formation of so much subchloride.
By
this
means
different experimenters
different
estimates of the
formed.
Carey Lea
1
The
for
have given
amount of subchloride
example
v.
Bibra
p.
741),
substance obtained by this means has according to
the formula
Ag 4 Cl 3
(Ber.
Deut.
Ghent.
when
states that
GeselL
1875,
but the above quoted investigations tend to show that mixture and not a definite chemical compound.
it
is
a
THE CHEMISTRY OF PHOTOGRAPHY.
44
chloride
silver
days one per
exposed under water
is
cent,
for
five
reduced to subchloride, and
is
Riche asserts that after exposure
for a
year and
a half the formula of the reduced salt corresponds to
Ag3 Cl
2
.
But
methods
such
that
sideration
become evident on con-
will
it
first
its
give
of the
the existence of this salt
assumed and the
buted to
never
to the formation
satisfactory evidence as
subchloride, because
can
is
loss of chlorine then attri-
as clear a case of circular
production
reasoning as one could wish to meet with.
So lief in
far
then
we
get no justification for the be-
the formation of silver subchloride
The
photo-reduction of the white chloride. duct, whatever to
be
it
identified
may as
characteristics with
be,
a the
by the pro-
not definite enough
is
sub-salt
by
its
same sharpness
chemical that
we
can distinguish between other chlorides and subchlorides, such, for
example
as mercuric
curous or cupric and cuprous chlorides. action silver
of solvents which are chloride, such
as
known
to
and mer-
By
the
dissolve
sodium thiosulphate, po-
tassium cyanide, or ammonia, the darkened chloride
ANALOGY WITH OTHER always leaves a residue of metallic again
we
SALTS.
45
But here
silver.
get no real information as to the presence
of a sub-salt, because the existence of the latter
is
assumed and the action of the solvents represented by such equations as these
:
= AgNaSA + NaCl + Ag = + 2KCN AgK(CN) 2 + KC1 + Ag = Cl + 2 Ag. + 3NH [2AgCl + 3 NH 3] 2Ag 2 3 Ag.2 Cl Ag2Cl
+ Na 2 S.
2
3
But these equations seem,
to
say the least of
them, somewhat improbable, because chloride were such an unstable
it
is
darkens under less rapidly,
Now
let
it
is
hardly
could be formed in the presence of
it
such a powerful oxidizer as theless
as to
compound
be decomposed by these solvents likely that
the sub-
if
known
well
nitric
that
nitric acid and,
acid. silver
Neverchloride
although somewhat
even under the strongest acid.
us consider the arguments from analogy
The
and see what value
really attaches to them.
nearest analogues
of the silver haloids are the
corresponding thallium.
salts
Thus
the
of
mercury,
insolubility
copper,
of
and
mercurous,
THE CHEMISTRY OF PHOTOGRAPHY.
46
cuprous, and thallous chlorides reminds us of silver that
so
chloride,
must lead us
analogy shows anything
if
to believe that silver
it
the analogue
is
of copper, mercury, and thallium in the cuprous, mercurous, and thallous chemists
all
by
sometimes
but when
;
it
asserted, as
is
rendered
is
existence of cuprous
or
speaking not analogous
mercurous chloride, the
to.
Silver
understand
terms
so
reality
comparable
that
what
with
strictly
is
chemists pre-
meant by these
white chloride
the
is
copper and mercury,
but to cuprosum and mercurosum will
we
by the
probable
analogy has been over-strained.
sent
admitted
is
find in books, that the existence of a
subchloride
silver
This
states.
these
only
other
is
in
chlorides.
But no chlorides of copper, mercury, or thallium are
known containing
less chlorine
than the cu-
prous, mercurous, or thallous chlorides,
there
is
no warrant
and thus
for believing in a silver chloride
containing less chlorine than the white chloride in other
attempt silver
words, the analogy breaks
to
compare the darkened
with the
lower chlorides
down
if
we
chloride
of
of these
other
ANALOGY WITH OTHER metals, but
is
other subchlorides. this,
If
limit the
silver chloride
and the
we compare
the four metals
we
the only admissible standpoint,
find that the
47
we
if
perfectly legitimate
comparison to the white
from
SALTS.
shall
analogy not only does not favour the
view that the darkened product of photo-decomposition
subchloride, but that
is silver
strong arguments against this view.
many
In the
first
place, the fact that the product of
at
highly- coloured
a
is
photo-reduction is
variance with the
curous chloride resolved
lecture,
mercuric
as
is,
chloride
and
chloride
compound
all
the other
pointed out in the last
I
by the and
that
fact
In the next place mer-
subchlorides are white.
lower
furnishes
it
action
metal
of
and
light
not
into
Then again
chlorine.
into
a the
lower chlorides of mercury, copper, and thallium are perfectly definite salts easily prepared
methods
;
but
presence of it
is
silver is
they
cannot
be
by chemical
formed
oxidizing agents, and that
impossible
to
believe
that
the
compound, which forms under
a subchloride.
in is
the
\vhy
darkened
nitric acid,
THE CHEMISTRY OF PHOTOGRAPHY.
43
It is
hoped that the time which
to be
devoted
the
to
to
proportion
be
not
of silver will
its
told
lectures
things
one
this
salt
out
of
upon
as
but
the
photo-
really
a type
chloride
at starting
you
have
is
concerns our present subject.
reaction as far as I
looked
importance,
of the
decomposition
of
consideration
I
that the
was to enable you
to see
how much we have
of these
object
to
yet
among
other
learn
con-
cerning the chemistry of photographic processes,
and now face
to
the
at
we
outset
find
ourselves
with a fundamental reaction which
face
cannot be
very
satisfactorily
From one
explained.
point of view, however, this
is
perhaps rather a
fortunate circumstance, because you will perceive that there in
is
yet
this direction.
room
Then
for
further
again,
you once ade-
if
quately realize the fact that the
4AgCl = 2Ag 2 Cl+Cl 2 does not rest upon an
mental
basis,
to receive
the
you true
will
absolutely
be
the
investigation
equation
:
,
secure
better
explanation when
experi-
prepared it
comes,
SUPPOSED SUBCHLORIDE.
49
without that severe shock to the feelings which is
generally produced
honoured notions.
graphy
so
is
by the upsetting of time-
Moreover, as
modern photo-
dependent on the photo-
largely
decomposition of the silver haloids, extract
information
the
all
we had
better
we can from
the
chloride before proceeding to the other salts.
To resume
the
argument,
I
will
remind you
then that the ground has been to some extent cleared
by our having
that silver
on
chloride to
exposure
may
undoubtedly, loses
the
subchloride,
a
there
that
is
no
But whatever
Ag2 Cl.
be the chemical composition of this product
of photo-decomposition, it
but
light,
chlorine
evidence that the darkened product
satisfactory
contains
arrived at the conclusion
reduction
we may
product, because
provisionally call
contains less
it
chlorine than the unaltered chloride
;
and
expressing myself dogmatically with
to avoid
respect
to
the formula of a substance which has never been
propose throughout these lectures to
isolated,
I
speak of
this
and of the analogous compounds
simply as reduction products.
E
THE CHEMISTRY OF PHOTOGRAPHY.
50
Now
with reference to the photo-decomposition
of silver chloride,
ordinary
is
it
circumstances
well
known
that
is
of strong reducing (chlorine the reaction
mean
a
is
to say that the
one,
of
product
by which
I
compound does not go on
continuously losing chlorine duction
agents
absorbing)
diminishing
absence
the
in
under
that
a
till
definite
darkened
re-
is
composition
left,
but the amount of decomposition becomes smaller
and smaller and the end result
a
large
small
amount
of
of reduction
investigation such
small and
a
much
that if
a
The quantity
ist.
its
it
is
larger
limit,
so
product
that
difficult
of
chloride
that
one
reduction
has for
plus [C].
made the
product
a It
the
chemis
so
associated or combined with such
amount of unchanged
chloride,
isolation has baffled all ingenuity.
the chloride
get the
unaltered
circumstance
very
a
always a mixture consisting of
is
percentage
this
is
finally reaches
is
exposed
maximum amount
Even
in thin films so as
to
of photo-decomposition,
the difficulty of separating the reduction product
from the unaltered chloride without decomposing
OXYGEN IN DARKENED CHLORIDE ? the former
a serious obstacle to the practical
is
solution of the problem.
But,
may now
it
be asked,
the darkening of the
if
srjuJfrjLV
chloride silver
what be
ot due to the liberation of metallic
is
nor to the formation of a sub-chloride, to chemical
attributed
change
stage to inquire
forward
rejected,
is
change
obvious
sufficiently
may
it
the
discoloration at
necessary
this
what other views have been put Passing over the theory
in explanation.
the
that
be
will
It
?
must
physical, which,
purely
has
reasons,
be considered
in
been
already the
for
first
place
whether the chloride simply undergoes dissociation
under the influence of
light.
The
apparent
absence of free metallic silver in the darkened product existence
and
the
of a
is
therefore
really
It
may
whether
composed only
or whether
it
of evidence
subchloride,
highly improbable. place
want
may
elements of water
render
be asked
the
the
next
in the
product
of silver and chlorine,
essential
must be confessed that
to
such a view
darkened
not contain as
as
in
this
oxygen or the constituents.
direction
E 2
It
there
THE CHEMISTRY OF PHOTOGRAPHY,
52
certainly a great
is
It
investigation.
erates
the
make
the
this
known
is
moisture
that
but
photo-decomposition,
known whether moisture
want of further experimental
in the
is
change
statement
a
not
air
and
arrested.
altogether
with
is
it
absence of
total
accel-
knowledge of
full
made
the numerous experiments which have been
knows how
to test this point, but every chemist difficult it is to
with respect to times
substances
difficulty
of moisture
I
is
it
gases
we have
that
enormous
get
to
of course
allude
gaseous
amount of evidence
that
or both are essential to
of silver chloride, and I
it
within
the
in
and
recent the
last traces
the
to
There
explosions.
pure,
appreciate
of removing
obtained by Prof. H. B. Dixon
on
really
only
learnt
I
results
his researches is
moisture
a
certain
or
oxygen
the photo-decomposition is
for
reason
this
have directed attention to the want
that
of further
1
investigation. 1
According to Abney dry silver chloride sealed up in a Sprengel vacuum does not darken when exposed to light for months. The presence of mercury promotes photo-decomposition. in Photography, 1882, p. 19.
Recent Advances
ABSORPTION OF OXYGEN. That oxygen the
was
chloride
the late Robert
first
announced
distinctly
Hunt 1
,
and
darkening of
the
to
essential
is
am
I
53
by
of the
glad
present opportunity of recalling attention
the
to
work of an investigator who has been so recently removed the
from among
preparation
of the
frequently had occasion
of
this
author,
and
amount of
the large
I
to
on
best described in his "
The
refer to
have
struck with
performed experi-
left
the
on
present
own words
subject
by another very easy experiment.
closed at one end, in
its
was
action
of
1
exposed
sunshine,
frequently
shaken,
in
is
com-
proved
Some
pure
bent
tube
a
and the other end immersed
a bottle of distilled water.
chloride
is
:
bination with the decomposing chloride,
was arranged
The
record.
absorption of oxygen, or rather
chloride of silver
have
I
the writings
been
carefully
bearing
lectures
present
mental work which he has
experiment
connection with
In
us.
for
during for
In
this
state
many days which time
the
to
the
it
was
the purpose of exposing
Researches en Light> 2nd
eel.
1854, p. So.
THE CHEMISTRY OF PHOTOGRAPHY.
54
the whole
of the
tube,
and
silver
on
it
prove
air
this
modern chemical
of
of
1
had taken
criticize
some absorption
that
evident
quite
we
thus ap-
of oxygen
substitution
the
of
under the agency of solar radiation.
atmospheric If
the
of chloride
precipitate
addition of the nitrate,
the
for chlorine
was
a
gave
appearing to
It
As
influence.
its
darkened the water rose into
chloride
the
to
powder
place."
experiment
in
the
knowledge,
it
must
light
be
admitted that the proof that the oxygen which disappears
is
absorbed by the darkening chloride
not perfectly conclusive, because
is
that
the
nascent
chlorine
in
it
the
is
possible
presence
water vapour and under the influence
form some oxide
may solves
in
the
water. 2
of
chlorine
But
in
of
of
light
which
dis-
of
this
spite
A similar experiment is described in The Art of Photography by Dr. Halleur. English translation, 1854, p. 76. 2 It is sometimes asserted that hypochlorous acid is formed 1
<
when
silver chloride
is
decomposed by
light
in the
water, but the equation usually given, apart from
of the existence of the
degree improbable.
4AgCl +
unknown
subchloride,
This equation
HO = 2
is
presence of
its
in
assumption the
is:
2Ag 2 Cl + HC1O + HC1,
highest
OX YGEN POSSIBL Y ESSENTIAL. the experiment
objection
one and
we
necessary
for
under
the
element is
is
supplied
reaction
is
suggestive
a hint that oxygen
get
the
of
darkening
action
of
taken
from
At
light,
but
the
air,
the
chloride
whether
this
or whether
not at present manifest. either
known
to
the free state or in the
in
chemists
that
HC10 + HC1 = The
and hydro-
hypochlorous
earliest record I
H2
+
p. 107)
:
CLj.
can find as to hypochlorous acid being formed
in the report of the British Association
Rep. 1859,
it
the
in
chloric acids mutually react with the liberation of chlorine
is
be
may
by water vapour taking part
If oxygen,
It is well
very
well worthy of further study.
is
rate
any
a
is
55
wherein
taining silver nitrate) in
it is
which
Committee of 1859 (B.A.
stated that the clear solution (con-
silver chloride
had become darkened
gave a further precipitate of chloride on the addition of sulphurous acid, this being considered as evidence of the presence of an oxide of
have repeated
chlorine in the solution.
I
confirm the statement.
It
is
this
experiment, but cannot
true that sulphurous acid produces
a white precipitate, but this dissolves up completely on warming with dilute nitric acid and therefore contains no chloride : not the slightest turbidity
which had been
was observed
in contact
in
a solution
with silver chloride
thus
for
treated
more than
a month, and exposed with frequent agitation to daylight and sunlight during that time.
The same white
precipitate
on adding sulphurous acid to a solution of is no doubt silver sulphite.
silver
is
produced
nitrate,
and
THE CHEMISTRY OF PHOTOGRAPHY. form of water vapour,
of silver
decomposition
for
the
of
the
chemical
contain
some It
oxychloride.
we
future
solution
constitution
of
the
of
the
This view has been suggested more
photosalt.
once,
rigorous
evident
venture to think
I
look
problem
than
that
direction
in this
is
it
chloride,
the nature of an
compound of
must
essential to the photo-
darkened product must
that the
is
is
but
at
rests
it
present
without
state
that
undergoing investigation by
Dr.
may
I
experimental proof.
the
subject
W.
R. Hodgkinson, and although his results are
is
not yet completed, guilty
tains
Ag
4
shall
I
of a breach of confidence
authority that
his
believe
I
the
an oxychloride
0(V
or
of
if
darkened the
I
not
be
state
on
product
probable
con-
formula,
:
/Ag.AgCl
\
\Ag.AgCl
If
we 1
we appeal certainly do
to analogy
get
in
warrant
Dr. Hodgkinson has since informed
this result.
a
me
legitimate
for that
way
believing
in
he has confirmed
OTHER SILVER HALOIDS. the probability of is
analogy
the
exposure to
first
becoming the
the
cuprous
and then
violet
change being
become
but
light,
in
all
to
of
photo-chemistry
work
our
simplify
in
when moist
salt
brownish black,
due to the
now been chloride
silver
dealing
given
with
will
other
the
The remarks which have been made
haloids.
with respect to the supposed with equal iodide
on
[D].
consideration which has
the
discoloured
probability
formation of an oxychloride
The
lowest
the
in
Both thallous and cuprous
state of chlorination.
are white
of copper
subsalts
and thallium, which are already
chloride
The
formula.
forgoing
by the
supplied
57
that
force is
to say
under the
influence
sub-
we have no evidence
Ag 2Br
such compounds as
apply
and
subbromide
the
to
subchloride
of
or
light.
Ag
2
I
formed
are
Silver
that
bromide
darkens on exposure to light and loses bromine, the product finally
becoming of a greyish
violet,
but never as dark as the reduction product of the chloride.
presence
As
in the
of bromine
case of the
absorbents such
latter
as
the
silver
THE CHEMISTRY OF PHOTOGRAPHY.
58
nitrate,
stannous chloride, or organic compounds, photo-decomposition, while such
accelerates
the
compounds
as mercuric, ferric, or stannic chloride
In the
retard the decomposition.
iodide the discoloration
and
the bromide, unless
by
does
not
take
some iodine absorbent
apparently unchanged by of silver
nitrate
or
light,
other
is
The
present.
nitrate
silver
is
absorbent
iodine
it
The darkened
1
more readily decomposed by
acid than the corresponding
all
but in the presence
acquires a greenish grey colour.
product
at
place
is
pure iodide free from excess of
than with
less
is
light
of silver
case
nitric
compound from
the
bromide.
Before leaving the photo-chemistry of the silver haloids
attention
must be
that time will not permit to the
1
According to Abney
(
under these circumstances
secondary reaction.
We
I
regret
do much more
to
salts
recently
Treatise on Photography, 5th ed. p. 24
also Hunt's Researches on Light, off
me
forms of these
coloured
and
called
;
2nd
ed.
98),
p.
but this
oxygen
doubtless
is
have observed that both
and bromide when exposed
to sunlight
give off bubbles of gas, especially
under
when
is
due
;
given to
a
silver chloride
silver nitrate solution
the solution
is
warmed.
COLOURED SILVER HALOIDS.
59
Lea and described by him
obtained by Carey
under the names of photochloride, photobromide.
and
photoiodide.
of
details
Without
1
the
these coloured haloids,
by
produced
methods
various
may
I
of
preparing
state that they are
such as would tend
reactions
give rise to the formation of subsalts these
to
haloids.
The
be partially
that
is
converted
may
silver
suitable
the
a
of
common
of
Thus the photo-
acid.
be obtained of a red colour and
nitrate
silver salt
sufficient
ammonia
chloride.
To
the
in
slight
to
I
formation
its
for
add
excess,
dissolve
ammoniacal
Amcr. Journ. of Science
1887.
from treat-
by
be shown as a lecture experiment. solution
1
reducing
haloid
with sufficient rapidity to enable to
in
should
salt
after being freed
into
ment with the necessary chloride
a
reduced by
agents, and the product, impurities,
(supposing
concerned, expressed
principle
the briefest terms, first
to
admixture with the normal
in
exist)
the
into
entering
May, June,
up
a solution
and
then
the
silver
solution
July,
Taking
ferrous
and November,
THE CHEMISTRY OF PHOTOGRAPHY.
60
sulphate solution
then added and the
allowed to subside,
precipitate
poured
is
the
black
clear
liquor
and the precipitate washed two
off,
The
three
times by decantation.
made
acid with dilute sulphuric acid
cipitate again
liquor
or
now
is
and the pre-
On
washed by decantation.
boiling
the latter with dilute nitric acid, washing as before,
and then boiling with
we
get
reddish
this
dilute
hydrochloric acid,
compound
accordance
in
with Carey Lea's statement [E].
had
have
I
some of the other experiments repeated before the lecture and the results are before you [F],
These coloured "
photosalts" identical
which the author
because he considers
with
the
products
contain
decomposition,
normal
haloids,
haloids,
and
less
the
them
calls
to
be
formed by photothan
halogen
reasons
the
adduced
in
support of the view that the latent photographic
image
is
formed of such photosalts appear to be
perfectly
valid.
however
to
significance
respect
to
The
enable at
the
discovery us
to
present, but I
chemical
is
too
estimate
may
its
recent real
observe with
composition
of
these
PHOTOSALTS.
this
mining
method adopted
the
photosalts that
former
part
of
to say
that
the
assumed
to
is
composition
lecture.
this
been
precisely in
urged this
By
deter-
for
to
open
have
objections which
those
6r
mean
I
deficiency of halogen has
formation
the
represent
of
a
been
a cor-
responding amount of subsalt without adequate
p roo f
may
it
be
due
really
the existence
to
an oxyhaloid compound as an essential con-
of
stituent of the coloured salt.
There which
is
not
lake
worked
chemical with
product
".
further consideration,
little
that the combination "
these recent researches
the suggestion
definite
reduction
a
in
worthy of a
is
and that are
one point
is
It
is
is
at
the
unaltered
of
the
haloid,
but
more of the character of to
chemical
certain precipitates such as
all
who have
analysis
barium sulphate,
and chromic hydroxides, alumina, property of bringing
photosalts
compounds
known
well
practically
that
&c.,
that ferric
have the
down with them a small
quantity of the salts contained in the solution
from which they are precipitated.
The
soluble
THE CHEMISTRY OF PHOTOGRAPHY.
62
thus
salts
form
chemical
definite
precipitates,
but
the
made
by
use
practical
considered
that
the
in
are
very
shows
that
preparation
known
of those coloured compounds
the
This property
exists.
of
to
with
they
washing
some kind of combination is
be
compounds
fact
remove
to
difficult
cannot
retained
as "lakes,"
which consist of some organic colouring matter precipitated
In
the
in
of
presence
alumina
[G].
accordance with this view of the nature of
the photosalts
been
has
it
found
that
silver
possesses the property of retaining
chloride also
small quantities of other metallic soluble chlorides
such as
mercuric,
ferric,
manganese, cobalt, and easily
on
present
mention
that
point
metallic
the
nickel,
washed out of the
the
and
chlorides
which
it
will
silver
form some kind of physical
not
are
As
precipitate.
of
bearing
be of interest to can
be
made
combination
to
with
magnesia, the properties of the metal being so disguised
that
whole of the tion.
The
mercury
silver,
fails
to
extract
the
even on prolonged amalgama-
compound
in
question
is
simply
PHOTOSALTS. formed by precipitating
silver
63
nitrate
with mag-
the precipitate, washing, drying,
nesia, collecting
and strongly igniting the mixed oxides of and magnesium. 1 that
From
the photosalts
may
these results
it
silver
follows
consist of such physical
combinations of unaltered haloid with the reduc-
and
tion product,
information this
is
in the
absence of more precise
the view
of their constitution
which most strongly commends
itself to
of photographic chemists. 1
Friedheim, Ber. 1888,
p. 316.
the notice
APPENDIX TO LECTURE
A
(p.
38
).
The
II.
following experiments illustrate No. i. Silver chloride is
the point referred to
:
prepared by precipitation in the usual way, taking care to use a slight excess of silver nitrate so as to
no
have
free
soluble
After
chloride.
being *
dark thoroughly washed by decantation (in a room ) the chloride is brought into the lecture room in the flask in which it was prepared and '
shaken up with of
water to which a few drops solution have been added.
distilled
sulphurous acid of the clear liquid
Some
is
filtered off into a test
tube and the flask then placed in the electric beam and kept there with occasional agitation for five minutes, filtered
another obtained.
by
side,
when a second quantity of the liquid is The flask is exposed as before for
off.
five
minutes and then
The
a
third
filtrate
three filtrates are then placed side
acidulated with
nitric
acid,
and
silver
APPENDIX. nitrate
added
second gives a
to each slight,
the
:
first
and the
65
remains
clear, the
third a considerable
liberation of showing the gradual chlorine from the chloride which at the same time turbidity,
becomes darkened.
The
of exposing moist silver chloride to light in one limb of a bent tube, the open end of which dips into a vessel of distilled
No,
water,
2.
was
exposed
old experiment
also
for
The
shown.
about
week
a
apparatus figured below
The water from in
had been in
previously
the
-
:
FIG.
chlorine
chloride
i.
the beaker on being tested for way gave a distinct .pre-
the usual
cipitate.
No.
3.
Some
moist silver chloride
is
placed in F
THE CHEMISTRY OF PHOTOGRAPHY.
66
the bottom of a tube and a strip of paper sensitized with potassium iodide and starch suspended above
mouth of the tube being closed by a well cork or india-rubber plug. The apparatus fitting is shown in the figure the
it,
:
FIG.
2.
On for
placing the arrangement in the electric beam about ten minutes the starch paper becomes
intensely blue.
This gives a most striking lecture
demonstration of the liberation of chlorine or of
some
chlorine
containing gas by the action
of
light.
B
The
(p. 39).
made use of
:
following
illustrations
were
APPENDIX. No.
i.
67
Three tubes were exhibited
in
which
silver
chloride (prepared by precipitating silver nitrate with excess of hydrochloric acid and washing by
decantation) had been sealed up, (a) moist in air (&) dried and in dry air (c) dried and in chlorine.
;
;
These tubes had been exposed to
light
some days
before the lecture, the chloride in (a) being very dark, that in (#) less discoloured, and that in (c)
had remained white. No.
Freshly prepared and washed silver was placed with water in two test tubes, one of which a few drops of mercuric chloride 2.
chloride to
solution were added.
On
exposing the two tubes
together to the electric light the chloride in the one containing the mercuric salt remains white, while that in the other rapidly darkens.
C
The increase of decomposition of with the time of exposure was shown by placing a sheet of paper coated with the chloride 50).
(p.
silver chloride
beam
light, and covering up means of a black paper portions by screen after exposures of five, ten, and fifteen
in
the
of electric
successive
minutes.
D
(P-
chloride
57)-
may
The photo-decomposition of cuprous be shown and makes a most striking
lecture demonstration.
The two
following experi-
ments can be performed before the audience No. i. Cuprous chloride is prepared by boiling :
F 2
THE CHEMISTRY OF PHOTOGRAPHY.
63
cupric oxide and scraps of copper
hydrochloric acid
till
foil
with strong
the solution becomes clear.
After being allowed to settle for a few minutes the clear solution is poured into cold water contained
an upright glass cylindrical vessel (gas jar), and the white crystalline cuprous salt immediately settles down to the bottom. The clear liquid is in
poured off and the precipitate washed once or twice with distilled water by decantation, an operation
which takes but
little
time owing to the rapidity
with which the heavy crystalline salt subsides to the bottom. The cylinder is then placed in the electric light when the cuprous chloride towards the light becomes almost black in 5 10 minutes, the side away from the light remaining
beam of
white.
No. clean
A
polished copper plate with a perfectly surface is immersed in a strong neutral
2.
solution
of cupric
chloride (prepared
by
boiling
hydrochloric acid with cupric oxide in excess)
a uniform
This in
is
film
of a greyish colour
is
till
obtained.
best done in an ordinary photographic dish,
which the solution can be rocked to and
over the
surface
of
the
plate.
In
about
fro five
minutes the plate is removed, washed with water and drained on blotting paper and then exposed, the surface being slightly moist, under a design cut out in black paper, to strong electric light for at
APPENDIX.
On
least ten minutes.
69
removing the black paper
the design
appears distinctly photographed, the exposed portions being darker than the protected This experiment has been adapted for portions. lecture
from
purposes
Priwoznik
(Ding.
Poly.
Journ. Vol. ccxxi., p. 38).
E way 8
(p. 60).
The experiment was shown
described
10 minutes for
F
the text.
in
its
A
(p. 60).
It
requires
completion. of the
specimen
rich
in the
about
purple
photobromide was exhibited, prepared according to Carey Lea's directions which are here subjoined :
3
grams
nitrate are
silver
dissolved
in
100
c.c.
water and ammonia added so as just to redissolve
The ammoniacal
the precipitate. is
of
100
poured into ferrous
silver
solution
water containing 6 grams
c.c.
sulphate in solution. To the mixed 2 grams of pure caustic soda
add
solutions
dissolved in 25 short time
of water, allow to stand for a
c.c.
and then add 2\ grams of potassium
bromide dissolved
in
a
little
water.
Make
the
mixture acid with dilute sulphuric acid, wash the residue thoroughly
by decantation, and warm
(it is
safer not to boil) with dilute nitric acid (1*36 sp. gr.
acid with
G
5
(p. 62).
strikingly
bulk of water). The formation of a lake
times
its
shown by taking a
a hot solution of
ammonium
can be
large flask containing alizarate (prepared
by
70
THE CHEMISTRY OF PHOTOGRAPHY.
adding commercial alizarine paste to the water and then a few drops of ammonia), and then adding to the hot solution, which is of a deep purple colour, first
some sodium carbonate
solution of alum.
solution
The coloured
lake
and then a is
at
once
precipitated and on pouring the contents of the flask on to a filter the solution comes through quite colourless.
LECTURE Theory of the Action of
III.
Sensitizers.
The Colour Change Indication of
of the Silver Haloids not a Quantitative their
Relative
Sensitiveness to
Modern Photography. Talbot.
The
Joseph
Collodion
Wedgwood,
Foundation of
I>avy,
Niepce and
Nice'phore
Wet
Light.
Plate
Process.
Fox
and
Daguerre.
Collodion
Dry
Plates.
IN the
last lecture
photo-chemistry
we devoted
of
the
silver
ourselves to the
haloids
without
special reference to their photographic utility,
without
taking
into
consideration
any
and
other
circumstance than that they are decomposed by the action of light with the liberation of a portion of their halogen. this
It
appeared incidentally that
photo-decomposition was accelerated by the
presence of halogen absorbents and that in the
THE CHEMISTRY OF PHOTOGRAPHY. of
case
the
iodide
some
such
was
substance
absolutely essential in order to render the product
We have
of decomposition visible. a
little
more
closely into the theoretical bearing of
this principle in order that
we may approach
practical part of our subject with
We have
next to inquire
in fact arrived at the
the
due preparation.
border-land between
photo-chemistry and photographic chemistry, and it
will
be advisable to commence with a com-
parative study of the three haloids.
From or in
the fact that halogen absorbents facilitate
some
cases are absolutely indispensable for
the photo-decomposition of a silver haloid,
we may
deduce a general principle which can be expressed in abstract
terms and which
will
be useful for
we say that a substance is composed of the elements A and B we simply mean that the compound A B is in a state of chemical further progress.
equilibrium
If
that
it
stable
is
If
from external sources either
in the
some
librium tends to
become
ordinary
energy be supplied
conditions of temperature.
electricity, or, in
under
form of heat or
instances, light, the
upset, that
is
equi-
to say the
THEORY OF SENSITJZERS.
73
compound tends to become resolved into A + B. Now some compounds have the equilibrium of their internal chemical forces more readily upset by one form of energy, and others by some different kind of energy. Thus the silver haloids which are so readily
decomposed by
Why
under the influence of heat. the case
are
light
why some compounds
very stable
this
should be
should be sus-
ceptible to ihe influence of one form of energy
others to another form of energy
molecular physics into which
The compounds which
is
and
a question of^
we cannot now
enter.
the photographer has to
deal with are of course those which are especially susceptible to the action of light.
The
first
principle
of
point in connection with the general
which
I
am now
considerable
importance,
circumstance that
nothing of
its
about to develop
it is
if
only
from
the
.having an important bearing on
The
point
is
are liable to estimate the action of light entirely
change which
one
apt to .be overlooked, to say
photographic operations.
compound
is
it
by
the
amount of
undergoes.
In
that
we
upon a
visible colour
consequence of
THE CHEMISTRY OF PHOTOGRAPHY.
74
we may over-estimate
this
the sensitiveness of
compounds and under-estimate
we may
fail
compound
is
to
altogether
acted upon
shows no change
by
that of others, or
simply because
optical accident, to bear in is
mind
after
it
is
a highly
only a chemico-
all,
and we must be careful therefore
amount of colour change
that the
no absolute measure of the amount of decomposi-
tion
that
different
is,
of the relative sensitiveness of the
compounds which may be compared with
respect to the action of light
Supposing then we
upon them.
have
a
compound
AB
capable of being resolved by light into A-f-B,
may the
compound A C with
sitiveness of
more
reason
AB
is
;
capable of forming
increased,. or the
AB
of the substance
of interest to bear in
mind
facilitates
words the sen-
in other
sensitive to light than
we speak
C
A or B C with B
the photo-decomposition
It is
it
be regarded as a general principle that the
presence of another substance
is
a
But the circumstance
that the product of photo-decomposition is,
that
recognize
light
in colour.
coloured substance
some
system
AB+C
alone, for
C
which
as a sensitizer.
that the sensitizer
THEORY OF SENSITIZERS. may
75
be a simple or compound body and that
may be either
in
any
state of physical aggregation,
gaseous,
examples
many
a
paper acts as
:
such as silver
salts,
To
or solid.
liquid,
and potassium dichromate
it
i.e.
give a few
sensitizer
towards
nitrate, ferric chloride, ;
alcohol
and ether act
as sensitizers towards such salts as the ferric, auric,
and
As an example
platinic chlorides.
sensitizer sition
of a gaseous
hydrogen accelerates the photo-decompo-
of silver chloride. 1
The
foregoing remarks will suffice to function
the. true
point to which
I
make
clear
of a sensitizer, and the next
wish to
call
your attention
an
is
extension of the general principle which has some
photographic
A B-f C
the. system
AB
importance. is
The
not only greater than that of
alone, but .its sensitiveness
affinity of
point
C
more
for
fully
A
of
sensitiveness
or B.
is
Let
by an appeal
a function of the
me
illustrate
to a special
this
case.
Silver chloride in the presence of silver nitrate
more
Is
sensitive to light than silver chloride alone
because silver nitrate 1
is
a chlorine absorbent.
Hunt's Researches on Light, 2nd ed.
p. 78.
On
THE CHEMIS TR Y OF PHO TOGRAPHY.
76
the other hand, as
I
stannic or mercuric
decomposition of
showed
the last lecture,
in
the
retards
chloride
silver chloride
photo-
because these
salts
not only have no affinity for chlorine, but they tend to prevent the liberation of that element.
compare
silver chloride
moistened with
nitrate solution, (2) with water,
tion of
stannic chloride,
system AgCl + AgNO 3
and
is
more
system
with a soluthat the
sensitive than the latter
AgCl + SnCl 4
,
chlorine readily enters into reaction with less
readily with
H
2
we
(i) silver
we should say
system AgCl-f H 2 O, and that the sensitive than the
(3)
If
O, and not at
is
more
because
AgNO
3,
with SnCl 4
all
[A].
Bearing these considerations
now
in
mind we
shall
find ourselves in a better position to deal with
the comparative action silver haloids.
If
of light upon
we expose
the three
three strips of paper
coated respectively with the chloride, bromide, and iodide of silver,
we
shall
find
.that
with
equal
exposure the chloride darkens considerably, the
bromide
slightly,
and the iodide not
Experiences of this kind formerly gave
at
all
rise to
[B].
the
ORDER OF DARKENING. impression that the chloride
bromide and the
light than the tive
is
77
more
sensitive to
latter
more
The papers used
than the iodide.
sensi-
in
this
experiment have not been specially sensitized they have been prepared
in
each case with an
excess of soluble alkaline haloid so as to insure the
absence of free silver
paper and moisture, question
now
be interpreted
nitrate.
The same
sensitizer,
The
present in each case.
is
before us
is
How
:
are the results to
?
In working out the answer to this question AVC shall
be enabled to apply the general principles
which have already been
laid
down.
You
are
prepared for the possibility that the amount of discoloration
may
not be a measure of the relative
sensitiveness of the three haloids,
and you are aware
that the sensitiveness of the salts depends also
the nature of the sensitizer.
suggests itself therefore
is
sensitiveness of the
silver
varied
by a
at
sensitizers.
pleasure It will
into an abstract
The
first
whether the
relative
could
not be
haloids
proper
selection
be instructive to put
form
:
upon
idea that
this
of idea
THE CHEMISTRY OF PHOTOGRAPHY.
78
A B+C
The system
more or
is
C
light according to the affinity
If
constituents, say B.
D
compound,
same
sensitive
sensitizer C, the
DE+C
sensitiveness of the system
compared with that of
one of the
for
we have another
E, and use the
be
may
A B-hC, because
fairly
we have
then only to consider the relative stability of
and the
and
DE
and the
relative affinities of
same substance
E
is
equal,
AB
compounds
then
and
the
DE
C
sensitiveness
measured
is
AB
B and E
If the affinity of
C.
to
less sensitive
for
for
of
B
the
by the
amount of decomposition which they undergo with the same amount of exposure to light On the other hand
if
AB
and
D E
are
sitive, their relative sensitiveness
by
selecting
different this
degrees
case
systems
some
other
of affinity
we have
for
equally
might be varied
sensitizer for
sen-
F
B and
consideration
:
AB + C AB + F
(2)
DE+C
(3)
DE + F ......
(4)
(i)
having E.
the
In four
COMPARATIVE SENTIVENESS OF HALOIDS. If the affinity of
F
C
for B, then (i) will
C
If the affinity of for
B,
B
is
greater than that of
be more sensitive than
for
B
is
It is quite
the changes on
all
gather that even
D E, of
F be
will
unnecessary to go on ringing
the systems, but you will readily if
we had two compounds
which the
stable than the second,
first
AB
was absolutely more
we might
equalize or even
reverse their relative sensitiveness sensitizer
(2).
than that of
less
then the order of sensitiveness
reversed.
and
for
79
selecting a
by
which had a much greater
affinity for
B
than for E.
Now we may
descend once
more from
the
general to the special and consider a particular In order not to complicate matters too
instance.
much we
will limit ourselves to
only, say the sensitizer
bromide and
two of the haloids
iodide.
If
we had
a
which entered into reaction with bromine
more readily than with iodine we should bromide more sensitive than the iodide
;
find the
on the
if
we had a substance capable of fixing more readily than bromine we should find
other hand iodine
the
order
of
sensitiveness
reversed.
I
may
THE CHEMISTRY OF PHOTOGRAPHY.
8o
mention incidentally that
this state
of affairs
actually seen in photographic processes.
mean as
to
may
I
is
do not
imply that the causes are quite so simple
appear from the reasoning, but there
doubt that the main principle
Thus
indicated.
is
of the
is
no
nature
has been found that in some
it
processes the iodide
is
more
than the
sensitive
bromide, while in other processes the bromide has the advantage. In considering the comparative action of light
upon the three
silver haloids
that no absolute
term tizer
"
and
therefore evident
meaning can be attached
sensitiveness
used,
it is
"
we
unless
when
even
to the
specify the scnsithis
done
is
our
ignorance of the degree of affinity between the
halogen and the sensitizer often renders
it
very
is
the
best
If
we take
-
difficult
adapted
to for
predict which
sensitizer
any particular
haloid.
three strips of paper coated with the three haloids,
paint on each a stripe of the solution
and expose
the action of light,
all
we
same
three for the
shall find the
sensitizing
same time
to
same order of
darkening as with the unsensitized papers
the
DARKENING OF THE SILVER HALOIDS. chloride darkens
most and the iodide
only effect of the sensitizer
is
to
discoloration in all three cases [C].
least.
From such an
decomposition.
the
to
the degree
relative instability of the three haloids is
The
accelerate the
experiment we gain no information as
of darkening
Si
no measure of the amount of There
may be
just
much
as
more of the bromide decomposed than there
is
or
of
the chloride, only the oxychloride, or whatever the
product of decomposition
may
be,
more
being
highly coloured than the oxybromide, makes the greater show,
and the same comparison can be
made between
the bromide and iodide.
to
make
perfectly
the
comparison
fair,
we must
amount of
the
haloids
not only disregard
discoloration but
have the same
the
the sensitizer must
affinity for the three halogens, or
different sensitizers
must be chosen, so that the
halogen-absorbing power cases.
between
In order
is
the
same
Such conditions would be very
realize in practice, but the
in all
three
difficult to
conclusion which
may
be drawn from this discussion of the comparative action of light
upon the three haloids
is
that for
G
THE CHEMISTRY OF PHOTOGRAPHY.
82
photographic purposes the order of sensitiveness bears no relationship to the
and may be If
in fact quite the reverse
we apply
that there
iodide
most
is
order of darkening
physical considerations
the least stable and
stable, the heats of
Ag, Cl Ag, Br Ag,
I
we
shall see
every reason for believing that the
is
haloids being
of this order.
the
chloride
the
formation of the three
:
.
.
.
.
.
.
29,380
.
.
.
22,700
.
.
.
13,800
gram
But although we are now able
units.
to look
upon the
degree of photo-discoloration of a silver haloid as a character quite distinct from
photographic sense,
it
its
sensitiveness in the
can be readily understood that
the earliest efforts were directed to that
compound
which undergoes the greatest perceptible change on exposure to
light.
This brings us to the beginning
of the art of photography in the year 1802,
when
Thomas Wedgwood and Humphry Davy published
an account of a process
for
copying pictures
WEDGWOOD, DAVY, AND FOX TALBOT. painted on glass or profiles cast by a strong
by means of paper or
83
light,
leather impregnated with a
solution of silver nitrate or coated with the chloride.
The
delineations thus produced were of course but
transitory because, on exposure to light, the un-
darkened portions of the design also darkened and the
picture
agent had
adds
" :
gradually
at that time
Nothing but a method of preventing the
by exposure
to the
day it is
made by Fox Talbot
in 1839.
to the
this
is
being
wanting to
elegant"
step in the direction indicated
Royal Society
from
delineation
render this process as useful as
A
fixing
been discovered and Davy
unshaded parts of the coloured
No
disappeared.
by Davy was
In a communication
experimenter described a
process for coating paper with silver chloride,
and
for obtaining impressions of objects placed in con-
tact with the prepared surface
The advance upon
by exposure
the experiments of
and Davy was however but
efficiency
Wedgwood
slight because the fixing
agent used was very imperfect in fixing agent
to light.
its
action.
was a solution of common
This
salt,
the
depending upon the solvent action of
G
2
THE CHEMISTRY OF PHOTOGRAPHY,
34
sodium chloride upon those portions of the chloride unacted
necessary
to
upon by
say that
It is
light [D].
these
earliest
silver
hardly
Talbotypes
were of no permanent value owing to the imperfect removal of the unaltered the process has
because
we have
importance
this discovery the first pro-
in
its
modern development we
as a silver print.
be of interest to
It will
add that the fixing agent now sodium
nevertheless
;
a certain historical
duction of what in
know
silver salt
in
general use,
was known to Sir John
thiosulphate,
Herschel as far back as 1819, and the application of this salt was described to the
Fox
in
in
1839
Royal Society, read shortly
a paper
after that
by
Talbot.
Although to give will
by hirn
it is
no part of
my
scheme to attempt
you a complete history of photography,
be advantageous at
historical order,
and
matter of duty to
who have
in so
name
doing
it
keep to the
becomes only a
the different investigators
helped to develop the art to
state of utility.
Davy and
this stage to
of
The
Fox
it
processes of
its
present
Wedgwood and
Talbot, with which
we have
JOSEPH NICEPHORE NIEPCE.
85
hitherto been dealing, were all based on the visible
discoloration of a silver salt under the influence of
and although such prepared surfaces were
light,
well adapted for the production of prints they were
not sufficiently sensitive to record the image formed
by a
lens
that
is
the camera picture with
gradations of light and shade.
The
efforts
fixation of this
camera image, and
in
were directed to the discovery of some sub-
former lecture
I
to fix
first
known
This investigator made his
in
1829, after fifteen years'
upon various substances. this date
work
Five years previous to
another French experimenter, the painter
Daguerre, had in
who was
a camera picture on a sensitive
surface of bitumen.
process
In a
called attention to the experiments
of Joseph Nicephore Niepce of Chalons,
and
view
all their
stance sufficiently sensitive for the purpose.
the
its
great desi-
deratum which the early experimenters had
was the
all
commenced work upon photography,
1829 he and Niepce entered into partner-
ship and prosecuted their experiments conjointly.
Niepce died
in 1833,
and Daguerre continued the
experiments upon iodized
silver plates,
which had
86
THE CHEMISTRY OF PHOTOGRAPHY.
been commenced during his partnership, the out-
come of these as the
researches being the process
known
Daguerreotype, which was announced
in
1839, a year of memorable importance in the history
of photography because this was the application of a silver
compound
first
practical
to the fixation
of a picture formed by a lens in the camera.
The system of Daguerre has now passed out of the domain of practical photography, but we shall see subsequently that this old process to teach us.
method
is
From our
still
has
much
present point of view the
of the greatest importance, because
it
brings us into contact with a kind of photo-chemical action which may, at different order to
first sight,
any of the actions with which we
have hitherto been concerned. revealed
by
this
appear of quite a
The
great principle
discovery was that the photo-
reduction of silver iodide could take place without
any
visible discoloration of the
invisible
surface
that an
image could be formed by a comparatively
short exposure, the picture only
when submitted velopment.
becoming
visible
to a subsequent operation of de-
All the photographic processes which
THE DAGUERREOTYPE.
87
have been invented since the time of Daguerre
from
take their departure
this
discovery of the
formation of an invisible image and
its
development
by appropriate treatment.
now propose
I
to pass briefly in review the
more
important of the methods which have been or are of practical
still
not with the object of
utility
giving detailed instruction in the working of the
numerous processes, perly
done
in
a
for this
of
course
could not lectures,
be pro-
and
the
can be obtained from the
necessary information
various works dealing with practical photography. It is
my
object rather to give a sufficiently distinct
general idea of the nature of the operations per-
formed to enable the chemical principles underlying
them
to be understood as far as permitted
present state of
knowledge.
necessarily be brief,
and
deal with the processes i.e.
it
will
up
by our
This review must perhaps be best to
to the
first
the formation of the invisible image.
stage only,
The
sub-
sequent operations of development, intensification, fixing, &c., will
because
be better dealt with separately
we can make
their study a comparative
88
THE CHEMISTRY OF PHOTOGRAPHY.
one, a
method of treatment which
will the better
enable us to extract any general principles that
may
underlie them.
Commencing with
the Daguerreotype,
sensitive surface prepared
we have
a
by exposing a highly
polished plate of silver (or silvered copper) to the
vapour of iodine and bromine alternately, so as to obtain a film of the bromo-iodide of silver.
proper degree of sensitiveness
is
judged by the
colour of the surface, and this requires
much ex-
In the original process iodine alone
perience.
The
was
used, but with pure silver iodide an exposure of from fifteen to
twenty minutes was necessary, so that
portraiture
was hardly practicable
of the process.
It
in the early
was found by Goddard
in
days 1840
that the sensitiveness
was considerably increased
by the use of bromine
in
conjunction with iodine,
and a good Daguerreotype plate can now be prepared of about the same degree of sensitiveness as a wet collodion plate.
The
early efforts
been alluded
to.
of
Fox Talbot have
already
Shortly after the introduction of
the Daguerreotype this experimenter
made known
THE CALOTYPE PROCESS. an improvement upon his former process,
which
in
the sensitized paper was coated with silver iodide instead of the chloride, and a mixture of gallic acid
and
siver nitrate
was used
as a developer.
It
may
be mentioned incidentally that the discovery of this J.
developer
iodide acid,
ing
be due to
to
The complete method
B. Reade.
a picture
said
is
of obtaining
by exposing paper coated with
and
Rev.
the
sensitized with silver nitrate
silver
and
gallic
developing with the same materials and
by sodium
Talbot
in
Calotype.
thiosulphate,
fix-
was patented by Fox
1841, the process being
known
as the
Improvements were subsequently made
by many workers
the sensitiveness of the paper
;
was increased by the use of a mixture of bromide and iodide modification
instead
of silver iodide alone,
being due
to
this
Blanquart-Evrard of
Lille.
The advantages
of these paper processes over
the Daguerreotype were that in the picture
was more
artistic,
surface instead of on a
first
place the
being on a dull paper
polished metallic mirror
which had to be viewed at a particular angle, and
THE CHEMISTRY OF PHOTOGRAPHY.
9o
next place the paper photographs could be
in the
used as negatives, from which a large number of positive prints could be obtained, the Daguerreo-
type
plate
One drawback
purpose. the
of course
being
want of
gularities in
unsuited
to these processes
and the
definition
for
frequent
this
was irre-
the prints, due to the coarseness cf
the paper fibre and the consequent inequalities in the transparency of the paper negative. this,
Blanquart-Evrard proposed
the paper negative by coating
and
in
in
1
To
obviate
848 to improve with albumen,
it
1849 Le Gray employed gelatine for the
same purpose. troduced the negatives,
This
last
method
and by
this
of
photography from
waxing the Calotype
who
Through the kindness has been associated with
its earliest
days,
show you some waxed paper prints obtained from them,
able historical
in-
means rendered them more
transparent and uniform.
of Mr. John Spiller,
experimenter also
interest,
I
am
enabled to
negatives,
and the
which are of consider-
being the work of
Fox
Talbot himself.
The
defects in the paper negatives
which have
THE NIEPCEOTYPE. just
91
been alluded to led as a natural result to
attempts to obtain negatives on a surface of greater uniformity and transparency, a glass plate being of course the
most
suitable
for
this
purpose.
It
appears that a successful photograph on a film of silver chloride deposited
was taken as
far
on glass (by subsidence)
back
as
1843
Sir
by
John
Herschel, but the difficulty of obtaining films this
method was too great
become generally
by
to enable the process to
practicable.
The
first
introduction of glass plate photography
successful
due to
is
Niepce de
St. Victor,
who about
the year 1847 tried various substances
nephew of the older Niepce,
for coating the plate, the first of these
paste which was soon replaced the whites
of eggs.
Niepceotype after
its
The
by albumen from
process,
discoverer,
being starch
was
known
as the
carried out
by
coating the plate with albumen previously mixed
with a solution of potassium iodide and, when dry, the film was sensitized
by immersion
nitrate bath, a layer of silver iodide
substratum being thus formed.
in
a silver
on an albumen
The
prints
from
these albumenized glass negatives were a consider-
92
TtiE
CHEMISTRY OF PHOTOGRAPHY.
able improvement
upon those obtained from Calo-
type waxed paper negatives. to
mention that
in
It will
1849 Blanquart-Evrard showed
that these plates could also be so that
we have
here the
Numerous
photography.
be of interest
employed when dry,
first
hint at dry plate
modifications and
im-
provements have been made from time to time
in
the original process of Niepce, but these do not
new
bring us into contact with any essentially principles.
The next advance
in
photography brings us to
the use of collodion as a substratum for the silver
The employment
haloid instead of albumen. this material in
was
first
suggested by Gustav
1850 and was made known
by Scott Archer
in
1851.
of
le
Gray
in a practicable
form
To attempt
anything
approaching a complete description of this process
would necessitate more than an
entire lecture
would moreover take us beyond our present of treatment. here that
till
It is
and
limits
no doubt well known to
all
within the last few years the collodion
process was the only one which could claim to be in general use
by photographers.
I
will
endeavour
THE COLLODION PROCESS. to compress a concise account of the
93
main
features
of the process into the shortest possible space.
Collodion
is
by
prepared
products obtained
nitrated
from
in the
is
which
the
is
product
C 12 H 14 O 10 (O.NO 2) 6 and
of the
is
is
By
extreme
cellulose hexanitrate,
insoluble in alcohol-ether,
the lower nitrates only being dissolved solvents.
Gun-
was discovered by Schonbein
This compound ,
and
nitric
appropriate strength.
nitration of cellulose, in 1846.
a
form of cleansed cotton wool and
of
sulphuric acids
in
cellulose is
by means of a mixture of
nitrated
cotton,
cellulose
The
mixture of alcohol and ether.
employed
certain
dissolving
by
these
stopping the nitration short of the
production of gun-cotton, which can be done by
employing a mixture of with a
and
little
nitric
and sulphuric acids
water, the trinitrate,
tetranitrate,
C 12 H 17 O 10(O.NO 2)3
C 12 H 16O 10 (O.NO 2)4
,
are formed and
these possess the necessary solubility, constituting
what
is
known
as collodion pyroxylin.
In addition
to this difference in solubility, gun-cotton
is,
as
you
know, much more inflammable and burns with greater velocity than collodion pyroxylin [E].
It
94
THE CHEMISTRY OF PHOTOGRAPHY.
will
be
well
mention here
to
passing that
in
nor the soluble pyroxylin are
neither gun-cotton
nitro-derivatives in the sense
known
to chemists,
but are organic nitrates of the type of ethyl nitrate,
C 2 H 5 .O.NO 2 is
,
it
desirable to mention this
on
works
many
formulae
C 3 H 5 (O.NO 2 ) 3
trinitrate,
glyceryl
thought
or the so-called nitro-glycerin which
because
in
the
chemistry
photographic
are written
have
I
.
though the pyroxylins
as
were true nitro-derivatives.
When
collodion
of a perfectly clean ether
poured on to the surface
is
evaporate rapidly and leave a beautifully
uniform
of
film
transparent
order to pre-
In
pare the photographically sensitive collodion
"
is
salted
iodide
soluble
the two.
or
bromide,
the
immersion
or
The
monium
in
"
bromide
salts
a
with the
iodide
plate
bath
of
and
are
nitrate
bromide or iodide
in
of
am-
cadmium
sensitized
being silver
some
it
mixture
a
usually employed
cadmium coated
or
the
surface,
dissolving in
by
which
pyroxylin
adheres firmly to the glass.
reacts,
and
glass plate, the alcohol
the
by
which film,
COLLODION DR Y PLA TES. giving a layer of
silver
double decomposition
95
bromide or iodide by
:
NHJ + AgNO = Agl + NH NO 4
3
3
CdBr2 +2AgNO 3 = 2AgBr + Cd(NOa) a
The
plate
is
exposed
in
a moist state, that
is
to
say, covered with a film of adhering silver nitrate solution.
It is
mind because that
is
important to bear this condition
it is
this film of silver nitrate solution
essential as a sensitizer
having no sensitizing
action
are sufficiently well
We
;
the collodion
absorbing
halogen
power,
itself,
no
has
[F].
The inconveniences of
it.
in
the wet collodion process
known
to
all
who have worked
need only consider the cumbrous equip-
ment required
for field
work and the
difficulties
of
carrying about and working in hot climates with a
solution
containing
ether.
Soon
after
the
introduction of the collodion wet plate process the first
attempt to prepare collodion dry plates was
made by Taupenot
in
1855,
and
this process
was
ultimately developed through various stages into a
THE CHEMISTRY OF PHOTOGRAPHY.
96
method
useful
really
Russell.
It
must
1861
in
by the
here to point
suffice
principles concerned in this
most
Col.
late
out the
advance
distinct
photographic methods.
in
The
of dry
object
furnish a sensitive
which can be kept
film
required for use, and which for
without
exposure
to
is
photography
plate
is
any time ready
at
to
having
till
the
undergo
operations of coating and sensitizing immediately before
placing
difficulty
in
which had
the
The
camera.
was the tendency of the collodion off the
the
plate
when
dry,
to
film
peel
when submitted
or for
to
dry
plate
develop-
holds
the
requisite
firmly to the glass
ment.
be met
Some substratum which
operations
ment.
practical
in the first place to
is
therefore
In practice the plate
is
albumen or gelatine or with
the first
a
first
film
require-
coated with
film
of
india-
rubber by pouring a solution of the latter substance in benzene or chloroform over the surface of the glass and allowing the rate.
When
the
substratum
coated with salted collodion
is
solvent
to
evapo-
dry the plate
and
sensitized
is
by
COLLODION DR Y PLA TES. immersion
Up
way.
in
a silver nitrate
bath
97
the operations
to this point
usual
the
in
be
may
regarded as leading to the production of a wet collodion
with
plate
a
film
supported
on
a
substratum of albumen, gelatine, or india-rubber.
But now the plate undergoes further treatment and a
little
explanation
make
will
clear
the
principles concerned in the subsequent operation.
were allowed to dry
If the plate
after
being
taken out of the bath, the silver nitrate in the adherent film would crystallize as in
so
would disintegrate or
doing,
dried and,
it
freckle
the
surface of the silver haloid so that the photographic efficiency
destroyed.
of
the
latter
would
The excess of silver
be
completely
nitrate
is
therefore
removed by washing and, from what has already been said
in connection
with the wet plate col-
lodion process, you will readily understand that in
washing out the excess of
silver
nitrate
we
practically destroy the sensitiveness of the plate.
The
next
surface
operation
of the
film
therefore
is
to
coat
the
with some substance which
will restore the sensitiveness
that
is
with some II
THE CHEMISTRY OF PHOTOGRAPHY.
98
which
substance
plays
function
these
and
are in
after
known
In all
"preservatives"
this
part inasmuch
surface
sensitive
contact with the
the
silver
as
technically
as they preserve the
manner of a
the
Such substances as
drying.
one sense they play
mediate
of
part
wet process and which retains
nitrate film in the this
the
much
air,
from imthe
after
varnish.
early days
of dry plate photography
kinds of substances were tried as preservatives,
and. on looking back of
history
the
art
into
we
this
chapter a
find
collection
formulae which are amusingly grotesque.
only remind you of the tea, beer processes. gallic acid,
these
in
and tannin, the
the
substances
sensitizing
action
first
latter
preparation
gum and
are
being of interest
of dry plates.
organic
sensitizers,
All their
being due to their faculty of
to explain that the preservative
of
need
used successfully by Col.
absorbing the free halogen [G].
surface
coffee,
I
of
Other preservatives are albumen,
as the substance
Russell
of the
the plate after the
It is
remains only applied to the
removal
of the
PRESERVATIVES. silver
nitrate, the
99
excess of preservative solution
being drained off and the plate being then allowed to
dry.
Preservatives
amount of moisture results
as
in the
first
a
far
sensitizer
sensitizer
is
as
which
necessarily
regards
likely to
be
is
next
the in
give
sensitiveness,
place water itself
and, in
a
retain
more
to
slight
the
best
because
some extent
place,
a
moist
perfect contact
with the silver haloid of the sensitive
film.
H
2
APPENDIX TO LECTURE
III.
*
A
(p.
trated
The
points referred to were illustaking a sheet of paper coated with silver
76).
by and painting on
two
chloride
it
solution of silver nitrate,
and
stannic chloride.
On
(2)
stripes, (i)
with a
with a solution of
exposing to the
electric light
few minutes the ground-colour darkens, the stripe (i) becomes darker than the ground-colour and the stripe (2) remains white. The paper is for a
prepared with excess of sodium chloride so as to contain no free silver nitrate.
B
(p.
76).
The papers coated with
were fastened on a board and
same time
C
all
the haloids
exposed
for the
to the electric light.
The
experiment was repeated after a stripe of a solution of silver nitrate had been painted on each of the three strips. The excess of (p.
Si).
last
silver nitrate solution
blotting paper.
should be removed by clean
APPENDIX.
D
The
84).
(p.
solution of
I0 1
solubility of silver chloride in
sodium chloride
is
easily
shown by
a
boil-
ing some freshly precipitated chloride with excess of strong brine and pouring the clear solution into cold water when the dissolved chloride is reprecipitated.
E
The
93)-
(p-
difference Jn the combustibility
of gun-cotton and collodion pyroxylin can be shown by placing a loose piece of each on the
top of a
heap of rather fine-grained gun-
little
powder. The gun-cotton on
ignition simply scatters
the powder, while the slower burning pyroxylin explodes the latter. This experiment requires some dexterity.
F
-(p.
A
95).
collodion
and
the usual
way
glass plate
is
coated with salted
sensitized in a silver nitrate bath in in
"
non-actinic
"
light.
On
removal
from the bath one half of the plate is immersed for a few seconds in a solution of potassium iodide and, after
washing
slightly, a brief
exposure
is
given to
On developing by iron (electric) light. developer the portion of the plate from which the excess of silver nitrate had been removed
diffused
by immersion
in
the
potassium
iodide
remains
white, while the other half rapidly darkens. The action of an organic sensitizer (p. 98).
G
can be shown by coating and sensitizing a wet " collodion plate in " non-actinic light in the usual
102
way.
THE CHEMISTRY OF PHOTOGRAPHY. After removal from the bath the plate is in a stream of water till free from silver
washed
of water drained off on blotting paper, and a design painted on the surface of the plate with a brush moistened with a solution of nitrate, the excess
gallic acid
thickened with a
little
gum.
The
plate
then exposed to the electric light for a few iron or seconds, washed, and developed (by
is
ferrous oxalate developer)
when
the design
ground.
the usual
manner, appears darker than the backin
LECTURE Emulsion
Collodion
Photography.
The Process
Emulsions.
IV.
Emulsions.
Gelatine
Different States
of Ripening.
Extreme
of Physical Aggregation of Silver Bromide. Sensitiveness
Applications of
THE
Modern Dry
photographic
in the last
Emulsion.
of Gelatino-Bromide
lecture
processes
belong
now
the historical
to
is
of
the
highest
interest
a thread of
them which enables
us to follow their development in a is
reviewed
briefly
portion of the subject, but there
continuity running through
Recent
Plates.
for
manner which
those
who
take
pleasure in studying the evolution of scientific discovery.
It
would lead
me
too far astray to attempt
such treatment on the present occasion and
must commence
at once with the latest
we
methods
of dry plate photography, the legitimate offspring
104
THE CHEMISTRY OF PHOTOGRAPHY,
of the collodion dry plate processes last described.
The
collodion
of
and
transport
the ad-
all
as
far
regards
manipulation, but
and,
till
manu-
their
was properly understood, were apparently
facture
their
in
capricious
point of view
we know what it
is
by the
liberated
action
development
subject to which
we
shall
efforts
in
the
introduction
of
1862 by Col. Russell, a
have occasion to return. left
much
of sensitiveness.
The
at their best these
to be desired
the
dry plates was con-
the
by in
of
wet plate process.
of collodion
facilitated
But even
so-called
possessed by a sensitizer such as
The working
alkaline
lack of sensitiveness
means that the
silver nitrate film of the
siderably
chemical
a
have not the same power of ab-
sorbing the halogen light as
From
action.
in this case
preservatives
next
as
of
in sensitiveness
they failed
means
them
of
expected
vantages facility
dry plates possessed
way
dry plates
of photographic experimenters were
directed to the production of silver haloids in an
extremely
fine state of division
viscid sensitizing
suspended
medium which
in
some
could be spread
COLLODION EMULSION.
105
over the surface of the plate and there allowed
The development of
to
dry.
us
down
idea
this
brings
to the photography of the present,
i.e.
to emulsion photography.
As find
with so
many
other useful inventions,
germ of
that the
existence long before
this
it
discovery
bore
came
As
fruit.
far
we into
back
as 1853 Gaudin proposed to use the silver haloids in
the form of emulsions, and
of
details
his
1861
in
Three
experiments.
he gave
years
later
emulsion process was
made
known by Bolton and Sayce, who used
silver
the
successful
first
bromide emulsified collodio-chloride
was
described
now attempt of
paration
which
I
felt
in
collodion
and
;
emulsion for printing
by Wharton
1865 a
in
purposes I
Simpson.
must
to give a brief account of the pre-
these it
emulsions, and
the
remarks
incumbent to make when dealing
with the wet collodion process must be repeated here with
tenfold
meaning
;
for
if
could occupy an entire lecture for
that
its
process
description,
the emulsion processes, owing to their multiplicity
and the
immense
amount of
practical
detail
THE CHEMISTRY OF PHOTOGRAPHY.
106
connected with their working, would demand a
whole course of realize
time that
this
by
you must
But
lectures.
am
I
fully
not dealing with
photographic manipulation, and
I
shall
be obliged
branch of the subject only
to treat of this
in
a
very general way. s~~\
To
a
prepare
emulsion
collodion
the
silver
r*
must be precipitated
haloid self.?
them salt
it-
There are of course several ways of doing
but
this,
the collodion
in
the
all is
one general
principle
and the haloid
that the silver nitrate
with which
it
reacts should
underlying
be brought to-
gether in the presence of a solvent in which the collodion
is
Alcohol
itself soluble.
which meets these requirements, and in
this
liquid
some haloid
solving therein and solution,
salt
salt the
we can then add an
is
the solvent
if AVC
dissolve
capable of dis-
collodion with this alcoholic
solution
of silver nitrate and thus precipitate the silver haloid in the required state of subdivision in the collodion, wherein to
it
remains
the viscosity of the
haloids
suspended
medium.
Of
owing
the silver
the bromide appears to lend itself most
COLLODIO-BROMIDE EMULSION. readily to this process of emulsifying,
and
107
collodio-
bromide emulsions are therefore the more generally
As
prepared.
cadmium
or
the soluble bromide that of zinc
is
usually employed, the
necessary
quantity of this salt dissolved in alcohol being
added to the collodion and then the alcoholic soluof silver nitrate
tion
is
gradually poured
in,
the
mixture being briskly agitated after each addition.
When
the whole of the silver nitrate has
been
added
the
for
some time our
occupy needless
ducted
So
in
cerned
to
ripen,
attention
allowed to stand
is
a
process which will later
again
rationale of the process
is
is
simple
at least as far as the chemistry
but the emulsion
use at this stage.
for a sensitizer in
is
in the
emulsion prepared
It
evident
that
is
con-
by no means ready
Consider for a
moment
to the necessity
the wet collodion process, and
us ask whether there
is
It
red or "non-actinic" light [A].
what has been said with regard
let
on.
say that these operations are con-
far the
enough
for
to
emulsion
the
is
any
in the
sensitizer present
manner
described.
only substance
capable
THE CHEMISTRY OF PHOTOGRAPHY.
io8
of performing this function
and
the silver nitrate,
is
might be imagined that
it
of this
salt
if
the quantities
and of the zinc bromide were so
adjusted as to leave a slight excess of the nitrate
over and above the quantity indicated
by the
equation
ZnBr 2 + 2 AgNO 3 = 2 AgBr + Zn(NO 3) 2
the
all
conditions
But
would be met.
for
necessary
impracticable, and a
this little
plan
is
,
sensitiveness
unfortunately
consideration will
make
clear the reason.
The
emulsion, at the stage where
contains
addition
in
the pyroxylin,
to
a
soluble
and
salts
would
would thus
crystallize
disintegrate
photographic surface. fit
for use
it
is
order to remove
it,
haloid and
silver
by double decomposition.
were coated with
plate
left
excess of silver nitrate and
the
the zinc nitrate formed If
the
we
To
therefore
this
as
mixture
the
and
film dried
destroy
render the
salts,
the
emulsion
washed with water
the soluble
the
and
this
in is
COLLODIO-BROMIDE EMULSION. done either on the plate the emulsion
is
washed
itself after
in mass.
It
109
coating, or
sometimes
is
customary to speak of these two kinds of emulsions as
"
washed
"
and
misleading because latter
"
unwashed," but
after coating
in
bulk after preparation.
to
describe the
emulsion
and the former
would be better
It
as
is
both washed, the
they are
on the plate
this
either film-washed
or mass-washed.
The
preparation of a collodion emulsion
by film-washing
plate
a comparatively simple opera-
is
After the plate has been coated with the
tion.
emulsion the latter
is
allowed to set and then,
before the salts have time to crystallize, the plate is
all
immersed
in
water
diffused out.
It
till
these soluble salts have
might be expected that by
thus washing out the soluble salts the sensitiveness of
owing is
by
the
film
would
be
seriously
impaired
to the removal of free silver nitrate.
no doubt that the sensitiveness this
treatment,
destroyed because,
but in
it
making
is
There
is
diminished
not
altogether
the emulsion, the
quantities are so adjusted as to .have
an excess
i
THE CHEMISTRY OF PHOTOGRAPHY.
io
of
silver
when
and
nitrate,
precipitated under these conditions
more
sensitive than
an
of
excess
of
when formed the
trace
an excess of that
salt
same way other
of silver is
emulsion-coated plate the sensitiveness
is
in
coat
the
After the
preservative before
some
authorities
plate
with
in
the
it
indicated,
case
suffi-
customary
some is
organic
stated
of
the sensitiveness
preservative.
In
is
silver
not increased by the
other words, the retained trace
a better sensitizer than
the
playing no part
this
of silver nitrate
is
preservative, the
latter
kind of emulsion beyond the film
by
collodio-
bromide emulsion prepared with excess of nitrate,
of the
washing
It is
drying, but
that,
the
traces
manner
to
when
found to be
therefore
washed
The
in
just
retains
cient for photographic purposes. to
presence
nitrate
present,
chlorides.
always
no doubt due
is
that silver chloride
soluble
in the
is
bromide under these
different sensitiveness of the
the retention of a
is
it
bromide.
soluble
two modes of preparation
bromide
silver
protection
from atmospheric influence.
in
of the
RIPENING OF THE EMULSION.
When
bromide has been
silver
collodion
manner
the
in
takes
it
maximun
its
in
a
degree of
period of so called "ripening"
sensitiveness, the
varying from
emulsified
described
time to acquire
certain
in
8 to 24 hours
the
to
according
soluble bromide used as a precipitant, the quality
of the collodion, &c. too
loses
it
long
bromide
particles
the
If
in
emulsion
the
sensitiveness,
become denser
is
and
kept silver
tend
to
out of the medium, and the photographic
settle
is
efficiency
Now
destroyed.
behaviour
this
the silver haloid in an emulsion
is
of
of particular
importance to us at the present moment, because this
is
state
the
hint
first
of aggregation
influence
upon
we
get
may
critical
of molecular aggregation
have
shall
have
a
that
of
much more
the to
as
a
soon
as
possible
after
it
bromide.
ha
haloid.
silver
do
with
this
will readily
outcome
practical
property the stock of emulsion as
determining
point in the state
ripening process hereafter, but you
gather
physical
the sensitiveness of the
There seems to be a
We
the
that
must
of
be
ripened,
this
used
and
1
THE CHEMISTR Y OF PHOTOGRAPHY.
12
this
one
is
of
the
of
disadvantages
film-
'
washing.
To
prepare an emulsion by mass-washing the haloid
silver
is
the
in
precipitated
collodion
as before, using either an excess of silver nitrate or an
excess
of
emulsion
the character of the
being allowed to ripen are
evaporated or
gelatinous
the
distilled
emulsion
under
remain
to
water
are thus
sion
is
dry
in
freed
the
according
After
required.
and
ether
and
the
semi-
off,
by being allowed
which
The
is
frequently
soluble crystalline
removed, and the washed
from water by being air
to
alcohol
washed
poured off and renewed. salts
haloid
soluble
spontaneously,
emul-
allowed
to
by heating
"on
a water-bath, or by being washed with alcohol.
The emulsion may
at
this
be
stage
regarded
as consisting practically of a dried silver
pyroxylin that
is
necessary
amount in
the
dry.
jelly,
and to prepare is
it
for
haloid
use
all
to redissolve in the requisite
of
alcohol
and
ether,
usual
way,
apply
the
The advantage
of
coat
the
preservative
mass-washing
is
plate
and that
GEL A TINE EMULSION. a large quantity of emulsion can at
one
deterioration
The more
and
operation
emulsion than
historical
because,
as
you
displaced
by
gelatine
transcend them
with
the
because cally
are
in
was the
the
interest
have
they
which I
greatly
have dealt
some
in
been
detail
emulsion process practi-
we have been enabled
to
although there are neces-
points which
many
practical
emulsions
now
a good general idea of the prin-
it
A
to pass over.
under
of
aware,
first
ciple of emulsification, sarily
without
are
processes
emulsion
introduced, and
get out of
prepared
kept
sensitiveness.
collodion
it
be
3
required for use.
till
collodion
of
may be
1 1
I
collodion
most
have been obliged
emulsion plate, even
favourable
circumstances,
can
seldom be made as sensitive as a collodion wet plate,
whereas
have
from ten to one hundred
sitiveness
The
a
gelatine
emulsion
plate
of a collodio-bromide emulsion
reasons
for
this
increased
will
but we have
consider the process
first
to
plate.
sensitiveness
of gelatine emulsion
appear
may
times the sen-
in
due course,
I
itself.
THE CHEMISTRY OF PHOTOGRAPHY.
ii4
The
use of gelatine as a vehicle was suggested
by Gaudin
in
1853
but the development of the
;
modern process dates from the year R.
Dr.
L.
Maddox made known
of the
details
the
practical
method of preparing a
gelatino-
Of
bromide emulsion. but
little
the chemistry of gelatine
known.
at present
is
when
1871,
It is
a nitrogen-
animal substance extracted by boiling from
ous
bone
cartilage,
skin.
It
connective
sinew,
and
tissue,
appears to be resolvable into two com-
pounds, one derived from the unhardened cartilage
and
called
from the hardened
The of
cartilage
the
other
known
substance constitutes the
latter
the
and
chondrin,
purer
forms
of
gelatine
as
derived glutin.
chief
used
by
part
the
photographer. It will
be advisable to give here a short account
of those properties of gelatine which are connected
with
its
emulsion.
use as a vehicle for the
When
allowed
to
silver
remain
in
haloid
contact
with cold water, gelatine swells and absorbs a considerable
quantity of the
the substance
gradually
latter
forms
a
;
if
warmed
solution,
the
GELATINE AS A VEHICLE.
on cooling to a gelatinous mass
latter solidifying
more or
firm
less
a
in
Eder
used.
is
available
gelatine sions is
confers
it
;
the
dissolved
the
for
the
water
necessary
degree
upon
when C.
It
renders
of emul-
preparation
keeping the finely divided
for
which
property of gelatinising
this
jelly
cooled to 20
is
that
states
good specimen should give a firm
a four per cent, solution
to
according
consistency
of water
the quantity
115
which
in
of viscosity haloid
silver
without
undergoing
decomposition
changes
soon
to
ordinary
temperatures
begin
take
and
chemical
;
even
place
more
still
at
rapidly
The time when decomposition depends much upon the quality of
on heating.
an
gelatine,
but
which
usually slightly acid
is
alkaline
ten
alkaline
of
and
days
the
four
to
in
Moist gelatine cannot be long kept
suspension.
in
it
average
to
begins
or
so.
start
production
high
of
at
evolve
Inferior
with,
quality first,
becomes after
which
may show
ammonia
the
sample,
ammonia
kinds,
sets
are
indications
three
after
days. I
2
or
THE CHEMISTRY OF PHOTOGRAPHY.
n6
As
a point of practical importance
mentioned
be
that
the
gelatine seriously impairs
its utility for its
should of
decomposition
making, not only because is
it
the
emulsion-
power of "setting"
diminished, but also because the products
of
decomposition have a tendency to reduce the
its
silver light,
haloid
i.e.
directly,
without
and thus to give an emulsion which "fogs"
With
on development.
to
respect
the
various
processes for preparing gelatine emulsions refer
to
exposure
you
I
must
works devoted
for practical details to the
to photographic manipulation. 1
I
propose to give
only a sufficiently concise account to enable you
understand the general method of their pre-
to
drawing comparisons between
paration,
gelatine
and collodion emulsions whenever we can learn
any point of importance treatment. familiar,
such
The bromide emulsion
is
mode the
of
most
although for certain purposes the gelatino-
chloride 1
from
emulsion
is
preferred.
The former
will
See for instance Abney's Photography with Emulsions, 1885, or
Eder's Ausfiihrliches
Handbuch der Photographie,
th.
iii.,
"Die
Photographic mit Bromsilber-Gelatine und Chlorsilber-Gelatine," Halle, 1886.
GELATINO-BROMIDE EMULSION. however be
our present
for
typical
sufficiently
117
purpose.
order to prepare an emulsion
In
with
haloid
we may
gelatine,
___
of a
either
silver
mix
the
-
with the gelatine solution
silver nitrate solution
and add the soluble
haloid, or
we may mix
latter
solution
with
silver
nitrate,
ln either case the
same
the
silver
the
is
making a
collodion emulsion.
(sometimes mixed soluble is
haloid
one point
from
a
in
which
no excess of
little
which
mind, and that is
in
the
therein
by
as
it
iodide)
is
in
is
it
that
is
is
the
There
[B],
gelatino-bromide
emulsion
of potassium bromide
the
Potassium bromide
generally employed
collodion
to bear in
with
the
is
precipitated
same manner
in
add
result
emulsified
is
agitation
just
and
gelatine
haloid
and
solution
gelatine
the
the
differs
essential
the quantity
so adjusted as to leave
silver nitrate.
It will
be instructive
to consider the chemical reasons for this difference
between the two emulsions. It
is
a well-known fact that organic colloidal
substances,
such as gelatine and albumen, form
THE CHEMISTRY OF PHOTOGRAPHY.
US
some kind of combination
with crystalline
chemical compounds
An
silver nitrate.
do not say
I
will
experiment
water to which a
we
If
point perfectly well.
salts
like
illustrate this
dissolve
silver
little
definite
gelatine
nitrate
is
in
added,
a certain amount of the salt combines with the
and forms what may be called techni-
gelatine cally
a
"
stable
sufficiently
the
silver
little
this
gelatino-nitrate,"
to
the
disguise
We may
salt.
compound being presence
add
instance
for
potassium bromide or chloride
or
of a
hydro-
chloric acid to such a solution without producing
any
precipitate as long as the reagents
in
excess [C].
if
there
is
a
the whole of
unpleasant
heat
with
oxide of containing
developer
deficiency
the
this
last
the
silver
and
of
or
not
de-
the
photographic
by
light
or
of
metallic
silver
or
some organic compound
which
fogs
is
compound has very
decomposed
formation
silver
potassium bromide
from
is
it
;
of
"gelatino-nitrate"
properties
view
point of
not
In consequence of this property,
Now
composed.
are
the
acts
plate
directly
on
[D].
This
the
of
COMPARISON OF EMULSIONS. means that
course
nitrate
readily understand
and you
latter,
therefore
19
reduced by
is
when heated with the
gelatine will
silver
1
why
it
so
is
important to insure the complete decomposition "
"
of the
gelatino-nitrate
by having a
sufficient
quantity of potassium bromide. In
you silver
a collodion
know
emulsion, on
we may have an excess and this does no harm if it
that
nitrate,
washed out afterwards. there
may
the other hand,
But even
in
this
veloper and
what
is
case
be formed certain organic compounds
containing silver which act directly on
cautions
of
are
these
fog
the
taken.
unless
plate It
compounds
is
special
pre-
exactly known
not
are,
the de-
but
during
the
nitration of cellulose small quantities of oxidized
products are formed which are not removed by
washing, impurities
and in
which the
remain
pyroxylin.
as
contaminating
It
is
these
products which form compounds with the of the nitrate, and in
making a
with excess of the latter salt
add a small quantity of
nitric
bysilver
collodion emulsion it
is
necessary to
acid in order to
THE CHEMISTRY OF PHOTOGRAPHY,
120
decompose these
silver
This
compounds.
precaution Avhich has to be taken, and the reason
now
is
emulsion performs
acid in a collodion
function
work,
hope
a
nitric
similar
the excess of potassium bromide in
to
a gelatine emulsion. its
I
The
clear.
sufficiently
the
is
The
acid, after
of course removed
is
it
has done
by the washing
process.
remembered
be
will
It
collodion
emulsions
when
precipitated
first
that
the
silver
not in
is
property sion
When silver
the
state,
and
is
sensi-
time to reach
ripening.
The same
shown by a gelatino-bromide emulmore in
precipitated
bromide the
much
a
in
first
division,
of
period
bromide
most
its
tive condition, but takes a certain this
with
connection
in
is
size
in
of
striking
the
emulsion
an extremely the
great extent determined
particles
by the
manner.
fine
the
state
being to
of a
state of dilution
or concentration of the solutions of gelatine and silver nitrate
and of the potassium bromide.
size of these finest particles has
The
been determined
by Eder from micrometric measurements
to
be
THE RIPENING PROCESS.
121
from *ooo8 to -0015 of a millimeter in diameter. In
this
but
stage a gelatine-bromide emulsion offers
emulsion
advantage over a collodion
little
Now
from the point of view of sensitiveness. in
was observed by Bennett that
it
1878
gelatine emulsion
a
week
at a
sensitiveness
is
moderate temperature (32
became
increased.
the temperature to 60
C.,
many days
in
ripening
then
the ripening of
by
increasing
a few hours
same
the
producing
the
C.)
was
It
the emulsion could be accelerated
as
a
allowed to stand for about
found by Stuart Wortley that
temperature
if
the
at
this
sensitiveness
cold.
In
1879
Mansfield carried this principle a stage further
and showed that by keeping the emulsion the temperature of boiling water for less
an hour, the could
be
point
in
maximum
reached.
the
history
at
than
of practical sensitiveness
This
is
of our
the
culminating
modern dry-plate
processes.
After the precipitation of the silver bromide in the gelatine solution the
next step
paration of the emulsion
to ripen
is
in the preit,
and
this
THE CHEMISTRY OF PHOTOGRAPHY.
122
done
is
by placing the
vessel
the
containing
gelatino-bromide in a bath of boiling water and it
keeping
there with
occasional
The proportions of gelatine
thirty or forty minutes.
and water given
in
for
agitation
the published formulae, have
been selected by experience as being the best for
precipitating the
silver
bromide In
state of molecular aggregation as
such
a
that
to insure
the ripening takes place in the shortest possible time.
The
reason
of
this
will
subse-
appear
quently.
When
the operation of ripening
the emulsion
cooled
is
the right consistency, strength
by
dilution
gelatine solution.
we have
and,
if
not
made up
is
is
completed already of
to the proper
with a further quantity of
It is
obvious that at this stage
a jelly containing potassium nitrate and
excess of potassium bromide in addition to the silver
bromide.
been explained sions
be
For reasons which have already in
the soluble
removed
connection with collodion emul-
and
before
allowed to dry on
crystallizable
the
emulsion
the plates.
salts
film
There
must
can is
also
be
a
COMPLE TION OF EMULSION. why no
special chemical reason
sium bromide should be
which we later
be
shall
on
therefore washed, being
means
The
in
warm
plates
There
is
gelatine
fascination haloid. is its
have been
salts
the solution
is
is
dis-
redissolved
and the
filtered,
can then be coated with a uniform film
and allowed
a
the soluble
water,
of canvas)
and then treated with
The washed emulsion
solved out.
is
reduced by mechanical
first
to a fine state of division till
emulsion,
emulsion
cold
through the meshes
(forcing
cold water
the
a better position to appreciate
course.
this
in
in
23
excess of potas-
in
left
1
to dry.
one operation
in the process
emulsion which I
possesses
certainly a very remarkable investigation, utility,
results in the
researches
of
a
certain
allude to the ripening of the silver
The gradual change
practical
of making
apart
from
cannot but
in
molecular state
phenomenon, and the
lead
domain of molecular investigators
question to
of
important
physics.
The
who have occupied
themselves with this subject, and especially those of
Van Monckhoven,
Eder, Abney, and Vogel,
THE CHEMISTRY OF PHOTOGRAPHY.
124
tend to show that the change
The
one.
by and
increase in sensitiveness
is
accompanied
probably the result of an actual increase
is
the size
in
a purely physical
is
of
the
of
particles
The micrometric measurements shown that the most
sensitive
bromide.
silver
Eder
of
have
form of emulsion
contains particles of from "003 to '004 of a milli-
meter for
If the
diameter.
in
ripening
continued
is
too long a period the particles
go on
still
growing, but chemical action at length begins to take place.
be heated
In
for too
bromide
silver
if
long a time with the gelatine
becomes reduced and gives
it
solution,
other- words,
rise
to
products which are directly acted upon by the
and
developer reason
why
bromide
in
thus is
it
the
produce
necessary to
first
place
aggregation as to insure of ripeness with the
Not only increase
but
the
changes
in
is
the
the
in
the
precipitate
the
such a
state
maximum
the
minimum amount
of
growth
the optical
bromide
the is
degree
by an
particles,
associated
properties
of
of heating.
ripening accompanied
size
molecular
in
This
is
fog.
with
which enable
CONDITIONS OF SENSITIVENESS.
125
the operator to ascertain whether the emulsion
first
bromide
precipitated
reflected
yellowish white
and reddish by transmitted
light
this
the
particles
layer of
and
is
the insensitive, unripened
is
grow the
the emulsion
violet
light
in
red
richer
by a blue
other
words, the larger particles absorb more of red rays and allow
more of the blue and
rays to pass through. is
When
ripe the
grey or greyish violet by transmitted
the silver bromide appears greenish light.
This
haloid,
and
is is
the
most
sensitive
the condition
by
;
As
in
In
rays.
by
light
condition.
transmitted
becomes
and poorer
The
of sensitiveness.
of the proper degree
is
the
violet
emulsion light,
and
reflected
form of the
sought
in
the pre-
paration of the emulsion.
The changes undergone by are, as
acter in
I
the silver bromide
have already stated, of a physical char-
and are not accompanied by any change
chemical composition.
solved
out of
a
If the gelatine
ripened emulsion
the
is
dis-
residual
bromide has the normal composition corresponding to
the
formula AgBr.
Moreover, the emulsion,
THE CHEMISTRY OF PHOTOGRAPHY.
126
if
well
prepared, unless
developer
not
is
acted
previously
upon
It
is
most
light,
attained.
is
evident that the bromide in the
therefore
emulsion
sensitive
to
exposed
even when the extreme of sensitiveness
the
by
not
is
same chemical condition
as
it
is
the
in
present after
photo-
But we know that over ripening
decomposition.
causes a decomposition of the bromide and enables it
to
be acted upon directly by the developer
without previous
in
exposure
longed heating of the
other words pro-
silver haloid in the
presence
of gelatine produces a similar effect to a short
exposure to
light.
In an
we have overstepped
over-ripened emulsion
the boundary of
physical
change and have entered the region of chemical change.
This molecular transformation
silver salt
of
the
from a small-particled, insensitive state
to a larger-particled, sensitive condition, thus in-
troduces a
new
factor
photo-instability of a
into
the question of the
chemical compound.
The
physical state of aggregation must be taken into consideration
as
well
as
those
conditions which have been
other
shown
to
chemical
have
a
MOLECULAR AGGREGATION OF HALOIDS.
127
determining influence upon the 'sensitiveness
of
photo-decomposable compounds.
The
fact that the chloride
and bromide of
silver
are capable of existing in different molecular states
has long been known, detailed accounts of the modifications
various
Stas
in
having been
This
1874.
published by
eminent investigator even
observed that by the prolonged boiling of silver
bromide with water, the
salt
acquired an increased
sensitiveness analogous to that
With
the process of ripening.
in
in
growth during will
size
of
be necessary, and
some
respect to the
bromide
the silver
this last process
which takes place
particles
further explanation
this is the
most favourable
opportunity for considering the subject. Silver
bromide
is
practically insoluble in water,
bromide
and
gelatine in hot, aqueous solution enables a
per-
but
the
presence
of
potassium
ceptible quantity of the silver salt to be dissolved up.
Let
me
illustrate this
periment shown lecture.
If
bromide and
we
in
an
take
gelatine
by
reversing an ex-
earlier part of the present
a in
solution
of potassium
water and add
silver
128
THE CHEMISTRY OF PHOTOGRAPHY.
nitrate
solution,
we must put
produce a precipitate when gelatine
latter to
when the same amount of
present than
sium bromide
is
words
other
soluble
of
excess
in
especially in the
of
bromide
silver
potassium
potas-
gelatine is
[E].
perceptibly
and
bromide
Now
presence of gelatine.
the emulsion undergoing ripening
is
same quantity
dissolved in the
of water without the addition In
more of the
in
we have
in
a hot
bromide
solution of gelatine containing potassium
the conditions most favourable for dissolving up
some of the
silver
There are reasons
bromide.
believing that the growth of the particles this
solvent action
of the
and which continually deposits the bromide
of
silver
this
it
is
There gelatine
is
yet
is
to be ripened
another
bromide,
salt
on
latter.
indispensable that an
potassium bromide should be present emulsion which
is
the
already present, thus
causing the increase in the size of the this reason
due to
menstruum, which
always saturated with dissolved
particles
is
for
by
For
excess of
in a gelatine
heat.
method of ripening a
emulsion to which
attention
must be
RIPENING B Y AMMONIA. called before It
we can
heat in
as
acquire
ways
its
ammonia
causing the
this
not
now
enter but for which
As
practical treatises.
and
details of
must
I
bromide to
silver
process,
numerous formulae into the
same
acts in the
There are
sensitive condition.
of working
29
leave emulsion photography-
has been found that
way
1
different
there
which
refer
I
can-
to the
you
a point of history
are
should
it
be mentioned that the ammonia process of ripening has been
hoven and by Eder and to manipulation
it
potassium bromide the
emulsion usual silver
by
mixture be
may
way, and haloid
respect
will suffice to state that in the
ammoniacal solution of
ripen
With
Pizzighelli.
preparation of such an emulsion,
of
Van Monck-
developed chiefly by
at first
then
brought
we may add an
silver nitrate to in
a
aqueous gelatine and gentle
partially
the
up
a solution
heat
or
;
ripened in the of
sensitiveness to
the
the desired
the
stage
the addition of ammonia, and continuing the
digestion perature.
for
a
The
short
time
ripening
ammonia has been
at
faculty
a
lower
possessed
successfully applied
in
K
tem-
by cold
THE CHEMISTRY OF PHOTOGRAPHY.
130
emulsifying processes,
such as those of Cowan
and Henderson.
We is
must pause here and ask ourselves why
that
ammonia
acts as a ripening agent.
immediate cause silver all
bromide
who
in
is
it
The
the solubility of
doubtless
ammonia, a property familiar to
are acquainted with the characters of the
silver haloids.
On
tion with water, or heat, the dissolved
ammoniacal
diluting the
on driving bromide
is
off the
solu-
ammonia by
reprecipitated [F].
An
action of this kind no doubt goes on during
the
ammonia
bromide
ripening process, the growth of the
particles
taking
place
by the gradual
deposition of bromide from the solution on to the particles already in suspension, just in
manner
by is
as in the alternative
digestion.
the
same
method of ripening
That the increase of
sensitiveness
due to a physical and not to a chemical change,
may be
proved by arguments similar to those
which have been made use of alternative
process
in dealing
of ripening,
with the
and there
is
no
occasion to repeat them here. I
have dealt at some length with the ripening
CAUSE OF SENSITIVENESS. but
process,
it
131
must not be concluded that the
extreme sensitiveness of a gelatine emulsion
due solely to the molecular
of the silver
state
There are other conditions which have to
haloid.
we can
be taken into consideration before
member
mercy of the preservative
Now
action.
vehicle itself
a
is also
is
in
a
will
re-
a bromine absorbent
sensitizer^
for sensitiz-
emulsion
gelatine
the
the gelatine
and because of the intimate
contact
which
gelatine
and the imbedded
everywhere
the sensitizing action in the
take
washed collodion emulsion we
that in a
are at the
ing
You
of this part of the subject.
leave
is
is
exists
between the
silver haloid
particles,
capable of being exerted
most perfect conceivable manner short of
the vehicle being actually in a state of solution.
Then
again, the perfect
imbedding of the
silver
haloid particles in the gelatine enables us to use
developers of great strength, and thus to
make
the
most out of the impression produced on exposure
;
but this part of the subject will be better understood after
velopment.
we have The
dealt with the theory of de-
co-operation of
all
these condi-
K
2
THE CHEMISTRY OF PHOTOGRAPHY.
132
tions,
both physical and chemical, has resulted
sitiveness,
has in
of
of a mixture which, for sen-
the production
in
towards
hitherto
transcends anything that
light,
been
and has
discovered,
placed
modern photographers a
the hands of
methods which,
for
and
rapidity
series
conveni-
ence of manipulation, must surpass the wildest
hopes
ever
of the
art.
The to
entertained
by the
early
pioneers
practical applications of gelatine emulsions
photographic
purposes
known and need
are
not be dealt
with at
in the present course of lectures.
sensitiveness of such films
well
sufficiently
length
The extreme
enables us to secure
instantaneous impressions of moving objects such as breaking waves, yachts at sea, express trains,
animals in motion or birds
in
flight,
other wonderful effects with which familiarized
of
late
years.
and
all
the
we have been
The problems con-
nected with the locomotion of animals and the flight
of birds have been
recently
considerably
advanced towards solution by the use of cameras with
revolving slides,
capable
of
taking
many
MODERN METHODS.
1
1 pictures in the course of a second of time.
easy manipulation of the emulsion enables
it
33
The to be
spread uniformly over the surface of paper, so that the operator can take into the field a very large
amount of sensitive
surface having but
and occupying but a small space sensitive film as
One
grapher to take no
on one continuous
less
pictures can be developed at
and the
after exposure,
stripped off
photo-
than four dozen negatives
of sensitized paper. 2
roll
in the
of the latest
in this direction enables the
developments
weight
such an area of
would have been impossible
days of glass plate negatives.
image
little
These
any convenient time
film with
and transferred
its
developed
to a thin trans-
parent sheet of gelatine so as to form a light negative which
is
practically
unbreakable, and
from which any number of prints can be obtained the usual way.
in
In
its
application to other branches of science
modern photography has already proved 1
See Nature, February
2
Reference
is
here
the courtesy of the
to be of
16, 1888.
made
to the
Company
Eastman Stripping Film.
By
a demonstration of the process was
given at the termination of the lecture.
134
THE CHEMISTRY OF PHOTOGRAPHY.
the very highest value, and holds out
prospects plies to
the future.
for
emulsion bids
still
greater
This particularly ap-
which science the sensitive
in
astronomy,
1
fair to largely
supersede the older
and more wearisome methods of eye observation. Almost from the dawn of its discovery by Daguerre, attempts were for
graphy
securing
The
bodies.
pictures
collodion
cessfully applied
made
by De
to utilize photo-
of
the
heavenly
wet plate was la
Rue
in
suc-
first
1852 to the
production of lunar photographs, and through the kindness
of Mr. Joseph
Beck
I
am
enabled to
show you on the screen some of Mr. De original pictures.
wards
brought
perfection
and the
in
la
Rue's
Lunar photograph}' was
after-
a
to
is
degree
of
America by Mr. L. M. Rutherfurd
late Dr.
Henry Draper.
of the moon's surface plates
considerable
now being
by
The mapping
the aid of gelatine dry
carried
on at Paris by the
brothers Henry. 1
One
of the latest applications of highly sensitive plates
Professor Oettingen, of Dorpat,
who
is
by
has secured impressions of
the flash produced by the combustion of hydrogen and oxygen in a closed vessel showing the intermittent character of the explosion.
SOLAR PHOTOGRAPHY. With is
culty
photography the
solar
to
respect
one of brightness
135
;
diffi-
to the excessive
owing
brilliancy of the sun, special flashing shutters have
to be
The
employed
sun's disc
in order to avoid over exposure.
is
however capable of being photo-
graphically registered with
all
its
rapidly changing
details of structure with
an exposure according to
M. Janssen, our most
successful
branch, of Ttnnnnr
f
The
a second.
pictures produced at
worker
Meudon by
years.
The camera was
splendid sun
this last observer
have been familiar to astronomers ten
in this
for
first
the last
successfully
applied to the registration of a total solar eclipse
by De has
la
Rue and
since
taken
Secchi in 1860, and no eclipse place
which
in
the
photography has not been called into
Whenever
visible the
sun
is
made
aid
of
requisition.
to give a daily
impression of himself on photographic plates in several
that
observatories
the
both here and abroad, so
appearance and position of the spots
which are so frequently seen automatically recorded.
Astronomer-Royal
I
By
on
his surface are
the courtesy of the
have here for your inspection
THE CHEMISTRY OF PHOTOGRAPHY.
136
some specimens of the Greenwich sun photographs. It
evident that the wet
is
many
presents
work.
collodion for
disadvantages
Among
drawbacks
its
mention the necessity
for coating
process
astronomical
need
I
and
only
sensitizing
each plate immediately before use, and the limited time of exposure admitted by such a moist
film.
this last reason the process is not at all
nebulae,
which require prolonged exposure.
This difficulty
of course overcome
is
of gelatine emulsion plates which can
be exposed sitive
for hours.
By means
by the use if
necessary
of highly sen-
dry plates the stars can now be photo-
graphed of
adapted
photography of faint objects, such as stars
for the
and
For
in
their
myriads
it
is
only a question
mechanical perfection of adjustment
driving rotation,
gear which
compensates
and length of exposure.
and nebulae too
faint
to
in
the
for the earth's
Distant suns
be seen by
human eye
with the best of instruments, and so remote that their light
may
take years to reach the earth, can
be made to record themselves faithfully on that
STELLAR PHO TOGRAPHY. surface which retina
The
has been well
which never
in
followed
in
up
1876,
secured
One
workers, Mr. A. A.
of our most success-
Common, whose
photograph of the great nebula in
1883
is
so
known
well
of
by observers too
countries
all
impressions
The work has been
plates.
numerous to mention. ful
of gelatine emulsion
use
on dry
stellar spectra
as "the
photography was made by Dr.
for astronomical
Huggins, who,
described
37
forgets."
successful
first
1
to
in
magnificent
Orion taken
astronomers, has
been good enough to forward some specimens of his
achievements
for
exhibition.
The
success
which has attended the use of gelatine dry plates resulted
last
year
(1886)
in
the meeting of an
International Congress in Paris at the instigation
of Mr. David
Gill,
Her Majesty's Astronomer
at
the Cape, for the purpose of discussing a scheme for a joint
astro-photographic survey.
the heaven
in
down
to the fourteenth
are to be photographed 1
The
best results obtained
plates in 1864
showed
stars
by the
All the stars
magnitude
l
different nations
by Rutherfurd with wet collodion
down
to the ninth magnitude.
138
THE CHEMISTRY OF PHOTOGRAPHY.
taking part in the work. will
photographs
by
A series of
this
about 10,000
means be secured
in
the course of five years on which will be recorded
some twenty tial
chart
tribute
to
million stars
which, the
material
when completed,
utility
of
for
a celes-
will
be
a
modern photographic
methods such as has never before been paid by one branch of science to another.
APPENDIX TO LECTURE
A
(p.
107).
The
IV.
principle of emulsification can
Two be illustrated by the following experiment are filled about 100 each c.c., up flasks, containing :
to the
same
level,
one with a 6 per cent, solution of
zinc bromide in water,
and the other with collodion
with the same quantity of zinc bromide. more satisfactory to weigh out the materials
salted It is
and make the solutions
in
the lecture room.
A
quantity of silver nitrate equivalent to the whole quantity of zinc bromide in the two flasks is
then dissolved in alcohol with a
little
water,
and
the solution divided into two equal parts, one of which is added to the aqueous zinc bromide solu-
and the other to the salted collodion. The same amount of silver bromide is of course formed in each flask, and on briskly agitating, the bromide formed in the aqueous solution soon becomes granular and settles to the bottom on standing,
tion,
while that formed in the collodion emulsifies.
THE CHEMISTRY OF PHOTOGRAPHY.
HO
B
(p. 117).
The
emulsification of silver bromide
easily shown by the following experiment Soak 20 grams of gelatine in a little water for half an hour and then dissolve completely, by
in gelatine
is
:
the aid of heat, in a larger quantity of water and add 12 grams of potassium bromide to the solution,
which should be made up to 150 ized gelatine solution,
when
c.c.
This brom-
cool has poured into
it
gradually with occasional agitation a solution of
operation
nitrate
silver
grams
15
is
in
150
best conducted in
c.c.
The
water.
a glass flask, the before the lecture.
two solutions being prepared It makes the experiment more instructive flask
is
if
a
prepared with a solution of 12
companion grams of potassium bromide in 150 c.c. water, and a solution of 15 grams silver nitrate in 150 c.c. gradually poured into this with brisk The silver bromide precipitated in the agitation. latter case becomes granular and soon subsides,
water
is
while that
precipitated
in
the gelatine solution
emulsifies.
C the
(p.
1 1
8).
Into two beakers or flasks introduce
same bulk of
(i) distilled water, 'and (2)
per cent, solution of gelatine. the
same quantity of
Add
silver nitrate solution,
very small quantity of this
salt
a 2
to each flask
only a
being necessary
just enough to give a distinct precipitate when potassium bromide is added to the aqueous solution.
APPENDIX. From
burette allow
a
a
141
weak
solution
(exact
strength immaterial) of potassium bromide to run into each flask. It will be found that (i) gives an
immediate
turbidity, while (2) will require
more of the bromide
much
solution before a precipitate
forms.
D in
(p. 1
1
8).
Some
inferior gelatine
is
dissolved
water and a few drops of silver nitrate solution The flask is heated in a water bath till the
added.
This experiment serves
solution begins to darken. to
show the reducing action of the
the silver
E
gelatine
upon
salt.
A
strong solution of potassium bromide (about 20 per cent.) is divided into two equal portions, to one of which is added about one128).
(p.
fourth
its
volume of a
5
per cent,
solution
of
gelatine, and to the other the same quantity of water. The two solutions of course contain the same quantity of potassium bromide per c.c. A
weak
solution of silver nitrate
beaker (from a burette).
is
It will
now
run into each
be found that the
solution containing the gelatine requires a
much
larger quantity of silver nitrate to produce precipitate than the purely aqueous solution.
F
(p.
bromide is
1
30).
a
A clear ammoniacal solution of silver
divided into two portions, one of which boiled and the other diluted with water. In both is
cases the dissolved bromide
is
precipitated.
LECTURE General Notions of Development. Image.
The Action of
V.
The Latent
or Invisible
Sensitizers in Different Processes.
Theory of Developers and Restrainers. Development Acid Development by Ferrous Sulphate.
by Vapours.
Alkaline Development by
Ammonium
Pyrogallate and
by Ferrous Oxalate.
THE
processes which have
may be
regarded as so
film of silver haloid of
now been
many ways more or
considered
of obtaining a
less sensitiveness
on which the picture formed by a lens can be
made
to impress itself in an
exposure for a suitable period. this invisible or latent
know
invisible
form on
In order to
image reveal
itself
make
you
all
that certain substances called "developers"
have to be applied to the
development
must
next
film,
and
engage
this process of
our
attention.
ACTION OF DEVELOPER. now
143
There
is
effects
hardly any phenomenon more striking than
even
in this
age of startling
scientific
the gradual appearance of a picture, with delicate gradations
all
its
of light and shade, on what
was apparently a homogeneous
surface,
on the
application of the developing solution.
In general terms a developing agent
may
be
described as a substance which exerts an action
upon those portions of a photo-sensitive compound which have been exposed to which
it
exerts upon the unexposed portions.
this difference of action
ence
in
light different to that
colour,
is
If
associated with a differ-
while the colour of
the photo-
reduction product does not differ to any striking
extent from that of the unreduced compound,
may have a ment.
strong contrast brought out on develop-
This point
is
ments shown
in
uranic
It will
salt
we
salts.
the
well illustrated first
by the
experi-
lecture with ferric
be remembered that a
becomes reduced to the ferrous
state
and ferric
on ex-
posure, but since the latter does not differ very strikingly in colour from the ferric salt, a ferrous
design on a ferric background
is
hardly perceptible
THE CHEMISTRY OF PHOTOGRAPHY,
144
at
a
The same remark
distance.
design on
uranous
a
uranic
to
applies
On
background.
washing the exposed surfaces with a solution
ferrous design
becomes developed
the
of
corresponding
colour of the design
is
in blue
and
owing to the forma-
the uranous design in brown, tion
of
know what happens.
potassium ferricyanide you
The
a
The
ferricyanides.
in these cases
an accident
contingent upon the fact that ferrous ferricyanide is
blue and the uranous ferricyanide brown.
By we may impart a different The salts of gold and silver
using another developer colour to the design. for
example, are reduced by uranous compounds
but not by uranic compounds, so that
if
we wash
the surface of the exposed uranium print with gold chloride solution, the uranous design only
upon and
is
"
"
developed
in finely divided
is
acted
reduced
gold which produces a picture of a purple colour. Similarly
if
we
uranous design deposition nitrate
by
of
use a solution of silver nitrate the is
developed
metallic
the
in grey,
silver
uranous
owing to the
reduced
compound
from [A].
the
The
chemistry of such processes of development as
POSITIVE these
AND NEGATIVE IMAGES
comparatively simple, and
is
may
145
be repre-
sented by the well-known reduction of gold and silver salts
4
by
ferrous salts
:
+ 6AgN0 3 =2Fe (S0 4)3 +Fe 2(N0 3)6 -h3Ag
There
2
is
2
another point brought out by the ex-
amples chosen to
illustrate the general principle
of photographic development which
tageously be dealt with now.
may
Not only
advanis
the
colour of the developed image dependent on the
nature of the developer, but the production of a positive or negative
is
also in a sense accidental.
Thus supposing a pattern black paper and a
under the
latter,
to be cut out in a sheet of
ferric
coated surface exposed
the ferrous design thus impressed
might be regarded as a negative because
it
appears
lighter than the background of unaltered
compound.
But on washing with ferricyanide the
faint negative
positive,
ferric
image becomes converted into a blue
because
it
happens that the colour given
by the photo-reduction product with the
ferricyan-
THE CHEMISTRY OF PHOTOGRAPHY.
146
ide
is
Now
much more if
intense than the ground colour.
instead of using a ferricyanide
we use
as a
developer some salt which gives a darker colour
with the
than with the ferrous compound,
ferric
such for instance as a ferrocyanide, matters are reversed, positive
From
and we get a negative
on development
instead
of
a
[B].
these preliminary considerations you will
be enabled to gain a general idea of the function of a developer, and at the same time the ground will
have been cleared by the establishment of the
principle that the developed
may
image
be positive
or negative according to the nature of the photo-
reduction product on the one hand and
developer on the other hand.
development
in the abstract,
We
and so
of the
must consider far as
present concerned, the fact of a
we
picture
are at
being
positive or negative in any particular case must be
regarded as accidental to the process with which
we
are dealing.
The next
point that
claims
attention
nature of that invisible image which sensitive film,
and which
is
is
revealed
is
the
formed on the
by the process
THE INVISIBLE IMAGE. of development.
As
147
we had
long as
compounds which underwent a
do with
to
visible
change in
colour under the influence of light, no such mystery as that involved in the formation of an invisible
picture obtruded itself
we were
in the region of
we had only to the
upon our notice
as long as
:
photo-chemistry proper,
due
to regard the change in colour as
production
of
some coloured product of
But as soon as we came to consider
reduction.
the photographic processes
parently
new
presented
itself.
kind
of
'
this
themselves,
ap-
action
photo-chemical
In discussing this subject
it
will
be necessary to limit ourselves to those compounds universally viz.
employed
the silver haloids.
for
photographic purposes,
What
is
the nature of the
image which exists on the surface of a sensitive film after
exposure
any relationship
in the
camera
?
has this image
to the visible product of reduction
resulting from the action of light
upon the
haloids in the presence of sensitizers
In answer to these questions
it is
admitted that the invisible image
silver
?
now is
generally
of the same
chemical composition as the darkened products of
L
2
THE CHEMISTRY OF PHOTOGRAPHY.
148
that
photo-decomposition
it
differs
only in degree and not in kind.
good
from the
There are
latter
many
reasons for this belief, although these
The
necessarily of an indirect kind.
are
difficulties
of
investigating this subject are evidently great,
owing
amount of the
silver
to
extremely minute
the
haloid which undergoes pjioto-decpmposition__on the
a
surface_of
what
in
is
itself
nothing more than
If the investigation of the photo-reduction
film.
products of the silver haloids
exposed
in
large
quantities to the action of light has hitherto baffled
ingenuity,
of
understand that the
readily
demonstration of the composition of the
direct
latent
will
you
image
our
beyond the reach
at present utterly
is
most
refined
chemical
methods.
reasons which have led to the belief that invisible
image
as the darkened
is
built
haloid
The this
up of the same material are
the substances
that
which accelerate or retard the formation of the latter
act
in
a
precisely
similar
respect to the latent picture. silver nitrate which, facilitates the
as
A
we have
manner with substance like
seen, so greatly
decomposition of the haloid acts also
ACTION OF SENSITIZERS.
149
as a sensitizer in all photographic processes
:
sub-
stances like mercuric, stannic or ferric salts, which are
inimical
enormously
the liberation
to
diminish
photographic film
the
free
sensitiveness
halogen, of
of a similar nature
and there
if I
is
much more
only had time to submit
photo-chemistry and photographic chemistry.
We
regard the invisible image as being formed of
an oxyhaloid such a fate
it
enables us to bridge over the gap between
you
may
the
[C].
This kind of evidence
to
of
salt
of
salt
of silver or of a combination of
with unaltered haloid (photosalt).
the
infinitesimal
quantity
of
The
liberated
halogen will depend entirely upon the nature of the sensitizer, but the
maximum that
surface
with the
is,
it is
evident that in order to get
a
photographic
to get an invisible
image formed
sensitiveness
minimum
of exposure,
some halogen absorbent distinctly formulated It will
of
by
we must have
present, a necessity first
Prof.
H. W. Vogel of Berlin.
be instructive to consider the action of the
sensitizer
processes.
in
the
more
important
photographic
THE CHEMISTRY OF PHOTOGRAPHY.
ISO
In the Daguerreotype iodide
and
is
it is
difficult at first sight to
can be.
silver
itself
silver
plays
silver,
imagine what the
generally supposed that
It is
the liberated iodine,
this
and
experiment made known
A
of
a film
on a substratum of
supported
sensitizer
the
plate
by absorbing
part
this
proved by an
is
1866
in
Poitevin.
by
film of collodion containing silver iodide
fectly
free
from
excess of
silver
pressed on to the surface of a
exposed to
light.
The
plate
nitrate,
per-
was
plate
and
thus coated
was
silver
found to be far more sensitive than a glass plate coated with the same collodion, clearly showing
But
that the metallic silver acted as a sensitizer.
the sensitizing action in this case
due on
is
not entirely
to the silver, because a film of pure silver iodide
glass,
prepared by iodizing a silver mirror de-
posited on glass, also gives a latent developable
image on exposure.
The
action
feeble under these conditions, in strong light
but the result silver
is is
is
certainly very
and a long exposure
required to produce
important because
iodide can act to
it
some extent
much
effect,
shows that as
its
own
A CTJON OF SENSITIZERS. This property of
sensitizer.
silver
1
known
to exist between silver
of the alkalies. tri-iodide
Potassium
KI 3 and ,
for
1
iodide might
have been anticipated from the analogy which well
5
is
and the metals
example forms the
the existence of this
compound
prepares us for the belief that silver iodide
may
be capable of combining with a further quantity of iodine.
In a former lecture
I
stated that the Daguerreo-
and we can now
type plate had
much
extract a
further information from the facts
which
little
to teach us,
have just been considered.
emphasize very clearly the laid is
down
These
previously
principle
that the sensitiveness of
facts
any system
a function both of the photo-instability of the
compound and of
the affinity of the sensitizer for
one of the constituents of the compound.
Consider
the sensitiveness of
plate
a
Daguerreotype
compared with that of a on
In the
glass.
first
film of pure silver iodide
case
we have
Agl-f-Ag, and
in
Agl + AgI,
the relatively strong
metallic
i.e.
silver
for
the
as
second case
the system the system affinity
the liberated iodine as
of
com-
THE CHEMISTRY OF PHOTOGRAPHY.
152
pared with
the
for iodine, this
feeble
of silver
affinity
iodide
difference in sensitizing efficiency
determining the superior sensitiveness of the
first
system. In the Talbotype process the sensitizer
know,
and
silver nitrate in
alone.
The
sensitizing action of this last salt
In
halogen.
instance, the reaction
following equation
61
you
process silver nitrate
due to the readiness with which liberated
as
conjunction with gallic acid,
the wet collodion
in
is,
is
the
case
it
is
absorbs the
of iodine,
usually represented
for
by the
:-
+ 6AgNO + sH O = 5 Agl + AgIO + 6HNO 3
3
2
The products according silver iodide
to this
and iodate and
3
.
scheme would be
nitric acid, the free
iodine of course resulting from the photo-decom1 position of silver iodide.
In the dry plate and emulsion processes either 1
This requires corroboration.
when exposed
to
light
in the
strongly acid solution, but the
has not yet been determined.
It is
known
that silver chloride
presence of silver nitrate gives a
amount of
free nitric acid
formed
ORGANIC SENSITIZERS.
153
the preservative, as in the case of tannin, or the vehicle
The
sensitizer.
case of gelatine,
in the
as
itself,
nature of
precise
formed when these organic
upon by the
a practical detail
will
is
products are acted
sensitizers
liberated halogens
the
unknown, but
immaterial from our present point of view.
this is
As
the
is
I
may mention
absorb over 20 per cent of
bromine
bromine
from
ordinary
atmospheric
water
in
that gelatine
weight of
its
four days at
temperatures, the product
consisting of brominated
compounds of unknown
constitution.
So much
now
let
invisible
us
for the
chemical action of sensitizers
return
to
the consideration
image armed with
conditions
essential
to
its
this
of the
knowledge of the
That the
formation.
image formed by the short exposure of a sensitive film of silver haloid should
be invisible
appear surprising, but the wonder just call to
the
mind how
reduction
product
purely superficial haloid
will
may
at first
vanish
if
we
infinitesimal in quantity
formed.
The
the surface layer of
action
is is
reduced
must be of such extreme thinness as
to
154
THE CHEMISTRY OF PHOTOGRAPHY.
parable with the actual
Nor must
themselves.
reduction chloride,
product, is
a diameter com-
section
transverse
present in
of
size it
molecules
the
be forgotten that the
except
the
in
by no means highly
of the
case
For
coloured.
can hardly be expected that the
these reasons
it
undeveloped
picture
should
be
anything
but
invisible.
We
must therefore regard the image formed
by the camera
lens as being painted in reduction
product on the surface of the sensitive
film,
the
varying intensity of action corresponding to the lights
and shades being represented by varying
amount of reduction lights
we have
position
the
the
number of
decomposed,
feebler lights fewer molecules are in
the deep shadows there
at
all.
The
the strongest
maximum amount
greatest
molecules are there
In
product.
is
of decom-
silver
while
haloid in
the
decomposed, and
no decomposition
actual state of affairs can be repre-
sented diagrammatically by taking a simple case.
Imagine three squares of paper on an orange, "non-actinic wall," one square
(A)
being black,
REDUCTION PRODUCT IN FILM. other
the
and the
white,
(c)
intermediate shade
film
;
s,
substratum.
A, B, and
If these squares
(B)
of an
:
FIG.
/
third
155
C
3.
are seen in elevation
;
/"and s
in section.
were photographed the black
would produce the smallest amount
-of
decom-
position, the white the largest amount of decomposition,
and
the intermediate
shade an
mediate amount of decomposition. of reduction product formed
shown
in
1
The amount
scale.
The quantity
by each square
the section of the film,
an exaggerated
relative
of silver haloid decomposed
amount
is
of course on
1
is strictly
not directly proportional to the intensity of the light in
The
inter-
speaking all cases.
varies in different films, but this consideration
THE CHEMISTRY OF PHOTOGRAPHY.
156
Such being the of the film
to
state of affairs
on the surface
which the developer
we may now proceed
to
is
consider the
applied,
methods
of development, selecting for this purpose types of developers which have been or are in actual use
by photographers.
Commencing with
Daguerreotype the latent picture aware, developed in this process
mercury
vapour.
This
mode
as
is,
the
you are
by exposure of
to
development
stands alone as a type of the action of vapours
upon the
invisible
image.
It
is
stated that the
process was discovered accidentally
who put one visible
on
it
by Daguerre,
of his exposed plates with nothing
away
in
a cupboard, and the next
morning found a picture developed,
this
result
being ultimately traced to a vessel of mercury
on one of the shelves. In a case of this kind development
due to can
the
circumstance
that
is
evidently
mercury vapour
form a compound with the product of
duction and not with the unaltered haloid. may be above.
neglected in a coarse illustration such as that
made
re-
The use of
DEVELOPMENT BY VAPOUR. amount of
mercury
is
deposited
157
proportional
amount of reduction product formed on
to the
different is
picture
parts of the plate, built up.
and
in this
way
the
sometimes asserted that
It is
the reduction product attracts the mercury vapour,
but this hardly expresses the facts of the case.
We
must consider the plate over a
warm
vessel of
mercury as being subjected to a constant bom-
bardment of mercury molecules over the whole
Where
surface.
the
molecules
meet
where they
product there they remain attached
meet unaltered haloid they the
reduction
product
reduction
fly off again,
alone
so that retains
ultimately
The
a layer of molecules of varying thickness. action
might be roughly represented by taking
a sheet of glass on which a design had been painted in gum, and blowing sand on to the surface. off,
Where
where
it
the sand
met gum
met it
glass
would be
it
would
retained,
the design would be thus " developed particles
[D].
As
far
as
"
in
fall
and sand
the physical action
concerned this explanation must at present
is
suffice,
but the chemical nature of the compound formed
THE CHEMISTRY OF PHOTOGRAPHY.
158
by mercury with
the
reduction
present unknown.
It is
not even
definite
any
compound
possible that the action
is
at
known whether
formed at
is
is
product
all
it
;
is
purely physical, the re-
" duction product being capable of being wetted,"
so
to
by the condensed mercury, while
speak,
the unaltered haloid it
be
may
In this connection
not.
mentioned that
the
Daguerreotype
capable of being developed by water
is
picture
is
vapour, although of course only in a transitory
be excused
may
I
way.
for
sizing
how much we have
oldest
known photographic
both to
The
its
once again empha-
yet to learn from this process with respect
physical and chemical principles.
iron developer
the wet collodion
so generally
process will
employed
serve
of the next class of developers.
in
a type
as
The
solution
contains as essentials ferrous sulphate and acetic acid,
some alcohol being added
to
insure
the
uniform flow of the solution over the surface of the plate. this
Let us
first
consider the action
developer from a chemical
Ferrous
salts
which were
first
point
used
of
of view. in
photo-
IRON A CID DE VELOPER. graphy by Robert Hunt agents
in
1844
which readily reduce
silver
1
are
reducing
nitrate,
have practically no reducing action on the haloids
under ordinary conditions.
59
but
silver
we add
If
ferrous sulphate to a solution of silver nitrate
we
get a precipitate of metallic silver [E], formed in
accordance with the reaction referred to a short
time ago
:
6FeS0 4 + 6AgN0 3 = 2Fe2(SO4)3 + Fe2(NO3)6 + 3 Ag2
Now image
the is
collodion
covered with the
film
and
of reduced
over the plate. disaster
with
invisible
its
sensitizing
film
of
we poured on to this a solution sulphate, we should of course have a
silver nitrate,
of ferrous
plate
if
silver
The
immediately deposited acetic
acid
by checking the reduction
nitrate, so that the free silver is
prevents of.
all
this
the silver
gradually deposited
on the reduction product, the amount of deposit being,
broadly
amount of is
built
up
speaking,
this product. in
proportional In this
metallic silver.
way
to
the
the picture
THE CHEMISTRY OF PHOTOGRAPHY.
160
This
developer
of
is
some of the
a
course
details
the
iron
mere outline sketch,
of which
Let us
deavour to supply.
of
action
explanation of the
must now en-
I
first
consider what
can be learnt from the use of acetic acid, which retards the precipitation of silver from the solutions of
its salts
the
although acid.
metal
action of reducing agents,
itself
is
insoluble
in
the
Substances which exert this retarding action
are called
or less
of the
by the
restrainers^
and these act with more
completeness according
to
the
stability
compound which they form with
If the restrainer
silver.
forms a very stable silver com-
pound we may have any degree of retardation
up to the silver.
total prevention of the precipitation of
The
organic salts of silver are less stable
than the inorganic
salts,
and the organic acids are
accordingly milder restrainers than acids.
Even
the
mineral
indifferent organic substances, such
as sugar, glycerol, or gelatine, act as restrainers virtue
by
of the viscosity which they confer upon
the developing solution, or because of a tendency to
form
feeble
compounds with the
"
nascent
"
GROWTH OF SILVER silver.
of as
"
DEPOSIT.
161
Such substances are sometimes
spoken
physical restrainers
them from
acids or
"
order to distinguish
in
compounds which are capable
of combining chemically with the
may
silver,
and which
therefore be regarded as chemical restrainers
[F].
The next siderable
point to be considered
one of con-
at the root of the
lies
it
importance
is
explanation of the development of the invisible
image
in silver.
attaches
itself
Important as
is
Why
in the
that the nascent silver
only to the
reduction
product
cannot be satisfactorily
it
present state of knowledge.
generally stated that the reduced haloid, invisible image, attracts the nascent silver
developing solution.
?
of pho-
this question to the theory
tographic development,
answered
is it
But
this
It is z>.,
the
from the
statement must be
carried further before the theory of the developer
can be considered in any
way
complete.
It is
ob-
vious that the reduction product attracts the silver,
otherwise the picture would not be developed at
To
say therefore that the silver
carry the explanation
very
is
far
all
attracted does not it
amounts
M
in
THE CHEMISTRY OF PHOTOGRAPHY.
162
reality to little
All
more than a restatement of the
who have used
;
know
that
cumulative in
its
the picture gradually gains in intensity
by
other developers
like all
action
the iron developer
fact.
is
it
the accumulation of fresh silver on the deposit
formed.
Now
reduced
silver
the question
is,
first
does the deposit of
begin to form at once upon the
reduction product, or
the latter in the
is
first
place
superficially reduced to the metallic state by the
developer
?
In other words,
can the reduction
product be reduced further by ferrous sulphate
These are the questions which difficult to
answer, and
I
am
it
is
?
now very
glad of the present
opportunity of pointing out a line of investigation
which might easily be taken up by any one of you
who
has the requisite chemical knowledge.
It
is
generally believed that no direct reduction of the invisible in this
image by the ferrous sulphate takes place
kind of development, 1 but that the nascent
silver is
from the very beginning of the process
deposited on the reduction product only. 1
Some experiments made
for
me by
What-
Mr. T. H. Norris in the
laboratory of the Finsbury Technical College confirm this belief.
DEVELOPMENT B Y ACCRETION. ever
may
be the truth with respect to the
action, there
is
no doubt that the
when once formed continues
to
feed
it.
there
any
is
163
to
silver
initial
silver deposit
grow as long as
mode
This
of
deposition will remind you of electrolytic action or
Evidence
of crystalline growth.
not wanting
is
that the growth of the silver deposit
may
of electro-deposition, the film of silver
be a case
formed
first
constituting one element of a micro-galvanic couple
by the developing
excited
solution.
shown by LermontofT that with nitrate
solutions of silver
and ferrous sulphate and a
silver a galvanic circuit
growth of metallic
can be formed, the nitrate
silver
The development means of the
strip of metallic
and depositing a
becoming reduced
has been
It
on the
crystalline
silver strip [G].
of the photographic image
ferrous
sulphate
developer
by
thus
resolves itself ultimately into a process of accretion.
Given a
faint silver picture to start with,
and the
metallic deposit will go on gaining in thickness as
long as there
is
nascent silver to feed
We
it.
can
imitate these conditions artificially without calling in the aid
of light at
all.
Here
for instance is
M
2
a
THE CHEMISTRY OF PHOTOGRAPHY.
i64
sheet of paper coated with silver chloride on which stripes of metallic silver
The
reduction.
have been produced by
stripes are at present faint, but
them over with a
on
solution
of ferrous
sulphate containing acetic acid and a
little silver
brushing
nitrate,
they become almost black, owing to the
further deposition of silver
upon them [H].
conditions in this experiment are
same
The
much about
the
as in an ordinary photographic plate under-
We have
going development.
a surface composed
partly of unaltered haloid and partly of metallic silver,
the nascent silver from the developer being
deposited on the metallic stripes only and none on the unreduced haloid. It will
tions
be readily gathered from these explana-
that
the
developers
typified
by the
iron
developer build up a visible picture by depositing
reduced reduced the
silver
on the
invisible image.
silver is supplied
haloid
is
collodion plate
easily
by
That the
the nitrate and not
shown by exposing a
by
\vet
and then washing out the excess of
silver nitrate before
applying the developer.
these circumstances no picture
is
Under
developed at
all,
DE VELOPMENT B Y MERCUR V.
165
or at most only a very faint one, probably the result
of the retained trace of silver nitrate which difficult to
On
remove by washing.
so
is
adding a few
drops of silver nitrate to the developer such a
washed plate can be developed as usual
mixture of substances containing what a
called
developer
when the
requisite conditions, electro-
All that
chemical or otherwise, are set up. necessary
is
and not the unaltered
capable of having requisite
is
a reducing agent capable of reducing
nitrate
silver
may be
deposit will act as a
silver
potential
Any
[I].
by a
its
haloid,
and
reducing power modified
restrainer.
It is
if
quite unnecessary
here in dealing only with general principles to the different kinds of developers which
specify
all
act
the
in
way
indicated.
As
illustrating
the
general theory an
experiment of Carey Lea's
highly instructive.
An
after
and
exposure is
nitrate is
is
is
iodized collodion wet plate
washed
free
from
silver nitrate,
then treated with a solution of mercurous
and pyrogallol when the
developed
in
mercury.
invisible
The analogy
developer with the iron developer
is
image
of
this
sufficiently
1
THE CHEMISTRY OF PHOTOGRAPHY.
66
the solution contains a potential deposit
obvious
of mercury, and the image
is
accordingly developed
in this metal instead of in silver.
Another important group of developers may be typified
by the
alkaline developer so familiar to
who have worked with word or two development which was
was used
as
may
first
to
A
gelatine emulsion plates.
the history of this kind of
not be out of place.
Gallic acid,
obtained pure by Scheele
in
1786,
as a developer in the early days of the
Talbotype
process.
The
sublimate
crystalline
obtained by heating gallic acid was
first
as a distinct substance (pyrogallic acid)
connot
all
in
1831,
and
its
identified
by Bra-
use as a photographic
developer was suggested in 1851 by Liebig and Regnault. as
I
It
was the
late
Colonel Russell
stated in a former lecture,
first
who
made known
in
1862 the advantages of an ammoniacal solution of pyrogallol for the development of dry tannin plates,
so that
when
gelatine emulsion plates
use there was a developer for them
came
into
already to
hand. In considering the principles of alkaline develop-
ALKALINE DEVELOPMENT. thing to be borne in mind
ment the
first
have no
free silver nitrate
collodion
167
process.
That
on the plate as
is
one reason
we
that
is
in the
the
why
ordinary iron developer cannot be used with dry Pyrogallol
plates.
is,
most of you know, a
as
hydroxybenzene derived from tive distillation,
gallic acid
tri-
by destruc-
carbon dioxide being given off as
one of the products of decomposition
:
C 6 H 2(HO)3 .COOH = C 6 H 3 (HO) 3 Gallic acid.
An
alkaline
Pyrogallol.
of pyrogallol
solution
is
a most
powerful reducing agent, greedily absorbing oxygen
from the
air,
Not only
is
and rapidly reducing the
silver nitrate
salts
of
silver.
reduced by such a solution,
but even the silver haloids are reduced, so that
we
have to deal with a substance of which the reducing
power transcends that of
ferrous sulphate
this reason the alkaline pyrogallate
alone
*t requires restraining, or
reduction over the whole plate fog.
It
;
[J].
For
cannot be used
we should have in
other words, a
has been found that a soluble bromide, such
as that of potassium, exerts the necessary restrain-
THE CHEMIS TR Y OF PHO TO GRAPH V.
1 68
that the developer actually used
ling influence, so
consists of an -ammoniacal solution of pyrogallol
mixed with potassium bromide. restrainer can
Here
and
action of the
be illustrated by an experiment.
a sheet of paper coated with silver bromide,
is
if
The
we
paint on
its
a stripe of
surface
am-
moniacal pyrogallol we get a dark stripe of reduced silver.
Now
on adding some potassium bromide to
the developer and again painting a stripe you see
we
get a
much
fainter impression
action of the bromide has been
the reducing
weakened by the
restrainer [K].
So much
Interpretation. is
now
for the facts
The
let
us consider their
point that chiefly concerns us
the retarding action of the potassium bromide.
It is
generally believed that the restraining power
of this substance
double
salt
is
bromide
i.e.
tendency to form a
itself.
less easily reducible
the well-known
fact
is
salt
than the
That such a doubk
potassium bromide exists
bromide
its
with silver bromide, this double
being more stable, silver
due to
silver
rendered probable by
of the solubility of silver
in a solution of
potassium bromide
[L].
COURSE OF THE PROCESS. The
restrainer
169
the alkaline developer acts
in
therefore in a different
way
to the acetic acid of
the iron developer, although the final result
The potassium bromide mixed with
same. alkaline
of
deposition
over the
all
on the
haloid
silver
prevents the
on
the
pyrogallate checks the reduction of the
unaltered
silver
the
is
a
of
film
The
latter.
and thus
plate,
iron
reduced
developer,
no tendency to reduce
the other hand, has
the unaltered haloid, but only the small quantity
of silver nitrate which
and
too
the
checked vents
rapid
by the
the
of
the
ciently clear
of
acetic
haloid.
alkaline to
the process
present on the plate,
reduction
deposition
the unaltered
is
of this
which
acid,
of
a
The
developer
of
film
principles will
nitrate
thus
is
pre-
silver
on
of action
now be
suffi-
enable us to follow the course of development
somewhat more
deeply.
Supposing we begin with an exposed gelatinebromide plate
;
a product which
unchanged
the invisible is
more
image
is
formed of
easily reducible than the
haloid, so that the first action of the
1
70
THE CHEMJS TR Y OF PHO TOGRAPHY.
developer
to reduce the reduction product,
is
Now
the invisible picture, to the metallic state. the alkaline developer differs from
the
i.e.
iron
de-
veloper in having no potential deposit of silver dissolved in it
it.
I
say no potential deposit, but
would be more correct
only a trace of dissolved
to say that silver,
it
contains
because the am-
moniacal pyrogallate does dissolve a trace of
silver
haloid out of the film, and this becomes reduced
and adds to the density of the image. appear therefore at
first
sight
It
might
that the alkaline
developer simply acts by reducing the invisible
image to the metallic picture being increased
state, the intensity
by the minute amount of
resulting from the
silver
of the
reduction
of the silver
bromide dissolved by the ammoniacal developing solution.
may
This explanation however, simple as
it
appear, will be found inadequate on further
examination.
In the
first
place,
it is
evident that the
amount of reduction product which forms the visible
image
metallic pictures.
silver
is
so small that
would
equivalent in
but the
give
In the next place,
its
it
in-
faintest
of
can easily be shown
DENSITY OF SILVER DEPOSIT. that the
the film
amount of
silver
bromide dissolved out of
by the ammoniacal
more than a
and
trace,
is
solution
picture.
same strength
as
is
nothing
fully-developed
ammonia of about
of
to
insufficient
quite
account for the density of the If a solution
171
the
in the alkaline de-
that used
veloper be poured repeatedly over the surface of
an unexposed gelatino-bromide found that the merest trace of
The
present in the solution.
plate, silver
it
be
will
bromide
is
density of the de-
posit in the completely developed picture clearly
shows therefore that the metallic image from
some other
The answer
Whence comes
source.
additional supply of silver
is
fed this
?
to this last question
must now be
dealt with before the theory of alkaline develop-
ment can be considered metallic
in
any way complete.
image produced by the
developer, which image silver of the reduction
is
first
The
action of the
in fact the equivalent in
product formed by the action
of light, comes into existence in the presence of the
unaltered bromide in which
have therefore what
may
it
is
imbedded.
We
be regarded as nascent
THE CHEMISTRY OF PHOTOGRAPHY.
172
silver in contact
of
silver
where is
wetted
being
particles
solution.
with silver bromide, the two kinds
Under
by the developing
these circumstances the unaltered
bromide becomes reduced it is
in contact
by this means
in
those places
with the nascent
that the additional silver
which reinforces the
It
silver. is
film first produced,
supplied
and gives
density to the image.
In the case of alkaline de-
velopment the picture
is
plied chiefly from the
unchanged
built
up from
silver sup-
silver haloid
not from the bromide generally,
the emulsion itself
but only from those portions which are
mediate contact with the the
first
in
acid
In
raised in relief
im-
image resulting from
is
Thus the image,
supplied by growth
one case the
silver picture
is
upon the surface of the collodion
in the other case the
The
in
up by accretion from above
development,
from below.
film.
silver
action of the developer.
instead of being built as
in
image
black, white,
is
;
sunk into the gelatine
and intermediate squares
of paper used to illustrate the formation of the latent
image
graphed
and
(see p. 155)
developed
would
give,
when photo-
by the two
methods,
COMPARISON OF METHODS. results
173
which might be thus represented diagram -
matically
:
E
A
P
Acid development.
Alkaline development. FIG.
In proof of this
ment the
silver
it is
image
4-
found that
is
condition.
On
after develop-
dissolved off the plate
nitric acid, the surface of
ferrous sulphate
if
the film developed
simply restored to
is
the
its
by
by
original
other hand, the picture de-
veloped by alkaline development, being imbedded in the film instead
leaves
its
after the
of being raised upon
its
surface,
negative impression sunk into the emulsion
removal of the
this beautiful
silver
by the
acid.
For
demonstration we are indebted to the
late Colonel Russell (1865).
174
THE CHEMISTRY OF PHOTOGRAPHY.
Although the foregoing explanation of the process of alkaline
and
is
development
probably in the main correct, there
point which
is
now
under notice
I
generally received
is
bring
it
made
not quite clearly for the
out,
is
one
and
I
same reason that
have dwelt upon other obscure points
in the course
of these lectures, viz. in order to incite investigation.
The
part of the process to which
ducing action of the nascent
I
refer
silver
is
the re-
representing
the invisible image upon the silver bromide with
which
it
is
In
in contact.
ducing action
is
decomposition.
the
all
probability this re-
result of micro-electrolytic
All the conditions can in fact be
reproduced by pressing particles of
silver into a film
of gelatino-bromide emulsion and developing with
an appropriate developer without any exposure to light
at
all.
Each
metallic
particle acts in this
case as one element of a galvanic couple, and re-
duces the bromide with which result
it is
in contact,
the
being a corresponding number of dark spots
dotted over the plate, which appear distinctly on
brushing off the silver particles and fixing with thiosulphate in the usual
way
[M].
BUILDING UP OF SILVER IMAGE.
175
There are one or two other proofs that building up of the
velopment been
which
described,
first
place
experiment by in
it
exposed
few minutes I
our
in
concluding.
In
Abney, who took a dry the
and
camera,
plate,
before
then,
one half of the
collodio-bromide emulsion
oped as
occupy
remind you of a striking
will
coated
developing;
such as have
well
may
de-
alkaline
in
image
the result of actions
is
attention for a
the
silver
the
with
plate
and afterwards devel-
The image on
coated
half
was much denser than that on the uncoated
half,
usual.
clearly indicating that
from
the
film
of
silver
the
had been supplied emulsion
collodion
as from the bromide in the film plate.
The developing
well
as
of the
original
solution in this case soaks
through the film of collodion emulsion before
The
can reach the invisible image.
undergoes
image
is
the
feed
reduction.
between it
On
with
and
reduction
the
two
silver
separating
the
latter
then
the
silver
and below, being
fed both from above
sandwiched
which
usual
it
films,
by
both
of
micro-galvanic
films
an
image
THE CHEMISTRY OF PHOTOGRAPHY.
176
is
found
on
collodio-bromide
the
was not exposed,
Then
plate [N].
well
as
there
is
which
film,
as
on the
original
an
equally
striking
experiment due to Dr. Eder, who coated a plate with a great thickness of gelatino-bromide emulsion and,
that
taken
the
after
exposing and developing,
reduction
of the
place under the
found
bromide had
silver
illuminated
portions
of
the film throughout the whole thickness of the In this case the
emulsion.
course fed entirely
bromide beneath
silver
is
of
the reduction of the silver
by
and as the
it,
picture
light
could not
have exerted any influence on the lower portion of a layer of emulsion
made
so thick as to
which was
be
opaque,
intentionally
the
reduction
which commenced at the surface must have extended downwards by the same process as that
by which
it
spreads both upwards and
downwards
in the
experiment of Abney's previously described.
Such
results as these are strongly suggestive, if not
actually demonstrative of electrolytic action.
APPENDIX TO LECTURE
A Exp.
An
144).
(p.
Lecture
I,
I,
V.
ordinary uranium 33) after
p.
one of which
print
exposure
is
(see
cut
developed with potassium ferricyanide, the other with silver nitrate, and the third with gold chloride solution. After into three strips,
strips are pieced together so that
development the the design
is
appears tricoloured, brown, grey and
purple.
B
146). " Pizzighelli's
follows
1.
Paper (well sized)
(p.
"
solution
Cyanotype
coated with
is
prepared
:
20 grams
gum
arabic in 100
c.c.
water.
2.
50
ammonio-ferric citrate in 100
3-
5
ferric
c.c.
No.
i
.
.
No. 2
No.
3
.
.-
.
water.
chloride in 100 .
.
.
c.c.
.20
c.c.
8
c.c.
water.
5 c.c.
N
as
THE CHEMISTRY OF PHOTOGRAPHY.
178
The mixed
solutions
if
too thick can be cleared
with a
A
little dilute hydrochloric acid. sheet of paper thus prepared and allowed to
exposed under a design cut out in black paper to the electric light for about 10 minutes, and then cut into two strips, one of which is developed is
dry
by being brushed over with a solution of potassium ferrocyanide and the other with a solution of the ferricyanide (about
15
per cent, solutions).
two
The show
strips are then pieced together so as to the developed pattern half positive and half negative.
may
The
developed with ferrocyanide require clearing by immersion in dilute hydroportion
chloric acid.
C
(p.
painted on chloride, electric
it
and
A
has a design with a solution of ferric or mercuric
149).
is
light.
gelatine
plate
then given a brief exposure to the The plate is washed and then
developed with ferrous oxalate developer, when the design comes out on a dark background, showing the retarding action of the ferric or mercuric salt.
D
(p.
scribed
157). in
The experiment
the text,
stripes
is
shown
ported vertically while a sand blast its
E
de-
being painted with
thick gum-water on a sheet of glass which
to
as
is
is
sup-
directed on
surface. (p.
159).
The
experiment
is
shown
as
APPENDIX TO LECTURE
V.
179
described in the text, a solution of ferrous sulphate being added first to a solution of silver nitrate to
show the formation of a precipitate, and then a stripe of the same solution painted on a sheet of paper moistened with silver nitrate, when a dark patch at once appears. For comparison a stripe of the solution is also painted on a sheet of paper coated with a silver haloid and free from excess of silver nitrate.
F
(p.
and
The
161).
physical,
ment
:
action of restrainers, chemical
shown by the following experi-
is
Equal quantities of a dilute solution of, (about one per cent.) are placed in four
silver nitrate
beakers.
To
(i) is
added about one-fourth
its
bulk
of a five per cent, solution of gelatine to (2) is added the same quantity of glacial acetic acid to ;
;
added the same quantity of dilute sulphuric (3) acid and to (4) is added the same quantity of is
;
distilled water.
The
four beakers thus contain the
same bulk of a solution of silver nitrate and each contains the same quantity of silver. A dilute solution of ferrous sulphate
is
then run into each
beaker from a burette, the same volume of solution being added to each beaker. The precipitation of reduced silver occurs at once in (4), less
rapidly in (i) and
G made
(p.
163).
(2),
and
least rapidly in (3).
Lermontoff's
experiment can
into a lecture demonstration
be
by dividing a
N
2
THE CHEMISTRY OF PHOTOGRAPHY.
180
two partitions by means of a vertical brown paper septum, which must be cemented watertight to each side and to the bottom of the cell. The latter is then filled up in one partition with a two per cent, solution of silver glass cell with parallel sides into
nitrate,
and to the same
level in the other partition
with a cold saturated solution of ferrous sulphate. The two solutions are connected by means of a bent silver wire which dips about half way to the On projecting cell in each partition. an image of the apparatus on to the screen, the
bottom of the
crystalline
growth of
silver is seen
on the end of the
With
wire in the silver nitrate solution.
a horizon-
lantern the arrangement of the cell
tal
must of
course be modified.
H
(p.
The paper
164).
silver chloride in the Usual
striped
with
weak
a
is
coated
first
way
and,
of
solution
when
with dry,
is
ammoniacal
As pyrogallate containing some sodium sulphite. soon as the reduced stripes are distinctly visible the paper
is
the text. in
washed, and then developed as described in The whole experiment can be performed
a few minutes
if
the chloride-coated paper is It is better to moisten the
previously prepared. surface of the paper with silver nitrate after
solution
washing and before development, instead of
putting silver nitrate into the developer. I
(p.
165).
A
glass
plate
is
ruled
with
a
APPENDIX TO LECTURE
181
V.
diamond down its centre and then coated with collodion and sensitized in the silver bath in the usual red light.
in
way
When
sensitized the plate
is
given a brief exposure to the electric light and then broken in half. One half is washed thoroughly in
water and then both this and the unwashed half are simultaneously developed with the iron developer, the washed portion of the plate after this treatment
being
much
lighter than the other.
The reducing power of ammoniacal was shown by the following experipyrogallol ments J (p. 167).
:
An
ammoniacal solution of silver nitrate was mixed with ammoniacal pyrogallol, an immediate 1.
precipitation of silver taking place. 2.
Sheets of paper coated with chloride, bromide,
and iodide of silver were painted with stripes of the same solution of ammoniacal pyrogallol. A dark stripe of
reduced
silver
most strongly on the
appears in
three cases
all
chloride, least strongly
;
on the
iodide.
This
last
experiment serves well to
illustrate the
relative reducibility of the three haloids.
must be
K
(p.
free 1
from excess of
68).
The papers
silver nitrate.
The experiment
is
performed as
described in the text.
L in
(p.
1
68).
The
potassium bromide
solubility is
easily
of silver bromide
shown by
boiling
THE CHEMISTRY OF PHOTOGRAPHY.
182
some
freshly prepared silver
bromide with a strong
bromide and pouring the a beaker of cold water. clear solution into solution of potassium
M
(p.
A
174).
gelatine dry plate
some
with water and
moistened
is
dust (prepared by
silver
with ferrous sulphate) The metallic particles sprinkled over the surface. are pressed on to the film by passing a glass roller silver
reducing
nitrate
A
over the surface of the plate. solution
oxalate the
(ammonium is
developer)
action
has
strong developing pyrogallate or the ferrous then applied, and when
been allowed to
sufficient
time
particles
brushed
the
plate off,
is
and
go on the
washed, a
fixing
for
a
silver
solution
(thiosulphate) poured over the surface. After being fixed and washed the plate can be put into a lantern
and its image projected on to the screen, when the darkened appearance of the portion which was under the
silver dust is seen to greater
makes the
more
advantage.
a design striking screen and the latter is paper applied to the surface of the plate before the silver dust is sprinkled on the design then appears in the It
is
illustration
if
stencilled out in a
:
last stage as
a dark granulation of the
film.
It
is
perhaps hardly necessary to say that the experiment
must be conducted
in red light
up to the application
of the fixing solution.
N
(p.
176).
Abney's experiment can be shown
APPENDIX TO LECTURE as a lecture demonstration
V.
by exposing a
183
gelatine
dry plate to diffused white light for a few seconds,
and
allowing a streak of a previously prepared coliodio-bromide emulsion to flow over The streak of the surface of the gelatine film.
then
allowed to dry and then the developed in the usual way (by ammoniacal
collodion emulsion plate
is
pyrogallol oxalate).
is
and potassium bromide or by ferrous striped portion of the plate comes
The
out darker than the background.
LECTURE
VI.
Rapidity of Emulsion Plates partly due to Developer
Ferrous
Oxalate Development
chemical
Test
Quantitative Micro-
Development of Chemical Reduction
Product and of Pressure Marks of the Silver Haloids in of the Invisible
Phenomena
Collateral
The Developer a
of Development
Relative Sensitiveness
Different Processes
Relapse
Image due to Reversed Chemical Change
Reversal of the Image or Solarisation The Phenomenon a Recurrent one Theory of the Process and the Function of the Sensitizer.
THE
distinction
between acid and
velopment which was dwelt upon lecture,
two
and the
kinds
of developers,
enable
the
why
reasons
cesses
in
which
was
us to appreciate
our
the
delast
mode^ of action of the
different
plained, will
alkaline
modern
also
more
emulsion
have such an enormous advantage
exfully
proin the
DEVELOPMENT OF GELATINE PLATES.
185
of rapidity over the old wet-plate methods.
way The
sensitiveness of the emulsion
has, as
itself
has already been pointed out, a great deal to do
with this rapidity, but a certain share must also In the wet-plate
be credited to the developer. silver
nitrate
present as a sensitizer.
is
If
we
applied an alkaline developer to such a plate, the free silver nitrate
results of a
for
would be at once reduced with
most disastrous nature to the picture
this reason
alkaline
development cannot be
In a gelatine emulsion plate on the other
used.
hand,, as there
danger of
no
is
fog
free silver nitrate,
from
this
we
being imbedded a
as
reducing
enough metallic
there
is
And
much
not only
use a stronger developer for this reason,
but also because
acts
we run no
and a
source
stronger developer can be used.
can
;
of the in
physical solution
silver
haloid
particles
a substance, gelatine, which restrainer,
which
we can apply a
would
be
strong
to reduce the silver haloid directly to the state
were
it
Thus
not so protected.
a gain at both ends of the process
have a more sensitive film to
start with,
we
and we
i86
THE CHEMISTRY OF PHOTOGRAPHY.
can use a strong developer after exposure. are the reasons
now
These
instantaneous photography
why
is
possible to every amateur.
It is
unnecessary here to specify
all
the different
kinds of developers which have been
or which
act in accordance with the
are in use.
They
principles of
one or the other of the typical kinds
all
Of
of development.
the numerous reducing sub-
stances which have been proposed as substitutes for
ammonium
I
pyrogallate,
need only mention
the pyrogallates of potassium and sodium (with or
without the addition of a sulphite,) hydroquinone (quinol),
and
pyrocatechol, resorcinol, hydroxylamine,
certain
ferrous
organic
are very largely used, a
oxalate
by Carey Lea in mind that it
1877
acts
alkaline
developers
devote a
little
Ferrous insoluble
;
class
developer introduced
and the
to this,
same way
generally,
we may
bearing as the fairly
consideration.
oxalate in
in
latter
good type of the
being the ferrous in
The
salts.
cold
is
a
yellowish
water but
a solution of potassium
readily
oxalate,
salt
almost
soluble
owing
to
in
the
FERROUS OXALATE DEVELOPER.
solid form, has
K
Fe(C 2 O 4 ) 2
2
as
the
2H 2 O
,
preparation tains
double
of a
formation
K
formula
2
Fe(C 2 O 4) 2 ,H 2 O or to
according
active
this
salt
mode
its
mix
obviously to
and potassium oxalate tions, as
of
solutions
potassio-ferrous
ferrous
it
is
sulphate
the necessary propor-
in
pointed out by Eder in 1879
FeSO 4 + 2K 2 C 2 O 4 =
of
solution con-
and the simplest way of preparing
oxalate,
the
in
which,
The developing
[A].
its
oxalate
187
K
2
Fe(C 2 OJ 2
:
-f
In order to restrain the strong reducing power
of the ferrous
salt
to the developer,
its
potassium bromide function being the
the ferrous oxalate developer the
ferrous
stance,
by
oxalate, which
is
is
it
in
action of
simple enough
;
the reducing sub-
becomes oxidized to the
the bromine which
added
same as
The chemical
the alkaline pyrogallate.
is
ferric condition
withdraws from the
re-
duction product, the latter being further reduced to
metallic
silver
while
bromide, except where
it
the is
unaltered
in contact
silver
with the
1
THE CHEMISTRY OF PHOTOGRAPHY,
88
nascent
not attacked owing to the pre-
silver, is
sence of the restrainers
bromide
(potassium
The
the solution and gelatine in the film).
between
the
oxalate and the
ferrous
product thus resolves
bromine upon ferrous oxalate potassium oxalate
3Br 2
2
2
reduction
of
action
the presence of
2
4
=-
3Fe 2 (C 2 O 4) 3
+ 6KBr.
addition of sodium thiosulphate, suggested
by Capt. Abney this developer, salt.
in
action
:
+ 6FeC O 4 + 3K C O
The
the
into
itself
in
in
1880, increases the activity of
probably by reducing the
There has been some discussion as
ferric
to the
chemical action of this accelerator and the equa-
manuals are generally
tions given in the current
erroneous.
The
is
thiosulphate
most probably
oxidized to tetrathionate, as in the equation
Fe 2 (C 2 O 4 ) 3
+ 2Na
Ferric oxalate.
2FeC 2 O 4 Ferrous oxalate.
Sodium
2
S 2O s
=
thiosulphate.
+ Na C O + Na 2
Sodium
2
4
oxalate.
:
2
S 4O6
Sodium
.
tetrathionate.
CHEMICAL RED UCTION PROD UCT. To
the
developers of this
class
ferrous citro-oxalate developer of
1
89
belongs the
Abney which
is
a mixture of potassio-ferrous oxalate and citrate
with excess of potassium
citrate.
Before leaving the theory of the action of photographic developers, there are certain collateral phe-
nomena more
or less connected with this theory
which must next claim our attention. in the first place present the action in
another light
there
is
me
Let
of a developer
nothing like looking
all
round an explanation when we wish to assimilate it
A photographic
thoroughly.
developer
may be
regarded as a microchemical test for the presence of traces of reduced silver haloid too minute to be In the cases which have been
detected by the eye.
considered, the infinitesimal trace of reduction pro-
duct forming the latent image
by the
action of light,
the analogy a
of course produced
and the developer,
little further, is
but also a quantitative
is
test,
to
push
not only a qualitative,
showing the quantity of
reduction product formed on different parts of the
exposed deposited.
film If
by the varying amount of the
reduction
silver
product could be
THE CHEMISTRY OF PHOTOGRAPHY.
190
formed on a surface of
by a
unaltered haloid
purely chemical method without calling in the aid of light at
developer would reveal the
the
all,
presence of this product although nothing might
be visible before
its
application.
Any reducing agent capable of reducing the silver haloids to the metallic state may be supposed to give as a
first
product the same compound as that which
constitutes the invisible image, provided the reducis
ing agent
applied in the presence of an excess
Thus the
of the silver haloid. phites or an
alkaline hypophos-
alkaline solution of certain sugars,
such as glucose or lactose, produce an invisible
image on a surface of is
silver chloride,
capable of development in the ordinary
[B].
Such
illustrations in
support of
invisible
is
similar
image
coloured product formed
upon the will is
way
have been recently adduced
by Carey Lea
it
which image
silver haloid.
in
the view that the
composition to the
by the
action of light
Whether
this
argument
hold good or not in the light of future work, at
reducing
any
rate
action
an interesting of
certain
fact that,
by the
chemical substances
PRESSURE MARKS DEVELOPABLE. upon the
a compound can be formed
silver haloids,
which behaves towards developers
same way
191
as the product formed
in precisely the
by
the action of
light.
Not only can a developable image be produced by chemical means without the action of light, but that the same result can be it has been found simply by mechanical
produced fact
was
for
iodized
made known
first
collodion
by Eder
firmed
Warnerke
and
for
pressure.
This
in
1866 by Carey Lea
plates,
and has been con-
bromized collodion, and by
Abney
for
emulsion
gelatine
The experiment is easily shown. It is only necessary to make marks with the rounded plates.
end of a glass rod on a gelatino-bromide
and
then
develop
exposure to developed as
light.
in
The
one
with
of
usual
way
plate,
without
pressure marks can be
though they had been formed by
the action of light [C]. as
the
the
This must be considered
obscure
photography.
means obvious, and
phenomena
The explanation it
is
have brought the subject
for
this
under
connected is
by
reason that notice,
no I
because
THE CHEMISTRY OF PHOTOGRAPHY.
192
I
do not want you to go away with the
pression
our
that
complete
as
research.
Moreover
offer
which
to
may
room
have
I
or
which
vestigations
no
leave
may have
a
or
change
can
compounds by It
pressure.
that
such
haloids
made
undergo
not
is
a
induced
of
amount
minute
of
as
mixtures to
great
therefore
the
sensitizers,
of
late
show that
improbable
compounds
the presence
in
them
submitting
unstable
in
be
In-
fruitful.
years by Spring and others, seem to
chemical
to
suggestion
been
so
further
for
be
not
are
theories
photographic
im-
silver
should
decomposition
by strong mechanical pressure, the decomposition being so infinitesimal
as
to
be
revealed
only
on application of that most sensitive of microchemical
There
tests, is
the photographic developer.
another point in connection with the
use of the silver haloids for photographic purposes
which we are now is,
in
a position to deal with
;
that
the relative sensitiveness of the three haloids in
different processes.
you
know
that
From the
the thermochemical data
order of sensitiveness,
as
ORDER OF REDUCIBILITY. measured by the
stability of the three
193
compounds,
might be expected to be iodide, bromide, chloride.
The is
order of darkening
the reverse, but this
by photo-decomposition
is
an accident connected
with the colour of the reduction products. order of reducibility of the three
compounds
the same as the order of darkening,
The
bromide, iodide [D]. reducibility
is
little
consider
to
way
these
who
problems,
the reduction of a silver haloid
regarded as the action between the halogen
and hydrogen.
Now
three haloid hydracids
the heat of formation of the is
in
H,C1 H,Br
gram
units
-}
4-
-
H,I
It is
to those
explanation will clear up this point.
In a general
may be
chloride,
the reverse of the order of stability
unaccustomed
but a
viz.
is
fact that the order of
may appear somewhat anomalous are
The
:
22,coo 8,440
6,040
not surprising therefore that silver chloride
should be the most ready to part with to reducing agents.
The
its
chlorine
practical application of
O
THE CHEMISTRY OF PHOTOGRAPHY.
194
these considerations
seen
is
the
in
comparative
facility
with which the haloids can be developed
by the
alkaline
of dry plate
method, when used
The
films.
the form
in
iodide requires a stronger
developer than the bromide, and the latter a stronger
A
developer than the chloride.
developer which
is
just strong
enough to develop a bromide plate
perfection,
might fog a chloride plate owing to
the
easier
of
reducibility
the
latter
These remarks of course apply only developers
which
the
haloids
I
silver
need
hardly
have
a
directly
remind
to reduce the silver
;
an
you,
haloids,
alkaline
reduce
to
acid
developer,
no
has
haloid.
to
tendency
to
tendency
but acts by reduc-
ing the silver nitrate present as a sensitizer. In actual photographic
order of sensitiveness of the haloids maintained, a fact for which
prepared when
we
plicating influences
the
processes
we
consider the
introduced
is
normal
not always
shall
be quite
numerous com-
by
the sensitizer,
the vehicle, or the state of molecular aggregation
of the haloid. sensitiveness
is
In the wet collodion process the
normal,
i.e.
the iodide
is
the most
ORDER OF SENSITIVENESS.
195
sensitive
and the chloride the
gelatine
emulsion processes the bromide
more so than the
most
sensitive
when
the latter
;
is
even
submitted to the ripening pro-
The
sensitiveness.
the
is
iodide,
which confers upon the bromide
cess
In
least sensitive.
order
for
extreme
its
emulsion
gelatine
appears to be bromide, chloride, iodide.
Such
facts as these are at present
very
difficult
to interpret, not only because of the complexity
of the conditions which determine sensitiveness,
but also because of our ignorance of the weight to
be
attached
bromide in
may
gelatine
to
each
condition.
emulsion
may
than
it is
AgBr the
+
because
be
a
the
strictly
of
is
a
In other words
absorbent
an iodine absorbent, so that the system gelatine
system
do
vehicle
bromine
better
Agl
may
+
comparing the haloids
we
the
be more sensitive than the iodide
better sensitizer for the former.
gelatine
Thus
not
know
comparable as
molecular
be more sensitive
gelatine. in the
whether
Then
than
again
in
state of emulsion,
the
salts
are
far as regards their
state
aggregation
we have
no means
O
2
THE CHEMISTRY OF PHOTOGRAPHY.
196
of
whether
knowing
till
this
the
is
complexity
the
same
known we
is
state
of
the two
cases,
and
unable to form
any
in
are
molecular
opinion as to the effect of the molecular condition
upon the
me when
follow
will
dark
as
emulsion
Ag2 Br
Ag3Br3
2,
the in
is
or
,
Chemists
say that we are
I
whether
to
gelatine
of the haloid.
sensitiveness
silver
the
Br n
Agn
,
bromide
condition
and
in
the
in in
a
AgBr,
comparing
such an emulsion with a silver iodide emulsion
we may of
a
action
in reality
different
quite
of
be comparing two molecules
the
consideration
;
Furthermore, the
order.
developer
must
be
is
to
susceptible
a weaker de-
veloper and thus has the advantage
if
into
the bromide, being more reducible
than the iodide,
point of view.
taken
from
this
This discussion will be instructive,
only as showing
how complex
are the
phenomena
with which the photographic chemist has to deal,
and how much has yet
to be learnt before
some
of the most familiar facts can be properly understood.
Closely
connected
with
the
phenomena of
RELAPSE OF INVISIBLE IMAGE. and
development
which
of
the
may now
our attention.
the
general
the
is
action,
photographic destruction
with
197
of
theory
or
disappearance
invisible
image,
a
subject
conveniently claim a share of It
is
a familiar fact to
all
who
have had experience of photographic processes, that the latent indefinite
time.
image cannot be preserved
The
during which the
period
image can be retained
in a
in different processes
from a few hours
;
an
for
developable state varies in the case
of Daguerreotype to two years or more in the case
With
of a good gelatine plate.
the lapse of time
the developable image gradually fades out in processes,
and
we have now
to
consider
all
the
explanation of this phenomenon.
Looking
at the invisible
image as a photo-reduc-
product we shall be prepared to admit that
tion
such a compound, like
all
susceptible of oxidation [E]. this it
reduced products,
is
In accordance with
view of the composition of the invisible image,
is
found that the latter can be destroyed by
oxidizing agents, using this term in a wide sense.
This
fact, I
need hardly stop to point out, gives
193
THE CHEMISTRY OF PHOTOGRAPHY.
additional support to the view that the invisible
image
is
product and
a chemical
physical modification of the haloid. that the
most
reduced haloid
that the
a mere
It is
obvious
regenerating the
direct
way
that
to say of restoring the lost
halogen to the film of the halogen
of
not
is is
itself.
to apply a further quantity
Of
course
not essential
it is
same halogen should be
applied, because
you can readily understand that there may be a series of
chemically analogous reduction products
oxyhaloids or whatever they
one halogen
may
may
be
which
Thus the
another.
replace
in
photo-reduction product of silver chloride would
be destroyed by bromine with the formation of a mixture of
silver chloride
halogens are
among
and bromide, so that the
the most effective agents for
destroying the invisible image.
exposed Daguerreotype plate
If for instance is
an
submitted to the
vapour of bromine or iodine, no picture can be obtained on development the
work done by
precisely silver
the halogen has undone
light.
analogous to that
chloride
is
exposed
The phenomenon is which occurs when to
light
in
a closed
DESTRUCTION OF INVISIBLE IMAGE. vessel.
You have
chlorine
is
seen in a former lecture that
evolved
when
haloid
this
sealed
up
becomes
If the chloride
coloured by photo-decomposition. is
199
a tube the halogen cannot escape,
in
and when the tube
is
removed from the influence
of light the action slowly becomes reversed
the
;
liberated chlorine reacts with the reduction product
and regenerates
darkened by
latter slightly
A
silver chloride.
light
tube of the
and put away
during the night will be found to have become white again by the morning.
such as
nitric acid, the
Oxidizing agents
chromates, permanganates,
metallic perhaloids, &c., are equally effective
in
destroying the invisible image [F].
The next
step
is
to connect these facts with the
spontaneous relapse of the invisible image
a task
which, in the absence of precise knowledge con-
cerning the chemical composition of the reduction product, form. are
but
is
by no means an easy one
Since
known
oxidizing
to
natural
of the latter
or
to
halogenizing agents
destroy the invisible image,
to is
per-
it
is
suppose that the disappearance
due to gradual oxidation or to
THE CHEMISTRY OF PHOTOGRAPHY.
200
There can be but
rehalogenization.
that
this
although
it
is
difficult in
doubt
true in a general way,
is
explanation
little
many
cases to follow the
exact course of the chemical changes which occur.
For
this reason
it
impossible to group
is
all
the
causes of relapse in the different processes under
one
chemical
general
principle
reaction,
be sketched
may
in
but
the
The
outline.
duction of a silver haloid by light
is
broad
not, as
I
re-
need
hardly remind you, a simple case of dissociation the reduction takes place at the expense of the
oxidation or halogenization of the sensitizer, whatever the latter is
may
meant when
I
be.
Chemists
say
that
directly, but
water
may
may
know what
halogenization
oxidation are often synonymous.
halogen for instance
will
The
and
liberated
not attack the sensitizer
take part in the reaction,
the halogen decomposing the latter and liberating
the oxygen which, in
the
nascent condition,
absorbed by or oxidizes the sensitizer C1 2 4-
H O + sensitizer ?
2
is
:
H Cl + (sensitizer oxidized).
In other cases again the halogen
may
be directly
REVERSAL OF CHEMICAL ACTION.
201
absorbed by the sensitizer, forming substitution or additive
of
Whichever of these modes
products.
action
takes place,
photographic process film
reduction
Now when is
clear that in every
is
it
we have formed and
product
oxidation
the stimulus of light
is
may
same
product.
withdrawn there the outward
no further liberation of halogen
tension, if I
in the
use such an expression, of the
halogen ceases, and we have reduced product in contact with oxidized product, an unstable system
capable of reacting chemically.
Such a reaction
would take place but slowly, partly owing to the solid
condition
of
the reacting
substances
and
partly depending on the stability of the oxidized
product, but as the reaction goes on the reduced
product would gradually become oxidized, while the
oxidized product would at
become reduced restored to
its
the
film
would
original condition
ture
would fade away.
that
we have what may be
same time
the
;
be
gradually
the latent pic-
In such cases
it
is
clear
considered as a reversed
chemical change.
The explanation which
is
here submitted
is
no
THE CHEMISTRY OF PHOTOGRAPHY.
202
doubt true "
be
in the abstract, but
in the air
"
deal with
me
Let
practical side only.
some of the
iodine than
in
free
may be
photography from
its
endeavour to
illustrate
principles
To
laid
begin
the Daguerreotype plate.
we have
a reduced product poorer
the original silver iodide
amount of
certain
may
it
are
typical processes.
with the simplest case
After exposure
afraid
who
by applying the
the explanation to
am
as far as concerns those
accustomed to
down
I
that halogen.
The
by a
iodine set
regarded as combined, wholly or partly,
with the excess of silver iodide, a possibility for
which you have been prepared
We
151).
(p.
thus
have
in a
reduction
contact with iodized silver iodide. is
product
But the
in
latter
a comparatively feeble compound, and as soon as
the plate it
former lecture
is
withdrawn from the influence of
begins to give
runs the
in the film
down film
its
The chemical
product.
duced
back
is
obliterated.
in the
tension which
by the action of dark
re-iodized
light
iodine to the reduction is
thus pro-
light gradually
the de-iodized portion of
and the
invisible
image
is
FADING OF IMAGE IN COLLODION PROCESS. Consider process.
by the
in
The
203
the next place the wet collodion liberated
iodine
is
here absorbed
(silver nitrate), possibly in
sensitizer
ac-
cordance with the equation:
+ 6AgNO 3 +3H 2O=5AgI+AgIO 3 In the absence of the external stimulus which, as long as
it
acts
is
tending to set free iodine,
it
not improbable that the mixture of oxidizing
is
substances in contact with the reduced
product
gradually react in the reverse manner, liberating iodine z>.
and rehalogenizing the reduced
destroying
the
invisible
product,
image according to
the reaction:
5AgI + AgI0 3 +
6HN0 = 3
6AgNO 3 + 3H 2 O + Whether
this
represents
61
(absorbed).
the actual course of
events or not must be decided
by
future work,
but you will readily understand that the reduction
product could not remain
for
any great length
of time in contact with nitric acid and an iodate
THE CHEMISTRY OF PHOTOGRAPHY,
204
without becoming oxidized. that
alone
acid
nitric
is
is
indeed
capable of
From
the latent image [G]. it
It
known
destroying
these considerations
follows that a wet collodion plate should retain
its
longer after exposure
impression
were washed of
free
sistence of the
It
the film
from the secondary products
photo-decomposition.
to be the case.
if
is
been
has
This
found
obvious also that the per-
image would be prolonged
the
if
formation of highly oxidized products were pre-
vented ab
initio.
The
truth
of
this
has been verified by Professor H.
W.
deduction
Vogel,
who
exposed an iodized collodion plate under sodium sulphite,
a
reducing
prevents the acid
agent
which
effectually
formation of an iodate or of nitric
:
Na 2 SO 8 +H 2 O = Na 2 SO 4 + 2HI The for is
a
invisible
much
image
is
retained
by such a
longer time than when
plate
silver nitrate
the sensitizer. In
cases
such as have been
where the chemical action
of
now the
dealt with, sensitizer
is
FADING OF IMAGE IN DRY PLATES. obvious, or where
of
degree
205
can be conjectured with some
it
cause of
the
probability,
the disap-
pearance of the latent image can be represented chemically with more
when we come
or
less
But
plausibility.
to deal with sensitizers like tannin
or gelatine in the dry plate processes, the explanation
is
much more
difficult
owing to our ignorance
of the nature of the halogenized products, and
we can
at
present
only advance
Thus the halogenized in the
absence of
gelatine for
light,
and
by analogy. example may
contact with the
in
reduced silver haloid, gradually rehalogenize the generally believed
latter.
It
spheric
oxygen
is
(or
also
atmo-
that
ozone) plays a part in
obliteration of the invisible
the
in fact it
has
been proved by experiment that ozone acts
like
other
The
in
agents
oxidizing
destruction of the
image
this
image may
sensitizer
and so
may
;
that
is
to say
oxidize the halogenized
liberate the halogen,
which then
The
longevity
attacks
the
of
impression on
the
such a case be
in
due to indirect rehalogenization the oxygen or ozone
respect.
reduction
product.
dry gelatine plates
may
THE CHEMISTRY OF PHOTOGRAPHY.
206
be due to the being its
in the solid state
can part but slowly with
halogen, while at the same time the action of
the air it
fact that the halogenized sensitizer
is
for the
same reason
retarded.
Nor must
be forgotten that the particles of the reduction
product are actually imbedded
in the vehicle in-
stead of forming a surface film as in the collodion
wet
plate.
Among
the
reagents which destroy the
latent
image and of which the mode of action
is
no means
Nitric
acid
clear,
are
the
mineral
acids.
by
no doubt acts simply as an oxidizer, but the
haloid hydracids cannot act directly in this way. It
is
extremely probable that there
case of these acids a film-reaction in acid
is
side
with reduction product, and
decomposed by being
in
which the
contact on one
with atmospheric oxygen, as shown ing scheme
the
in
is
on the in
other
the follow-
:
-Hcn HBr (HI
Reduction product + 2 \
V
+O =
I
(
Silver
-{
(
Chloride
Bromide Iodide
)
V J
+
HO
DESTRUCTIVE AGENTS. If for the is
product
moment we assume
207
that the reduction
actually an oxyhaloid, the mineral acids
might be supposed to act directly upon such a
compound
in
accordance with the equations
:
Ag4 OI 2 + 2HNOy=2AgI + 2AgNO 3 + H 2 O Ag4 OBr2 + 2H I=2AgI + 2AgBr + H 2 O But
hold
explanation does not appear to
this
good because
carries with
it
it
the
implication
that the silver haloids should not undergo photo-
decomposition when immersed
and
reduction
the
that
mineral acids,
in
products when
should be decomposable by such acids.
ment disproves
haloid
bromic
is
deduction
bromide can
or
chloride
this
suspended
acid,
in
be
;
formed Experi-
darkened
silver
formed when
hydrochloric
and the darkened
the
or hydro-
product
is
not
bleached by immersion in these acids, even when the latter
are
of
sufficient
the latent image.
no action in
in the
It
strength to destroy
appears that the acids have
cold on the reduction
bulk when this product
tact with the air, as
is
is
the case
product
excluded from con-
when
it is
suspended
THE CHEMISTRY OF PHOTOGRAPHY.
208
the
in
acid
thin
film
action,
acids
the
and that that
probable
the
reduction
spread over a plate in the form of a
is
product
But when
solution.
in the process.
is
a destructive
readily exert
the reason
why
oxygen
atmospheric
seems so
it
takes
part
1
The explanation of
the destruction
or
spon-
taneous disappearance of the latent image which
has been
advance
submitted will enable us to
a step towards the consideration of another phen-
omenon which has long been a puzzle I
photographers
allude to the reversal or solar-
isation of the image.
from the experimental as
we proceed
ledge
of
the
in
Let us approach
this subject
side, interpreting the results
the light of our present
conditions
of the
struction
to practical
the
necessary for
reduction product.
know-
we
If
de-
take
a sheet of paper coated with silver chloride and
darken of 1
may
it
by exposure
reduction It is
to light,
product which
we have
can
of
a surface
course
be
not improbable that the halogenized sensitizer (or vehicle)
give back
its
halogen when acted upon by mineral acids in
the presence of the reduction product. these acids
may
The
destructive action of
thus be due to indirect rehalogenization.
RE YERSIXG A GENTS.
209
bleached by any substance which acts as a re-
This experiment
halogenizing agent [H]. viously nothing
more than a
of that which occurs
when
treated with similar
is
this lecture)
Now
visible
demonstration
the invisible product
reagents (See exp.
F
of
and requires no further explanation.
was observed by Lassaigne
it
ob-
is
in
1839,
and
about the same time by Sir John Herschel, that a solution of potassium iodide also bleaches the
darkened product of photo-decomposition under the influence of light, a fact which was investigated others if
we bear
by Robert Hunt, Fox Talbot and This result
[I].
in
further
mind the
is
also easily
explicable
fact alluded to in a
lecture (p. 25), that potassium iodide
is
former
susceptible
of photo-oxidation by atmospheric oxygen with the
liberation
Herschel's in
of
In
iodine.
Lassaigne's
and
experiment we have potassium iodide
contact with a reducing agent on one side and
with atmospheric oxygen on the other conditions
are
favourable
of the potassium iodide sensitive
salt
and
the
for
;
all
the
the decomposition the photo-
the latter
is
reduction
product
acts
THE CHEMISTRY OF PHOTOGRAPHY.
210
towards
as a
it
sensitizer,
halogenized
and
and chloride
act in a similar
because these
thereby becoming re-
salts are
more
way but more
of greatest
point
connection with these facts
slowly,
stable in the presence
of light and oxygen than the iodide
The
bromide
Potassium
bleached.
[J].
importance is
us
to
the strict
in
analogy
which obtains between the bleaching or reversing action of the alkaline haloids and the destruction
of the reduction product, visible or invisible, by
The only
dif-
the latter act at once upon
the
oxidizing or halogenizing agents. ference
is
reduction
that
product
in
act only under the stimulus of light acids,
c.
the former
the dark, while l ;
the mineral
are in the one case chemical reagents,
while the alkaline haloids are in the other case 1 It has been observed that potassium iodide to some extent bleaches darkened silver chloride paper even in the dark, but
this
preliminary action
probably due to the formation of a
is
certain quantity of the lighter coloured iodo-reduction product
double
decomposition.
reaction
would be
Assuming the
oxyhaloid
formula
by the
:
Ag4 OGl 2 + 2KI = Ag4 OI 2 +
2KC1.
This would be analogous to the well-known decomposition of silver chloride
by potassium
iodide.
RE VERSAL BY POTA SSIUM photochemical
example
A
IODIDE.
Consider a
reagents.
2
1 1
concrete
:
sheet of paper coated with a silver haloid,
say the chloride,
is
exposed to
for
light
a few
seconds and a stripe of hydriodic acid painted
on
On
it.
washing and developing, the portion
acted upon by the acid
remains white, because
the reduction product has been rehalogenized in
accordance with principles with which familiar. is
paper a
In
next place a similar sheet of
the
darkened by exposure, then painted with
stripe of
exposed
you are
to
potassium iodide solution and again This
light.
schel experiment,
is
the
Lassaigne-Her-
and you know what happens
the portion of the paper painted with the potas-
sium
iodide in the presence
of light behaves exactly
the hydriodic acid in the absence final result, so
duct, I
is
the
The potassium
becomes bleached.
iodide
far as
same
need hardly
in
of
light,
like
and the
concerns the reduction pro-
both
cases.
stop to point out the practical
application of this bleaching action of potassium
iodide
;
but you will readily understand that P 2
if
a
1
THE CHEMIS TR Y OF PHO TO GRAPH Y.
2
sheet of darkened silver chloride paper
coated
is
with a solution of potassium iodide and exposed
under a design, we
have a print
shall
in
which those
portions of the surface protected from the light re-
main dark while the exposed portions become bleached.
from
A
process for obtaining positive prints
based
has been
&c.
engravings,
on
this
principle [K].
From
the
the alkaline
bered
and
which
haloids,
the
upon
depend
destruction itself
plate
it
be remem-
must
of
co-operation
we
led
of the latent image on
the
without
the
are
extraneous
aid
familiar under the
name
of " solarisation," because
an
effect
ally
in
the presence of strong sunlight.
first
describe
is
plate
gains
is
in
of a
This phenomenon has long been
reversing agent.
it
light
naturally
atmospheric oxygen, the
to
of such reversing agents as
action
produced by over-exposure, especi-
the
facts
in
exposed to strong intensity
then begins to
up
fall off.
landscape the sky
outline. light,
me
If a sensitive
the latent image
to a
certain
Thus
in
may come
Let
point
and
an over-exposed
out light instead
CONDITIONS OF SOLARISA TION. of dark
the negative,
in
we should have
a reversal of natural
process
is
more
solarised
by
of white.
this
defect,
tendency This
over-exposure.
being the result of too strong an illumination
upon
certain
of the plate,
portions
apparent that the high lights
by
and
be said that the
may
it
printing
effect
sensitive the plate the greater the
become
effect
from
free
altogether
but speaking generally
to
on
that
sky would appear black instead
the
No
so
213
will
be
may
picture
means become reversed and give an un-
this
natural
of light
distribution
The
print.
through
the the
and shade
enabled
of Mr.
kindness negative
am
I
was
seen that the trees have
John
taken
years ago on a wet collodion
well
is
appearance
general
the silver print which
whom
a
in
it
a
in
seen
Spiller,
great
plate.
in
exhibit
to
It
the
by
many
will
be
come out almost white
against a dark sky in the positive.
The
conditions leading to solarisation, and the
peculiarities in the
phenomenon
studied
observers,
by
many
itself,
and
have been
especially
by
Abney, but beyond the establishment of the very
THE CHEMISTRY OF PHOTOGRAPHY.
214
important fact that atmospheric oxidation essential factor in its production,
facts
and
point,
I
has led in
In
an
must be con-
it
fessed that our theoretical notions are
what vague.
is
some-
still
attempting to co-ordinate the
them from a chemical stand-
to explain
am prompted by the same motive me to dwell upon other obscure
photographic theories,
suggestions which
the
viz.
which points
hope that the
venture to put forward
I
may
serve as a stimulus to further experimental inquiry.
The phenomenon
of
been
has
solarisation
observed by Bennett, Janssen, and others to of a recurrent character.
has
observer
phases in
solar
upon
experiments
of the
dry plates
In
course
the
the
to
light
process
of
spontaneous
;
that
is
to
agent.
dition
in
which
is
it
reversing
appears that the
succeeded by a neutral con-
the
plate
is
on development and shows no pression (ist neutral
reversal
say reversal by the
these observations
ordinary negative
last
successive
film itself without the use of a special
From
of his
photography, this
brought
be
stage).
uniformly sign
This
dark
of an
last
stage
imis
NA TURE OF SOLARISA TION. image coming out
the
followed by reversal,
The
a positive on development. followed
by another
whole plate light field
The
is
on
ordinary
negative,
each
other
light,
next
uniformly
neutral stage).
by
a
second
and the phenomena succeed in
it
same order
the
effects
and
(2nd
is
as
which the a
gives
succeeded
is
again
These are the strong
and
development
condition
reversal
neutral stage, in
solarised
last
215
is
as before.
of continued exposure to
estimated that the second
negative stage requires for
its
production a light
of 100,000 times the intensity of that required for the formation of the
There are other
first
facts
negative image [L].
connected with solarisation
which must be taken into account before presented what
in
termed a complete long been
known
legal case.
I
have
phraseology would be In the
first
place
it
has
that the preliminary exposure of
a sensitive plate to diffused white light greatly facilitates
subsequent reversal.
Then
the strength
of the developer has to be considered.
A strong
developer acts in the same
way
as over-exposure or
too great an intensity of
light,
so that a solarised
216
THE CHEMISTRY OF PHOTOGRAPHY.
plate might give an ordinary negative with a
weak
developer, and a reversed negative (positive) with a
Then again
strong developer.
the
through
chiefly
it
has been found, of Abney,
researches
that
oxidizing agents facilitate reversal, while reducing
agents retard
it
or prevent
it
altogether.
Oxidizing
agents and preliminary exposure act in the same
way.
A
washed with a chromate, perman-
plate
ganate, &c.,
is
washed with a
easily reversed, while a similar plate nitrite or sulphite is
not susceptible
of solarisation with ordinary exposures.
must be borne reversal
mind
in
go on invisibly
that the in
Lastly,
it
phenomena of
the film because the
amount of reduction product formed never reaches Eder
a visible quantity.
bromide plate to
may
states that a gelatino-
be exposed for a
sufficient
time
produce strong solarisation on development with
ferrous oxalate, without a trace
being apparent.
now
to
be
Such are the
dealt
with
from
of discoloration facts
a
which have
chemical point
of view.
At
the outset
we
are as before confronted with
our ignorance on two points, the chemical com-
DIRECT POSITIVE PICTURES. position of the reduction product
217
and of the halo-
genized sensitizer, so that any theory of solarisation
can at present be expressed only in very general terms.
Now
reversing
the
idea to be grasped
first
like
agents
potassium
upon the
the
manner previously explained
fresh
+ 2H O + O
in
2
product,
iodide
for
i.e.
1859 that
will re-
I
-.;
4KOH +
2l 2
:
,
it
is
we take an
Potassium
can be used as an
artificial
Poitevin showed as long ago as
possible to get a positive on glass
instead of a negative
by means of
this substance.
iodized collodion plate, sensitize
and then expose
it,
to diffuse light for a few seconds,
get a film of reduction product on the surface
of unaltered haloid. to
2
the latent image.
instance
solarising agent.
we
and
in
a precisely similar manner upon the in-
visible
If
which
your memories by repeating the equation
4KI act
iodide,
that
product of photo-reduction
acts
visible
is
remove
potassium the camera
silver
nitrate,
iodide for
If the plate
or
then washed
coated with a film of
solution,
three
is
and then exposed four times
in
the period
THE CHEMISTRY OF PHOTOGRAPHY.
218
necessary to get a good negative, the most strongly illuminated portions of the
become
film
rehalo-
genized, while the deep shadows remain as unaltered
reduction product, and the intermediate shades get
On
partially rehalogenized.
come out
lights therefore
development the high
white, the
shadows dark,
and the intermediate shades of an intermediate
we
other words
in
This
negative.
tint
get a positive instead of a is
experiment
for
the invisible
image what the Lassaigne-Herschel experiment product of photo- reduction [M].
for the visible
The
principle
Poitevin's this
that
:
revealed
image.
it
just
amounts
agent It
is
is
able to act as a
by rehalogenizing the
for this
reason
that
an emulsion, because ness of the latter. this
salt
a former lecture
it
if
left
in
diminishes the sensitive-
That
is
why
by washing, (p.
invisible
an excess of
potassium bromide acts detrimentally
remove
to
under the joint influence of
and atmospheric oxygen,
reversing
experiment of
this
any photochemical reagent capable of
liberating a halogen light
by
a very simple one
is
is
123).
as
it
is
essential to
pointed out in
REVERSING ACTION OF SENSITIZER. In
ordinary
special
of
cases
solarisation,
photochemical reagent
added
is
219
no
where
to the film,
there must be something present which plays the part of such a substance.
we must
sensitizer that
tion of the
believe, to the
I
is,
look for the whole explana-
How the
phenomenon.
will of course
It
sensitizer acts
depend upon the particular process
the chemical reactions which take place
may
present quite impossible to follow out, but
be
fairly asserted that
when the
genized up to a certain point
promoted by
and taking place even
We 1
in
may
it
begins to react reaction
being
oxygen and moisture,
the presence of light.
thus connect solarisation
The
be at
sensitizer is halo-
with the reduction product, the the presence of
it
;
l
with those other
observation of Sabatier, that a collodion wet plate becomes
if, towards the end of development, daylight is suddenly admitted to the room, relates to cases of what may be called
reversed
pseudo-solarisation,
the present
which do not come under consideration
The
category.
was given by Seely
in
1860.
that if the surface of a plate
in
explanation of this kind of reversal
is
It
depends simply upon the
fact
strongly illuminated during develop-
ment, the portions of the picture already developed, being represented by a more or less opaque film of metallic silver, act as a screen and prevent the further action of light on the portions of the film beneath them, whereas the undeveloped portions of the
THE CHEMISTRY OF PHOTOGRAPHY.
220
phenomena which have tion
led us
up
to
its
considera-
with the destruction of the invisible image by
;
oxidizing or halogenizing agents, with the destruction
of this image
in
the
dark by the haloid
hydracids plus atmospheric oxygen, and with the
spontaneous relapse of the latent picture in the
dark by the action of the halogenized sensitizer itself,
more or
less
Let us see how
when applied
aided by the oxygen of the
air.
explanation will carry us
far this
to special cases.
Imagine a collodion wet plate exposed to the continued action of strong
The
light.
silver iodide
goes on losing iodine, while the sensitizer nitrate) concurrently absorbs the
(silver
halogen with the
formation of oxidized products, probably iodate and nitric acid.
The amount
silvei
of these oxidized
products at length becomes so great that they begin to react with the reduction product
the action
surface are susceptible of photo-reduction to an extent proportional to the intensity of the light
observation referred
which
falls
the light which
upon them. is
If,
thus admitted
as in the is
stronger than that by which the latent picture was first formed, it is obvious that the undeveloped portions of the surface will come out darker
than the
first
to,
developed portions,
i.e.
the picture will be reversed.
RECURRENT SOLARISA TION. begins to reverse
work done by the undone.
and a
itself,
first
lighter
than
shorter exposure.
We
if
we develop \ve
the plate
it
developed after a
have arrived at the
first
the system,
Reduction product still
the
Supposing the action to continue
neutral stage.
we have
amount of
action of light becomes
If at this point
would be
certain
22 1
+ AgIO 3 + HNO 3 + O,,
undergoing chemical change, the reduction
product becomes more and more halogenized and oxidized versed.
the whole action of the light
till
At
this point
true reversal,
re-
the stage of
and the plate on development would But
give no result.
same
we have reached
is
state as
when
we have normal
affairs
have now arrived at the
the experiment was started
;
haloid under a film of silver nitrate
again, this sensitizing salt resulting from the re-
duction by the reduction product of the oxidized
products
first
formed, and the cycle recommences.
After a further exposure
we should
get a negative
of the second order on development, and so on.
Consider again the solarisation of a gelatine-
222
THE CHEMISTRY OF PHOTOGRAPHY.
bromide
The
plate.
more brominated
becomes more and
gelatine
till it
begins to rehalogenize the
reduction product; then the latter becomes more or less
converted into normal bromide, state
original
of
affairs
operations begin to repeat themselves. process
is
the the
The whole
nothing more than an accelerated cyclical
repetition of that
which occurs
the spontaneous
in
disappearance of the latent image
So
and
restored
is
till
far the
explanation
may
in the dark.
be considered to
hold good in a general way, but there are other points which have
to
with the theory.
Perhaps the most obscure of
these
is
be brought into harmony
the part played
by oxygen and by
oxi-
dizing agents, but the obscurity here arises from
our
ignorance
of
chemical
the
halogenized sensitizer, and
good reason
for dwelling
this,
upon
nature
by the way,
it.
It
may
of
the
is
one
be safely
asserted that oxidizing agents act inimically to the liberation of halogen.
I
may remind you
of
some
of our earliest experiments in this direction. sheet of paper coated with a silver haloid
exposed to
light
A and
remains unacted upon at those
FUNCTION OF OXIDIZING AGENTS. portions of
with
its
oxidizing
surface which have been
such
solutions,
as
223
painted
mercuric
or
stannic chloride, potassium dichromate, &c., (Exp.
A
Now
Lect. III. p. 100).
any substance which
is
inimical to the liberation of halogen cannot act as a sensitizer,
and
if in
contact with a substance which
can act in this capacity action
of the latter
absorbing capacity.
it
will lessen the sensitizing
by diminishing
Thus a
its
halogen
sensitive plate in
an
oxidizing solution, or washed over with such a is
solution,
easily solarised, because the sensitizer,
being in contact with the oxidizing agent, can hold a less charge of halogen its
it
parts
more
easily with
halogen to the reduction product, and so more
readily rehalogenizes the latter.
Whether the oxygen of the oxidizer comes absorbed by the sensitizer, and
actually bereplaces the
halogen which the latter has passed back to the
re-
duction product, must depend upon the nature of the sensitizer.
Evidence
is
not wanting that such oxi-
dation does actually occur. if
a gelatino-bromide plate
image
is
Thus Abney states is
exposed
till
that
a visible
apparent, the portions of the film corre-
THE CHEMISTRY OF PHOTOGRAPH}'.
224
spending to the image do not swell up when the
immersed
plate
is
well
known
water. 1
in
to be
Such a property
conferred
upon
plicated in
by the
There
sideration which tends
however another con-
is
show
to
that
absorbed by the sensitizer
actually
oxygen during
process of reversal on dry plates, and that
is
is
the the
the intervals which separate the succes-
fact that
sive
com-
is
brominated gelatine acts
fact that
a similar way.
by
gelatine
oxidizing agents, but this interpretation
is
phases are not uniform but of continuously If the
increasing length.
process were simply a
case of alternate bromination and debromination
of the sensitizer, the intervals might be expected to
be uniform.
The
fact that the
points to the using zer
:
it
up of something
in the sensiti-
indicates the exhaustion of the halogen-
absorbing power
of
the
source of such
extraneous
oxygen
intervals lengthen
of
the
oxidizing
latter,
and
the
cnfeeblement solution
or
only is
of
the the
atmosphere.
These considerations 1
will
enable us to strip the
Treatise on Photography, 5th ed. p. 309.
COURSE OF CHEMICAL CHANGES. phenomenon of spontaneous its
We
mystery.
say gelatino-bromide
imbedded bathed on
in a its
exposed to
up
to
some of
reversal of
must look upon a
225
sensitive plate
as a film of silver bromide
bromine-absorbing substance, and
by atmospheric oxygen. When
surface
light the vehicle
becomes brominated
degree of saturation
a certain
complex
;
bromo-derivatives, or additive compounds, or oxi-
dized products are formed, and these at length begin to react with the reduction product aided
the external oxygen.
The
may be
process
regarded
as analogous to the destruction of the latent
by the haloid hydracids, and indeed
it
probable that some hydrobromic acid
by
not im-
is
is
image
actually
formed by the bromination of the gelatine, and takes part in the process of reversal.
events
will
scheme
:
AgBr +
Gelatine
be
understood
from
The the
+ O
course of following
First stage.
gelatine
+
oxidized products
+ HBr {Brominated Debrominated )
^j
V-
+ O
First negative.
(
HoO
\
First neutral
stage and reversal.
THE CHEMISTRY OF PHOTOGRAPHY.
226
From
these explanations the other facts
con-
nected with solarisation follow as necessary consequences. plate
It
obvious that a highly sensitive
is
would halogenize
than a
less sensitive plate
occurs
more readily
We
sensitizer
its
that
;
most
in the
is
more rapidly
why
solarisation
sensitive processes.
must be prepared to admit that a vehicle
capable of becoming highly charged with halo-
genized products might act without the aid of
oxygen, and
it
has accordingly been found that a
gelatinp-bromide
plate
prolonged exposure
be
can
reversed
in a neutral liquid
which prevents access of
air.
1
by
(benzene)
Then again we
see
that a substance capable of neutralising the effect
of external oxidation, and of preventing the accu-
mulation of too large a quantity of halogenized products in the sensitizer, must act antagonistically to reversal.
on the
film.
Such
So
is
the action of reducing agents
also
process which partly
it
is
now
evident that any
halogenizes
the
sensitizer
1
"If a plate be exposed in benzene, however (a liquid which does not permeate through the gelatine), the phenomena are still existent."
Abney's Treatise on Photography, 5th ed.
p. 309.
FUNCTION OF THE DEVELOPER. must the
accelerate
the
of
rate
saturation point,
i.e.
because
reversal,
halogenized sensitizer
partially
227
nearer
is
of halogenization
the point
necessary for the reversal of the reaction to set
This
why a preliminary exposure of
is
its
in.
the plate is
so favourable to solarisation.
The
last
attention
is
phase of the subject demanding our the part played
have to follow out plate as
upon a
action
its
When
film.
exposed
action
its
compared with
by the developer
solarised
upon a normally takes
reversal
we
place,
the
portions of the film where the greatest action has
been exerted,
i.e.
the strongest lights, consist of the
most highly halogenized (and oxidized) portions of
At
the sensitizer or vehicle.
the
same
time,
owing
to the length of exposure, the silver haloid over the
whole surface of the plate posed.
Now
is
to
some extent decom-
the general result of halogenizing or
oxidizing such a vehicle as collodion or gelatine is
to harden
solutions
;
it,
and make
the greater the
the less pervious does
it
it
less
pervious to aqueous
amount of halogenization
become
[N].
When
fore the developing solution is applied, the
Q
there-
amount 2
THE CHEMISTRY OF PHOTOGRAPHY.
228
of silver deposited or reduced on any part of the film
is
determined by the readiness with which this
solution can get at the reduction product
the sensitizer is
where
most highly halogenized not only
is
the developer less able to attack the reduction
product, but there
may
be
in
some cases
of the latter present owing to
by the
On
reversing action.
portions
of
the
illumination are
film
the image
is
partial destruction
the other hand, the
which have
;
these portions
reversed on development.
proportional to the
deposit
;
in is
less
come out
solarised portions remain
development the density of the
formed
received
more pervious and respond sooner
to the developing action
dark, while the
its
actually less
light
;
In ordinary
silver deposit
is
amount of reduction product
a solarised film the density of the stiver inversely proportional to the degree of
halogenization of the sensitizer.
This
is
doubtless
the chief function of the developer, but the action is
further
complicated by the element of time
having to be taken into account.
During the process of development the
solarised
portions must be regarded as also undergoing reduc-
FUNCTION OF THE DEVELOPER. tion (or accretion) to
some extent
is
entirely a
With a strong de-
case of relative rates of action.
veloper the action upon
it is
229
the unreversed portions
exerted at once, because these are the most
A
pervious to the solution.
weak
developer, on
the other hand, cannot attack the relatively small
amount of reduction product on the unreversed portions, but as effect at all
vious
it
solarised
it
must act longer
to produce
has time to penetrate the parts
of
the
film,
and
any
less per-
to reach
amount of reduction product which they contain. Hence a weak developer
the relatively larger
give a negative, and a strong developer a
may
positive
This,
I
on development of an over-exposed
may
remind you,
characteristics of the
is
plate.
one of the well-known
phenomenon with which we
have been dealing. I
have been tempted to dwell at some length
upon these
residual
phenomena, both because of
the promising fields of investigation which they offer to the scientific student,
importance action.
in the
and because of
their
general theory of photographic
There has been too
great
a
tendency
230
THE CHEMISTRY OF PHOTOGRAPHY.
hitherto to limit attention to the sensitive silver haloid, as
future
though
we must
with which
it
A
The
two correlated
silver haloid
factors
and the
sensitizer
which cannot be con-
any of our photographic
processes.
ray of light falling upon a sensitive plate
like the
which
is
In
associated as playing an equally
is
sidered apart in
in chief.
look upon the sensitizer or vehicle
important part. are
were the agent
this
is
motive power driving a dynamo-machine feeding a storage
cell.
When
of the latter has reached a certain point
the charge
it is
capable
of reversing the motion of the system, and of converting the
dynamo
into a motor.
plays the part of such a storage
becomes charged,
i.e.
The cell
down and
reversal takes place.
when
;
a
halogenized, to
amount, the chemical energy stored up to run
sensitizer
in
it
certain it
begins
APPENDIX TO LECTURE
A
187).
(p.
A
VI.
solution of potassium oxalate
is
added gradually to a solution of ferrous sulphate in order to show the precipitation of ferrous oxalate
and
its
B
(p.
solution in excess of potassium oxalate. An alkaline solution of milk-sugar 190).
painted in stripes on the surface of a sheet of and after being allowed to act
is
silver chloride paper,
for
a few minutes
(at the
ordinary temperature of
the room) the paper is well washed, and then brushed over with a ferrous oxalate developing solution.
The
stripes
which have been reduced by the milk-
sugar, although before
development undistinguish-
able from the rest of the surface,
come out
intensely
dark.
C
(p.
191).
The experiment
scribed in the text.
is performed as deCare must be taken not to tear
After developing and fixing, the pressure marks can be projected on the screen by means
the film.
of the lantern.
232
THE CHEMISTRY OF PHOTOGRAPHY.
D E
I
(p-
93)-
Repetition of Exp.
J, 2,
Lect. V.
197). Exp. E, Lect. I. is repeated, the of the solution exposed to light being
(p.
portion
divided into two parts before the addition of the There are thus three vessels, (i) ferricyanide.
containing unexposed solution, (2) and (3) conTo one of the latter taining exposed solution.
some chlorine water
added, and
is
The
cyanide to all three.
then
ferri-
chlorinated and the un-
exposed solutions give the same result, showing undone the work done by the
that the chlorine has light.
F
199).
(p.
bromide nitrite,
is
A sheet
of paper coated with silver solution of sodium
sensitized with a
or with silver nitrate, and exposed to the
electric light
till it
The paper
shows
just
faint signs of
darken-
then well washed, and three or four stripes painted on it with various oxidizing solutions, such as bromine water, potassium diing.
is
chromate, mercuric chloride, potassium permanganAfter the reagents have been
ate (acidified), &c.
allowed to act for a few minutes
(in
red light) the
again well washed, and then developed with ferrous oxalate developer. The stripes come out
paper
light
is
on a dark ground, showing the destruction of
the reduction product .
G
(p. 204).
A plate
by the oxidizing is
agents.
coated with iodized collo-
dion and sensitized in the silver nitrate bath in red
APPENDIX TO LECTURE
VI.
233
A
few seconds' exposure to way. white (electric) light is then given, after which one half of the plate is immersed in nitric light in the usual
diffuse
acid (one part 1-4 sp. gr. acid and two parts water), then withdrawn and washed, re-dipped in the silver
and developed by
iron developer.
The
portion of the plate acted upon by the nitric acid remains undeveloped, showing the destruction of the inbath,
product of photo-reduction. sheet of paper coated with silver (p. 209).
visible
H
A
chloride
is
exposed
to
diffuse
white
light
till
distinctly darkened, and then painted with stripes of chlorine water and a solution of iodine in
potassium iodide in order to show the bleaching action of these substances. I
(p.
The darkened
209).
surface of the paper
painted with another experiment solution of iodide and exposed to potassium stripe white light till bleached. This experiment serves
used
in the last
well to
show the
is
similarity in the action of the
potassium iodide under the influence of light,
and
of the chlorine water and iodine solution in the
absence of
light.
A
sheet of paper coated with silver chloride and darkened as before is painted with J (p. 210).
stripes of solutions (about 5 per cent) of
chloride,
bromide and
strong white light
till
iodide,
potassium
and then exposed to
the iodized stripe appears
THE CHEMIS TR Y OF PHO TOGRAPH Y.
234
yellowish
white.
lighter than the
The bromide
ground colour,
is
the iodide, while the chloride
bleached at
K paper
has hardly
A sheet of darkened silver chloride
sensitized with a
is
stripe
all.
212).
(p.
stripe, although then darker than
5
per cent solution of in a moist state
and exposed
potassium iodide, under a design stencilled out
On removing
screen.
out light on a dark little acid to the
a black
in
paper
the screen the design comes ground. The addition of a
potassium
iodide
solution
accelerates the action.
L by
Bennett's experiment can be shown placing a sliding screen of black paper over a (p.
215).
gelatino-bromide plate, and giving different stripes of the surface exposures to the electric light for periods varying from two or three seconds to ten or fifteen minutes. On development by ferrous oxalate the darkness of the stripes increases up to a certain It is impossible exposure, and then falls off again. to name the precise period of exposure necessary
to
show the
different
effects of reversal, as
plates.
An
this varies in
instantaneous exposure of the plate to diffuse light
the whole surface of
hastens the experiment.
M
(p.
218).
An
iodized
sensitized in the silver bath,
collodion
exposed
plate
for a
is
second
or two to diffuse white light, and then washed with
APPENDIX TO LECTURE
VI.
235
One half of the plate is then red light). solution of potassium iodide cent per dipped nitric acid), and the whole with dilute (acidified surface again exposed to white light for about a water
(in
in a 5
minute.
On
washing, re-dipping in silver nitrate,
and developing with the iron developer, the portion of the plate which has been dipped in the potassium iodide solution
comes out much
lighter than the
other portion.
N
A
design is painted with weak bromine water on the surface of a gelatino-bromide (p.
227).
plate (in red light).
After remaining
in
contact
with the film for a minute or two the plate is well washed, and then exposed to diffuse white light for a
few seconds.
On
development by ferrous
oxalate the design comes out
background.
lighter
than the
LECTURE
The Spectrum.
Composition of White Light. tensity
and Photographic
Objects.
Intensity.
Spectrum Photography.
Visual In-
Colours of Natural
Graphic Representa-
Action of the Spectrum on the Silver
tion of Intensity.
Haloids.
VII.
Concurrent Reversal in Mixtures.
Reversal in
Spectrum under various Conditions. Reversal in Solutions of Oxidizing Substances and other Reversing
the
Agents.
WE
have thus
considered
far
photographic pro-
cesses as originating in the photo-decomposition of
the silver haloids without taking into account the particular constituent of the light that produces the
chemical change.
It is
doubtless well
that ordinary white light
of colours, and
it
is
it
made up
of a
to
all
number
a familiar fact that such light
can be decomposed into allowing
is
known
its
component colours by
to pass through a prism of
some dense
DECOMPOSITION OF WHITE LIGHT.
237
transparent substance, such as glass or quartz, or
by causing
it
to be reflected from or transmitted
through a surface on which are ruled a number of very
fine parallel lines. is
decomposition persion
;
In the case of a prism the
produced by refraction and
dis-
the different coloured rays being unequally
refracted, are separated
by the dense medium of the
The
prism through which they pass.
violet
and
blue rays are the most refrangible and the orange
and red are the
least refrangible, while the green
and yellow are refracted to an intermediate extent and thus occupy a position intermediate between the violet and blue on the one side and the orange
and red on the
other.
The decomposition of light by means of a ruled " surface, known technically as a grating," is due to a process called diffraction.
too far into
physical
It
would take me
considerations to
attempt
here to treat of the theories of dispersion and diffraction refer
you
;
to
for this portion of the subject
works on physics.
explanations will suffice to
A
make
I
must
few preliminary
clear those points
which are essential to the complete understanding
238
THE CHEMISTRY OF PHOTOGRAPHY.
of the practical bearing of these familiar facts upon
modern photographic
The
rainbow-tinted band of colours produced
passing a
known
processes.
beam
of white light through a prism
and
as the spectrum,
blue, green, yellow, orange,
and
viz. violet, indigo,
red.
of the intensely glowing carbon
lamp
you see that
is it
now
The spectrum of
points
in the
way
consists of
From what
of explanation,
that the position of
spectrum colour.
more
is
It
a continuous
band
in
in the
has been already said will
it
be understood
particular colour in the
any
a measure of the refrangibility of that will
materially assist us in gaining a
precise idea of the true significance of that
spectrum with which we
shall
in the present lecture, if
the physical nature of
I
have so much to do
give a brief sketch of
light.
Those among you who have studied physics
know
the
before you on the screen, and
which the colours graduate into each other order named.
is
customary to
is
it
recognize seven spectral colours,
electric
by
that light
is
an undulatory movement
highly elastic medium,
known
will in
a
as the ether, which
PHYSICAL NATURE OF COLOUR. all
pervades
239
and penetrates between the
space
When
particles of matter.
the ether
thrown
is
into waves by a sufficiently rapid series of vibra-
wave-movement
the
tions,
is
in
propagated
all
directions from the source of the disturbance as a
centre with a velocity of about 186,000 miles per
second.
the oscillations are below a certain
If
frequency they are
;
human
to affect the
of being
capable
instruments
fail
detected
eye, but
by appropriate
these longer-period waves are
as radiant heat.
On
the other hand
known
we may have
ethereal undulations which are too rapid to affect
the eye
;
these also can be detected
methods well known to Colour
is
physicists.
the visual impression corresponding to
oscillation-frequency.
waves of one
If
we had
a series of ether-
definite rate of oscillation
comes to the same only,
thing,
we should have
one
as you have seen, in
is
or,
what
definite wave-length
a pure monochromatic light
of a certain definite refrangibility.
which
by appropriate
not pure
;
it
is
physical language means
White
light,
polychromatic, that
it
is
a
jumble of ether- waves of different periods and
THE CHEMISTRY OF PHOTOGRAPHY.
240
When
wave-lengths.
a thin slice of such light
analysed by a prism, the spectrum which ceive
is
we
is
per-
the result of the sorting out of the waves
of different lengths and their classification according to wave-length or oscillation-frequency. shortest
The
and most refrangible waves produce upon
the eye the sensation of violet, while the longer
and
less refrangible
of red. well
The
known
waves produce the impression
actual lengths of the ether-waves are to physicists, but
concern ourselves with
now
that the wave-length
is
increases from the violet towards
the red, while
the oscillation-frequency diminishes as the spectrum in the
same
direction.
we
formation which about, because
contingent
it is
it
is
upon
1
The
visible
in the red to line is
H
in
mind
possesses
mode
kind of spectrum that
most familiar to photographic
must be borne
its
investigators.
extreme violet
0-0007606 and of the
is
It
that the extent occupied
spectrum extends from about the Fraunhofer line in the
of
know something
desirable to this
traverse
1
The spectrum formed by a prism certain characters
we need
that
all
;
the wave-length of the
H line 0-0003971
of a millimeter.
A A
REFRA CTION AND DIFFRA CTION SPECTRA. by the
different colours in such a
24 1
spectrum does
not actually represent the relative proportions of these colours present
the white light
in
proportions are necessarily falsified
owing to the unequal
The
violet
frangible,
and
are
blue
rays being the
than the
and spread less
The
orange, and red rays.
by the prism
refrangibility of the colours.
separated
greater extent
these
;
more out
to
re-
a
refrangible yellow,
colours are thus
out at the violet end and squeezed
up
drawn at
the
red end, so that the space between two points at
the more other
refrangible
end separated from each
interval (expressed in
by any given
lengths) would be greater than
senting the
same
the
wave-
space repre-
interval at the red
end of the
spectrum. If
we wish
colour,
and
to observe the true distribution of
we must appeal
this is
to the diffraction spectrum,
accordingly called the normal spectrum.
For most photographic purposes the
refraction
spectrum answers
it is
to
remember
that
all it
requirements, but
well
has the defects indicated.
Then again you must look upon
the extent of the
R
THE CHEMISTRY OF PHOTOGRAPHY.
242
spectrum as a physiological accident de-
visible
pending upon the construction of our eyes, and not as indicating
a
real
ethereal undulations at either
the
to
end of the band of
Both beyond the
visible colours.
limit
physical
and below
violet
the red there are ether-waves incapable of affect-
human
ing
vision
may
already said,
and the
them
to
alter their
fall
can be
this
in
such a
visible
by
way
as to
Substances
property of changing the wave-
length of an ethereal undulation fluorescent [A].
have
substances
certain
upon
wave-length
made
bring them within our visual capacity.
which possess
I
be regarded as radiant heat,
ultra-violet rays
allowing
which
the infra-red waves, as
;
These
ultra-violet
are
said to be
waves have no
special designation, simply because
we have no
specialized organ of sense for perceiving them, but
we
soon learn that from a photographic point
shall
of view they are of the highest importance. In considering instances of photo-decomposition it is
essential that
we should know something more
definite than that a
posed by
light.
compound
If our
is
knowledge
simply decomis
to be
com-
VISUAL AND PHOTOGRAPHIC INTENSITY. we should know what
plete
of the light tion.
is
most
Looking
light,
The
particular constituent
effective in causing
decomposi-
at the visible spectrum of white
such as that of the electric light which
on the screen, the the
maximum
first
thing that strikes us
of visual intensity
is
is is
now that
in the yellow.
and most obvious question that
first
arises is
whether that colour which appears the most tense to the eye
ments made
in-
the most active in promoting
is
photo-decomposition as photographic
243
is
visual intensity the
intensity
The
?
in this direction
same
earliest experi-
take us back to the
year 1777, when Scheele allowed the solar spectrum to
fall
on a sheet of paper coated with
and thus found
that
the
rapidly in the violet rays.
salt
silver chloride,
darkened
most
This fundamental ex-
periment can be easily repeated by throwing our electric
light
spectrum on to a sheet of
You
chloride paper [B].
become perceptibly luminous effect
silver
see the violet end has
discoloured, while the strongly
yellow has
not produced
any
photographic intensity does not
coincide
with visual intensity.
R
visible
2
244
THE CHEMISTRY OF PHOTOGRAPHY.
The has
line of investigation
been
physicists,
opened up by Scheele
by numerous chemists and
followed
among whom
I
need only mention the
names of Herschel, Becquerel,
W.
J.
Fox
Draper,
Talbot, and Robert Hunt, to convince you that the
problem has been regarded as one of no inconsider-
more recent
In
able importance.
photographic investigator self
with the
has
felt
every
who has concerned him-
development of the subject
scientific
necessary to study the action of the
it
spectrum upon the sensitive
times
silver haloids
As the
compounds.
final
or other photo-
outcome of
the work which has hitherto been done,
it
all
may be
taken as fully established that visual intensity and
photochemical activity are fact that
no way
The
related.
yellow and orange appear brighter to us
than violet accident.
in
and
blue
is
another
In the majority of
be photo-sensitive, of the spectrum decomposition.
is
it
physiological
compounds known
happens that the
violet
to
end
the most effective in promoting
Could we look upon nature with a
photographic eye,
we
should
experience
strange reversals of colour impression
;
a
some
wood
in
SUPPOSED CHEMICAL FORCE. springtime carpeted with violets and cinths, for instance,
spectacle
than
wild
would appear a more
meadow
a
245
with
ablaze
hya-
brilliant
golden
buttercups.
That the
violet
and even the
ultra-violet rays
are the most effective in the majority of cases fact that
also
for
salts, for
is
is
a
true not only for the silver haloids, but
the
and mercuric
uranic, cupric,
ferric,
the chromates, and for the salts of gold
and platinum.
In view of this circumstance
it
is
not surprising that the more refrangible end should
have been formerly regarded as the special
chemical force.
physics
we
find the
In
the
region
of
older works
on
spectrum divided into the three
regions of heat, light, and actinism
or chemical
With the advancement of knowledge this the notion that a division has broken down
force.
;
chemical force resided
in the violet rays
was due
simply to the circumstance that the most familiar
compounds, and especially the
more that
sensitive to these rays.
many
frangible
salts
It is
of
now
silver,
well
were
known
substances are sensitive to the less re-
radiations,
and even the
silver haloids
246
THE CHEMISTRY OF PHOTOGRAPHY. we
themselves can, as
presently, have
see
shall
their sensitiveness so modified as to
be decomposed
by the red end of the spectrum.
The importance of knowing
the specific action of
the spectral colours on the silver haloids
be apparent at ever,
that the various
camera screen
If
first sight.
in
may
not
you consider, how-
objects
focussed
on the
order to be subsequently photo-
graphed are possessed of different colours, the necessity for this knowledge will It will
become obvious.
be readily understood that objects will im-
press themselves
upon an ordinary photographic
plate with an intensity proportional to the
amount
of violet and ultra-violet light which enters into the colour which they reflect or
composition of the scatter.
The
fact that reds
and yellows impress
themselves feebly, while violets and blues impress themselves strongly, experiences
of
the
is
one of the most familiar
practical
photographer.
So
also the varying photographic activity manifested
on different days according to the state of the atmosphere, the horizon, &c.,
is
height
well
of
known
the
sun
above the
to all workers with the
COLOURS OF NATURAL OBJECTS. The
camera.
different
247
on
necessary
exposures
amounts
different occasions represent the varying
of blue, violet, and ultra-violet rays, absorbed from the sun's light
by our own atmosphere under
its
different conditions of humidity, or according to
amount of suspended matter which
the It
it
contains.
can easily be understood also that the length
of atmosphere traversed by the solar rays depends altitude of the sun above the horizon,
upon the this
is
light
why
and
the photographic efficiency of day-
greater at noon than earlier or later in
is
the day.
From
the photographer's point of view
it
is
an
extremely fortunate circumstance that the colours of natural objects are never pure.
this I
mean
no colour would appear perfectly mono-
to say that
chromatic
By
we analysed its light and observed its The colour of any natural object is
if
spectrum.
always a mixture
some rays of the spectrum
are absorbed and others are reflected, so that the
colour which finally reaches the eye effect.
In addition to this
white light
is
is
a residual
a certain amount of
scattered from all surfaces except
THE CHEMISTRY OF PHOTOGRAPHY.
248
Were
dead black.
it
for the latter circum-
not
would present much
stance, a photographic picture
more
and shade than we
violent contrasts of light
actually witness.
The composite
of a
character
which
colour
appears simple to the eye can be well shown by
means of
certain artificial colouring matters.
light transmitted
solution of
"
through a glass
aniline blue
"
cell
containing a
appears on the screen
of a rich blue colour, and this solution of "
On
analysing
these
"
iodine
nothing but green.
apparently transmits
green
The
by passing them
colours
through a prism you see that red
is
present in
both cases, a fact which the eye utterly
fails
to
perceive before the prismatic analysis [C]. It will
be evident from the explanations which
have now been given colour in the spectrum
that is
the position
due to the length of the
corresponding ether-wave, so that physical measurement its
it
is
a true
For photographic pur-
necessary to have
positions of reference
we have
of colour independent of
subjective sensation.
poses
of any
some
some recognized
definite lines in the
FIXED LINES IN SOLAR SPECTRUM. spectrum which we
mentioning lines are
the
can
in the
found
about instead
talk
spectrum of sunlight and
The
are generally used for this purpose.
the solar spectrum to which
dark
lines
traversing the
physicist is
who
lines in
allude are narrow
I
spectrum at irregular
intervals in a direction perpendicular to
they are known
of
Such fixed
by name.
colours
249
its
length
;
as the Fraunhofer lines, after the
first
mapped them.
accurately
It
no part of the present subject to explain here
the origin of these dark lines state that they are
;
it
will suffice to
produced by the absorption of
the particular waves which they represent in posi-
by gaseous and vaporous substances
tion
sun's, as
well
as in
our
see
in
the
photograph
The
own atmosphere.
more important of these dark of
the
lines,
solar
the
in
which you spectrum
thrown on the screen, furnish the necessary positions of reference.
In order to study practically the photo-reducibility
of the silver haloids or other compounds
by
different colours of the spectrum, the older experi-
menters often made use of coloured glasses
;
but
250
THE CHEMISTRY OF PHOTOGRAPHY.
this
method
obviously unsatisfactory because
is
by such media
the light transmitted
monochromatic of procedure
is
A
scientific
mode
photograph the spectrum
itself,
[D].
to
seldom
is
more
far
a narrow slice of white light being allowed to pass
through a prism, and the spectrum being then
on
focussed
examined. sun,
the
The
the electric
magnesium, or in rays
of
remember
all
surface
photographic of
source or
oxyhydrogen
be
may
light
light,
be
to
the
burning
any other source of radiation rich refrangibilities.
in carrying
important to
It is
out such experiments that
the materials composing the lenses and prisms of
the spectrographic apparatus have a certain specific well known, for instance,
absorbing power.
It is
that glass absorbs
more or
light,
so that in very exact
less
of the ultra-violet
work we must
either
use a diffraction spectrum or have our lenses and
prisms of quartz, as
first
pointed out by Prof.
Stokes in his classical researches on fluorescence.
When
a spectrum
graphic
surface,
induced
in
is
the
allowed to
fall
on a photo-
amount of decomposition
the different regions
is
shown by the
CUR VES OF INTENSITY.
25 1
degree of darkening of the silver compound, instead of allowing the spectrum to act discoloration
be
developed
in
invisible impression
the usual way.
visible
may
produced, a short exposure
is
given and the
employed by
till
or,
Both these methods have been
The
different experimenters.
results
may be expressed by a graphical method which is now so generally adopted that we must understand
its
principle before
making
Supposing, for example,
further progress.
we wished
visual intensity of the spectral colours
of a curve. lines
We may take
drawn perpendicular
to
the
made
spectrum, the proportional to
the intensity of the colours as seen
more
For
accurately, as
by means
as ordinates a series of
height of these lines being
or,
show the
to
by the
measured photometrically. 1
practical purposes the strongest of the
hofer lines answer
all
eye,
requirements.
The
Fraun-
intensity
of the colour seen at the position corresponding to
each of the selected lines would be marked off as a point on each 1
line,
and the points then joined by a
See Abney and Festing's Bakerian Lecture for 1886.
Trans. Part
II. 1 886, p.
423.
Phil.
THE CHEMISTRY OF PHOTOGRAPHY.
252
curve which would show at a glance the distribu-
The
tion of visual intensity in the spectrum. is
shown
in the
ML
H
diagram
FIG.
a
such a diagram
maximum
little
D.
is
H the
in
it
also
that
near the the
A.
JfaL.
distribution
in
case
this
same method
is
be
in
in
violet.
of heat
that
in the yellow,
side of the line
A
line
extreme
is
the visible
sented by another curve, the
would
B
C
Yellow.
at once seen
is
more refrangible
seen
extends from
way
Green
of visual intensity
to the
It
about
D
F
Blue
VISUAL INTENSITY OF COLOURS OF SOLAR SPECTRUM.
5.
From the
:
G
Violet
result
spectrum red
the In
might
maximum
to
a
similar
be
repre-
of which
the infra-red.
The
applicable to the representation
SPECTRUM PHOTOGRAPHY.
253
The amount
of decom-
of photographic intensity.
by a
position undergone
parts of the spectrum
is
silver haloid in different
shown by the degree
of
darkening on long exposure, or by the density of
the
silver
deposit with It
development.
is
and
short exposure
only necessary to
make
the
lengths of the ordinates (Fraunhofer lines) proportional to
the degree of darkening, and then
The
connect the abscissae by a curve as before.
curve then shows at a glance the distribution of
photochemical
spectrum
We
efficiency
in
every part
for the particular salt
are now,
I
upon the
The
in
spectrum
action of the pure spectrum
vehicles has
investigators, especially
Abney
work
silver haloids in various conditions
in different
Herschel,
employed.
venture to think, in a position
to follow the results of recent
photography.
of the
been studied by
by
J.
W.
and
many
Draper, Hunt,
and Becquerel, and most recently by with
improved
appliances,
and
with
greater care in eliminating the effects of impurities
than has hitherto been bestowed upon this
branch of work.
I
shall of course
be unable to
THE CHEMISTRY OF PHOTOGRAPHY.
254
do more than give you a general notion of the
The
results obtained. is
question to be asked
first
whether the different haloids have the same
maxima
of sensitiveness, and this can be answered
by experiment
way by
in
a
somewhat rough and ready
allowing our spectrum to
fall
on three
of paper coated with the respective
slips
haloids
and, after a sufficient exposure, developing in the
usual
way
[E].
chloride the
or
a
trum blue, trifle
little
;
The
shows that with the
result
maximum beyond the
is
limit of the visible spec-
with the bromide the
maximum
and with the iodide also
more towards the
notice also that the
about
in the violet, just
in the
but a
in the blue,
violet
You
end.
bromide spectrum
than either of the others
is
that
it
is
will
longer
extends more
towards the red, a fact of which we shall see the practical significance hereafter.
The experiment shown
is
necessarily a
hasty
one, and gives only a crude idea of the
action of the spectrum
In
upon the
more exact work the
local
different haloids.
greatest
precautions
have to be taken to insure trustworthy
results
PHOTOGRAPHED SPECTRA. the effect due to
with the
haloid,
every substance
whether as
stituent of the film, or as
an
255
associated
con-
essential
an accidental impurity,
must be studied individually before we
arrive
the true photographic spectrum of the haloid. is^
at It
no doubt the neglect of these precautions which
has led former workers to give different positions
maxima
the
to
The
haloid.
especially
felt
of decomposition
action
of
the
same
makes
itself
for
impurities
with prolonged exposure, so that
the spectrum printed up to the stage of visibility
never so satisfactory as that formed by a short
is
exposure and subsequent development. result of all the
up
recent experiments
in the following
M
L
diagram
is
final
summed
:
D
II
The
C
B A
IT.
M. FIG. I.
Chloride
6.
;
II.
SPECTRUM PHOTOGRAPHED ON THE SILVER HALOIDS. Bromide
;
III. Iodide.
The
dotted curves show the extension
towards the red by longer exposure.
THE CHEMISTRY OF PHOTOGRAPHY.
256
The
chief point of interest in connection with
these
curves
is
that
What
the silver haloid molecule.
we
molecule
We
molecule.
cannot
of these curves
pure
haloids
same
position.
itself,
;
and
maxima
The same
inherent in
maximum
are
of
are
sensitizer,
;
any
are observed,
by development
;
neither
provided
does
the
these
do
by
the state of
vehicle
not
the
obtained,
molecular aggregation of the haloid makes difference
that
in
always
curves
when the necessary precautions direct printing or
resides
careful experiments with the
by
the
one par-
in
The cause
is
shift the
property
curves show
most susceptible
is
ticular region of the spectrum.
the
that
The
shall learn subsequently.
that each haloid
in
physical
they indicate a fundamental property of
reality
is
a
they represent
nor
form
no the
actual
chemical compounds with each other or with the silver
haloid.
spectrum or
may
The
length of the photographed
be increased by longer exposure
we may encroach more red, or we may even so
by other methods
and more
into
the
modify the haloid as to get a new
maximum
PHOTOGRAPHED SPECTRA.
257
the less refrangible region, but the position of
in
maximum
the
blue
the
in
or
violet
not
is
thereby affected.
we
Interpreting these results practically
has the advantage for light which
silver chloride
and
rich in violet
is
see that
ultra-violet rays, while the
bromide and iodide have the advantage It
rays.
is
be
not to
photographed
understood that
these
any measure of
us
give
spectra
for blue
absolute sensitiveness, because, as you are
from
aware also
influenced
is
But when white
conditions.
or the rays from a coloured object
sensitive
which
is
plate,
acted
spectral colours
way
this
lectures,
by many other
light
a
former
is
it
fall
upon by the greatest range of must have the advantage
of sensitiveness.
You
will
sums up on the surface of the emitted
A 1
by the
haloid which
on
evident that that haloid
in the
understand this
you consider that the image thrown by a
if
now
object is
whose
affected
lens
film all the rays
image
by the
forms. 1
it
violet, blue,
Excepting the small percentage absorbed by the material of
the lens.
S
THE CHEMISTRY OF PHOTOGRAPHY.
258
green,
and yellow rays during the same exposure
which
in the case of
another haloid would allow
only the violet rays to tages in the
way
that with the
must
act,
You have
of sensitiveness.
same exposure
advan-
offer
silver
bromide gives
a longer spectrum than the other haloids
means
that
green,
yellow,
and
iodide, arid there is
one of the
make
haloid
this
is
there
present
is
is
a
so
or
property
sensitive
highly
in
is
the action
mixtures of the haloids.
an excess of some good sensitizer
capable of rapidly absorbing the liber-
maximum due
is
impressed
resultant
condition
is
due to the compounding of the
not
efficient sensitizer
observed.
to each spec-
the photographed spectrum
But
spectra of the separate haloids.
is
for
combine to
point to be considered
ated halogens, the
trum
this
that
processes.
of the spectrum upon If
chloride
causes which
many
;
sensitive
the
no doubt that
modern photographic
The next
than
red
bromide
silver
more
is
seen
fulfilled,
i.e.,
if
if
there
the above is
not
an
present, a very different effect
This
effect,
whatever
may
be
its
SPECTRA ON MIXED HALOIDS. true explanation,
we
who
discovery to Capt. Abney,
its
has worked out the essential conditions by
almost laborious nothing more
do
a very remarkable one, and
is
are indebted for
259
series
of experiments.
now than
a
give
summary of the conclusions of this The general nature of these results
I
can
very brief 1
investigator. will
be best
seen from the following curves, 2 selected as types
M
B A
L
T.
E.
nr.
w. FIG.
CONCURRENT REVERSALS
7.
from
a
large
illustration
Let 1
me
IN
MIXTURES OF SILVER HALOIDS.
number published
by Abney
in
of his work. first
explain
the
meaning of each
See chap. xxxv. of his Treatise on Photography, 5th
ed. p.
277
;
also Proc. Roy. Soc. vol. xxxiii. p. 164. 2
I
curves
am
indebted to Capt.
shown
in this
Abney
and other
for permission to
reproduce the
figures.
S 2
THE CHEMISTRY OF PHOTOGRAPHY.
260.
ciple
which they
reveal.
The
been selected so as to be
two
Thus
pairs.
In
I.
I.
and
II.
of bromide
upon mixtures lodion.
the
attempting to interpret
before
curve
prin-
four spectra have
comparable
fairly
represent the action
and iodide
in
a wet plate sensitized with silver
an acid or alkaline developer.
In
II.
the con-
were precisely the same, excepting that
ditions
the excess of silver nitrate was washed out. III. there
being developed In IV. the
no other
after a short
as
in
gelatine,
and the image
Now
before.
image
exposure as before.
sensitizer being present,
developed
the
silver nitrate, the
same haloids were used
compare the
:
The only in
In
was a mixture of iodide and chloride
on paper sensitized with
results
col-
was used, and the image developed by
nitrate
was
in
difference
former
there
between is
a
I.
and
II. is
sensitizer
present, while in the latter there
is
that
(AgNO 3)
nothing but
a mixture of bromide and iodide with practically
no
sensitizer.
have
You
see that in curve
been expected,
we have
the
I.,
as might
superposed
SPECTRA ON MIXED HALOIDS. spectra of
common maximum is
and
bromide
the
a totally different state of
G
near
there are
now two maxima,
H, and another
and
compounded
when
the
such
a
the
in
sensitizer
comparatively
feeble
(rather
Reduced
simply mean that
mixture of haloids green,
and
between
G is
and iodide curves for
gelatine
sensitizer
maximum
;
is
its
we have
this case
G, a
that
maximum
in
than
in
nearer the blue
and another minor
near H.
common
a minor one near
absent
is
may be neglected in before a minimum about
II.),
there
present, the curve
is
of the chloride
the blue-green
the
blue-green
action as
II.
difference exists between III.
When AgNO 3
and IV.
in
has become a minimum, and
The same
F.
But
affairs
maximum
with their
iodide
about G.
261
in
the violet,
to practical terms these facts in the is
absence of sensitizers a
more
sensitive to the blue-
less sensitive to the violet rays
of the
spectrum than either haloid separately.
We may
have next to consider how these
be interpreted.
The
results
case of a mixture of
haloids with excess of sensitizer
is
quite normal,
262
THE CHEMISTRY OF PHOTOGRAPHY.
and requires
no
special
markable destruction
and the
of
green when the sensitizer
about
G
there
first
about
G
into the blue-
absent, are the chief
is
sight appear to be that
a reversing process going on,
is
owing to the rehalogenization of the
sensitizer,
accordance with the principles discussed in the
in
This explanation
last lecture.
by Abney, is
re-
The most obvious ex-
comment.
planation would at
the
;
sensitiveness
maximum
shifting of the
facts requiring
explanation
for the
is,
however, rejected
very good reason that the effect
not analogous to ordinary solarisation, because
the
same
result
exposure.
is
obtained even with a very short
But although ordinary reversal
missible under these circumstances,
probable that
we have
phenomenon due
to
to the
is
it
is
not im-
do with an analogous
same chemical
cause.
In order not to complicate the argument
be well to
restrict attention to
only, say the bromide
and
greatest
is
about
The
iodide.
G
;
it
will
one pair of haloids
the spectrum where the greatest position goes on
inad-
region of
amount of decom-
it
amount of bromine and
is
here that the
iodine would be
CONCURRENT RE VERSAL. If the
liberated in a given time.
263
removal of the
halogens keeps pace with their liberation, as
is
the case in the presence of a sensitizer, the largest
amount of reduction product
we have
region
is
maximum
the
development as appears
in
formed
of intensity on
curve
I.
halogens are not speedily removed
But
if
is
more or
less
the
no active
if
present, their rapid accumulation
sensitizer
rays
in this
must
undo the work done by the blue
not only because of the actual quantity of
;
these halogens as
compared with the amount of
reduction product, but also because of the fact that bromine and iodine
ously would iodine,
form
a
when
liberated simultane-
compound, a
bromide of
which would probably be more active as a
rehalogenizer than halogen alone.
Chemists hava
long been familiar with the fact that a mixture of halogens
is
often
more
reactions than the halogens
So
far
image
to is
it
will
in
chemical
by themselves.
then the explanation
forward, and similar
effective
is
perfectly straight-
be seen that the process
that which
occurs
when
is
the latent
destroyed by a halogen, only the latter
-
THE CHEMISTRY OF PHOTOGRAPHY.
264
supplied (and probably in a more active form)
is
by
the haloid in the film itself instead of from
The
an external source.
effect is thus
analogous
to ordinary reversal with the part played
halogenized sensitizer
The element
out.
left
by the of
time does not come in because the rehalogenization goes on with the action of light ab tion of sensitiveness about
what
I
The
will
venture to
initio
G may
the reduc-
:
be attributed to
call concurrent reversal.
increase of sensitiveness in the
attributed
by Abney
green
to the formation of a
is
new
molecule, a bromo-iodide of silver of the formula
AgBr,AgI, or
Ag
2
This compound
BrI.
is
sup-
posed to be formed by the action of the bromine liberated from the latter
bromide upon the
being almost insensitive in this part of the
spectrum, while the bromide colour, as will be seen
is
acted upon by this
by comparing curves
III. of Fig. 6.
The bromo-iodide
believed to be
more
in
iodide, the
II.
thus formed
sensitive for the green,
support of this view
it
and
and
has been found that
a surface of washed silver bromide
is
is
if
darkened by
exposure to light and then brushed over with a
DO UBLE
SIL VER HALOIDS.
solution of iodine, a
compound
265
obtained which
is
towards the spectrum in precisely the
behaves
same way
The
as the mixture.
from these
conclusions drawn
but chemists
facts are perfectly sound,
are not very willing to admit the existence of
molecules without adequate proof.
you therefore that there
I
new
remind
will
a rare bromo-iodide of
is
occur as a native mineral in Chili,
silver said to
and there are a whole
series of
chloro-bromides
containing various proportions of metal, chlorine,
and bromine, of which the Chilian mineral em-
Ag3 BrCl 2
bolite,
,
is
But the most conclusive Abney's
light,
to
the
Under Fig.
7,
spectrum
furnished
of
surfaces
by
silver
iodine,
the
and then exposed
presence
of
sensitizers.
these circumstances curves similar to IV., are
illustration is
by
in
is
known.
best
darkened by exposure to
chloride,
rehalogenized
proof
with
experiments
bromide or
the
perhaps
is
obtained
[F].
The
point
of
this
that the sensitiveness to blue-green
shown even
in the
presence of a sensitizer
;
if
the silver haloids were present as a mere mixture,
you know that under
these
circumstances
we
266
THE CHEMISTRY OF PHOTOGRAPHY.
should have had a resultant spectrum as in curves I.
and
III.
With
respect to the chemistry of this last exis
it
periment
difficult to
which are not more or
offer
any suggestions
less speculative,
owing to
our ignorance of the true composition of the reduction product.
But
be useful to consider
may
it
what might happen on the supposition that product the
an oxyhaloid.
is
formula
sub-haloid
old
It is
this
pretty certain that will
have
to
be
abandoned, and the sooner we familiarize ourselves with other possible ways of regarding these actions, the better will
Thus,
we suppose
if
by the action of oxybromide,
duct by iodine
in
be
upon ,
2
I
2
future progress.
compound formed
silver
bromide
is
the
the destruction of this pro-
alcoholic
represented by the equation
Ag4 OBr +
for
that the
light
Ag4 OBr 2
it
re-
solution
might be
:
+ C 2 H 6 O = 2Ag2 BrI + C 2 H 4 O + H 2 O
In the absence of alcohol the
meets a different
fate
it
may
oxygen of course escape in the free
REVERSAL IN SPECTRUM. state or
it
may form
of the iodine.
oxidized products with some
The bromo-iodide may
give as a
mixed oxyhaloid,
Ag4 OBrI.
product a
reduction
267
Such are the possible processes which may go on
when the spectrum bromide and
on a mixture of the
falls
iodide, the iodine
which rehalogenizes
the oxybromide being in this case supplied
decomposition of the
silver iodide
by the
by the
liberated
bromine.
From
the action of the spectrum upon the silver
haloids with short exposure,
is
it
only a natural
step to the action of the spectrum with prolonged
exposure
duce this
:
the exposure
if
reversal, in
answer
in the
long enough to pro-
what part of the spectrum does
phenomenon occur
shown
is
?
Two
of Abney's curves,
accompanying diagram
this question for silver
(p. 268), will
iodide
and
for
a
mixture of bromide and iodide. In No.
I.
silver nitrate
No.
II.
pure
silver
iodide was sensitized
and developed
after long
exposure
in
a mixture of three molecules of the iodide
and one molecule of the bromide was exposed the
by :
presence
of
excess
of
silver
nitrate
in
(wet
268
THE CHEMISTRY OF PHOTOGRAPHY.
collodion plate), and then developed or alkaline method.
the
that
fact
iodide
curve
Both these curves point
region
of reversal
of
decomposition
maximum
ordinary
The
the
by the acid
is
making
is
now
D
G
FIG.
ORDINARY REVERSAL
8.
Pure Agl
+ AgN0 3
;
II.
3 AgI
IN
;
the true
elevation on
From
was discussed
is
A
It is
.
evident
maximum reversed,
is
only
and the
the less refrangible side simply re-
presents a small product.
maximum
B
C
SPECTRUM.
nearer the green had been produced.
apparent
in
maximum
+ AgBr + AgN0 3
however, that this shifting of the
:
depression,
appear as though a new
it
ML
I.
a
G.
maximum
the position where the curve shows a
thus
near
particularly instructive
with short exposure, there
the
at
is
to
residue of unreversed reduction
the theory of solarisation
in the last lecture,
it is
these curves express results which
which
obvious that
might almost
PHO TO- OX1DA TION IN SPECTR UM. have been is
halogen
anticipated
most
269
where the evolution of
:
rapid, rehalogenization (reversal)
might be expected to occur the soonest.
It
be regarded as a general rule that when a haloid
may
silver
given a very prolonged exposure to the
is
in the
spectrum begins
in
reaches
a
that
presence of a sensitizer, reversal region
maximum
We may
now
where
the
decomposition
with a short exposure.
pass on to the consideration of
the action of the spectrum upon the silver haloids
presence of
the
in
other
substances, both
This subject for a short will
It
true
will
reversing
agents and
oxidizing and
reducing.
be best approached by returning
time to purely photochemical actions.
be remembered that
it
was stated at the
very beginning of our subject that light in some cases promotes oxidation (Lecture
are
now
property putting
in
of
you
I.,
p.
25).
We
a better position to deal with this light,
in
and
I
possession
will
commence
of some
by
well-known
facts.
Although
in
most instances of photochemical
reduction, the violet
and blue rays are the most
THE CHEMISTRY OF PHOTOGRAPHY.
270
it
effective,
oxidation are the
that
appears
accelerated
is
most
cases where
many
in
by
the
light
red
rays
Thus the photo-oxidation
active.
of lead compounds, of mercurous oxide, of ferrous
and manganous compounds, of
more rapidly
sulphides, proceeds in
the violet rays.
that
I
because
arsenites in the
laying
we know
of
down
many
a
red
rays
photo-reduction
must
fully
general
law,
of photo-
instances
oxidation by the more refrangible
the
red than
must not be understood
It
am now
the other hand,
and of
rays, and,
we
shall
may
be
made
to
of
the
silver
salts.
on
learn subsequently that
bring
about
But
we
prepare ourselves for the possibility
of photo-oxidation
;
we must
learn to look
upon
a photo-sensitive surface as the seat of chemical
changes
in
which both reduction and oxidation
be taking
may result
place
simultaneously,
the
same
thing
as
on.
nature
of
the
compound
This amounts that
saying
product of photo-decomposition the
final
being determined by the relative rates at
which the two processes go to
the
is
the
final
determined by
with
which
the
BLEACHING BY POTASSIUM IODIDE. photo-sensitive
substance
by the nature of
as
is
this last substance.
from these general notions we
some concrete
to consider
In
the
last
lecture
iodide
potassium
was shown.
to
light,
of potassium iodide.
the
of
result
atmospheric
periment
and then
silver
of
chloride
was darkened bleached by a
in
the
this
By
oxygen.
of this
repeating
spectrum we
the
bleaching
light [G].
action
as
explained
oxidation
reversing process
the
rehalogenizing action
was
which constituent of the
that
action
reversing
the haloid
The
of the soluble iodide
in
may
exposure when painted with a solution
further
the
Starting
next proceed
be remembered that a sheet
of paper coated with
by exposure
well
instances.
upon darkened
It will
as
associated,
271
is
shall
being
salt
by
the
ex-
find
out
the most active
The
shows
result
takes place
in
the
same region of the spectrum where the maximum of
decomposition
reversing agent. as
in
ordinary
chloride
occurs
The
in
the
absence
action cannot be the
solarisation,
has already lost
its
because
the
of a
same silver
removable chlorine
THE CHEMISTRY OF PHOTOGRAPHY.
272
by preliminary exposure
iodide
the potassium
:
indeed be looked upon as playing the part
may
of the halogenized sensitizer, but the co-operation of
oxygen
The
experiment. the
condition
of
conditions
of
necessary
under
action
bleaching
of
a
is
result
the
a
is
good
from which we
principle
compound
photo-sensitive
iodide, the photographic surface
of
product
potassium
which
chloride.
silver
iodide
undergo
strongest at the
;
It
of
out
:
the
potassium
the reduction that
happens
those
most
oxidation
blue and violet rays is
one
is
is
the
illustration
set
here
is
its
compounds
rapidly in
the
hence the bleaching action
most refrangible end of the
spectrum. Investigations in the direction indicated last
by the
experiment have been made by Abney with
glass
plates
coated
in different vehicles.
with
The
the
plate
silver is
first
haloids
given
a
preliminary exposure, then immersed in a glass cell
containing the solution or gas to be tested,
and exposed developed.
to the action of the
The
spectrum and
results obtained are of
extreme
REVERSAL IN SOLUTIONS. and some of the curves are shown
interest
diagram on that
273
curve above
a
the
line
a curve below
while
action,
must be borne
It
p. 274.
normal
line
signifies
reversal, the local intensity of the reversal
indicated as before
mind
in
indicates
the
in the
being
by the height of the curve
at
different points. It is
by no means easy
in the present state of
knowledge to see the precise meaning of these
and we must be
curves,
satisfied
if
we can
get
but a glimpse into the photochemical processes
which they
reveal.
No.
I.
be called normal reversal
bromide
a
plate given
in
an ordinary gelatino-
prolonged
exposure
the spectrum, and about this there
You
mystery.
know
that
sensitive as far as the red if
enough
G
;
spectrum curve No.
gradually continues
it
I.
act
not
to
much
bromide
is
only gets exposure its
towards to
is
silver
the curve which has
creeps
what may
represents
maximum
the
(Fig.
red 6,
as
II.).
near the
This
simply shows therefore that while
halogenization of the sensitizer (gelatine)
on very rapidly
at the blue end,
it
is
is
going
going on
T
274
THE CHEMISTRY OF PHOTOGRAPHY.
R
G
D
A.
A?Br
in gelatine over-exposure.
IT.
AgBr in in
It.
W*
KBr
:
collodion
solution.
AgBr in gelatine in K^CraO? solution.
AgBr in gelatine in KaMngOg solution.
.
Agl in
in collodion solution.
KI
Agl in collodion in KgCrgC^ solution.
W.
Agl in
in collodion solu-
KgMn-jOg
tion.
in collodion in mineral acids.
\TJf* Agl
,
FIG.
9.
REVERSALS IN SPECTRUM IN PRESENCE OF REVERSING AGENTS.
JNTERPRETA TION OF CUR VES. more slowly the
at the red end, so that
blue end
constitute
has
what
received
I will call
red end has only received
by
27 5
the time
enough bromine
to
a reversing charge, the
enough to produce a
normal impression on development.
Such curves as
maxima,
are
most
the
satisfactorily, but
and VIII., which show two
II.
it
is
to
difficult
explain
worth while to make an
attempt to unravel their meaning,
if
only to get
suggestions on which to base further experiments.
The
first
of these
collodio-bromide to diffuse white
plate light,
per cent, solution of
exposing to
was a
obtained by giving
a
exposure
preliminary
then immersing in a five
potassium bromide
(acidified),
the spectrum and developing.
No.
VIII. represents the action of the spectrum upon a collodio iodide plate (after preliminary exposure)
when immersed
in
a
mineral acid.
It
added that collodio-iodide when immersed tion of potassium
similar to is
at b
into
y
No.
in
a solu-
bromide gives a curve somewhat
II.,
only the
and the second
the red.
may be
minimum
maximum
is
The curve showing
of reversal
shifted
more
the action of
T
2
THE CHEMISTRY OF PHOTOGRAPHY.
276
the spectrum on a silver bromide film in mineral acids
similar to
is
reversal
least
G
between
between
is
and
No. VIII., but the region of b
D
and
b.
In attempting to understand these is
bear
to
essential
We
results
it
mind the complexity of
in
under which the experiments are
the conditions
made.
of
instead
with a film which has had a
start
preliminary exposure and therefore containing a
mixture of unaltered haloid and reduction product, together
with
This
immersed
is
the
in
spectrum allowed to act upon are
favourable
haloid
is
to
sensitizes
halogenized
partially
reversal
and
solution
The
it.
because
conditions the
already partially dehalogenized. the
therefore
falls
spectrum
this
upon
the
silver
When surface,
the
rays which are most active in decomposing
the
substance
produce the
dissolved
maximum
the blue -end, in curves
due to
a
similar
when the spectrum of
darkened
silver
the
reversal II.,
action is
in
;
solution
the
will
maxima
at
V. and VIII., are thus to
that which occurs
allowed to
chloride
fall
on a sheet
paper coated with
INTERPRETATION OF CURVES.
These blue end maxima are
potassium iodide.
normal action reversed, the
fact the curves of
in
dotted
above
curves
showing the
277
the line
in
II.
of the ordinary
positions
and
V.
maxima
of decomposition.
The more
end of the spectrum are
reversals at the red
There
deal with.
difficult to
is
no doubt that
these represent the chemical destruction of the re-
duction product
most favourable to
tions are fact
oxidation, since oxidizing solu-
by
their production.
In
has been found that in reducing solutions,
it
such as potassium
no
gallol,
nitrite,
sodium
sulphite, or pyro-
reversal at all takes place.
Reversals in
potassium dichromate and potassium permanganate are
shown
in
curves
collodio-iodide
very that
way,
similar all
plate to
It
must be
understood in
the same
by preliminary exposure of the
then immersion to the spectrum.
reversal
VII.
is
to
in
the
The
less
and
solution
general effect
enormously
by the
A
hydroxyl gives a curve
these curves are produced
viz.
agents
in
and VII.
IV., VI.,
III.,
increase
refrangible
plate,
exposure
of oxidizing the
rays.
rate
of
Thus
in
THE CHEMISTRY OF PHOTOGRAPHY.
278
and
IV.
VII.
mixed one
it
the action
end and reversed that
seen that
is
normal
is
the red
at
the
result
a
the violet
at
This means
end.
of the
the latter region the destruction
in
is
reduction product has been going on to a great
extent by photo-oxidation, while
end
was
haloid
the
reduction
violet
undergoing
photo-
other words, reduction and oxidation
in
:
still
the
at
have been going on simultaneously at the two ends
of
the
spectrum.
Potassium
dichromate
causes reversal only at the red end as seen in III.
and VI.
probable that the specific absorp-
It is
something to do with
tion of the salt has
of
limitation
and
violet
appears
action,
end
blue
from
with
IV.
permanganate
one
other
given
and VI. exerts
end
end.
with
dichromate
the
absorption
and and
thus
action
i.e.
Potassium
VII.
violet
The dichromate its
This
spectrum.
of
the
off
by permanganate,
and the orange
the permanganate in
cuts
it
the
strong
but transmits the
green, at
of
a comparison
curves with those III.
because
this
in
blue red
at
agrees
upon
the
the rays
the
with less
ACTION OF SPECIFIC ABSORBENTS. refrangible
more
the
but acts as a
rays,
refrangible
rays
we have a
distinct
former this
in
image
we
reason
this
get no action in the blue with the
while
towards
screen
for
:
279
salt,
region
with the permanganate [H].
Now
although the
the violet and in
blue,
absence of either
the case of dichromate
light
of
the explanation there
offered,
or
direct is
action
all
in
reversed,
intelligible
in
which has just
the
been
an apparent mystery about the
is
proceedings at this end of the spectrum when
we have
do
to
with
that
permanganate
potassium
which requires clearing up.
allude to the fact
I
the violet and blue rays which are trans-
mitted by this solution produce or normal impression
which produces appears that
all
these
the
with
the
same
II.),
mineral acids (No. is
possible
direct
same exposure This
more remarkable when we consider
when
rays
through colourless solutions,
It
a
distinct reversal in the red.
very
bromide (No.
only
transmitted
such as potassium
potassium iodide (No. V.) and
VI II.),
that
the
cause strong reversal rays
in
question
are
THE CHEMISTRY OF PHOTOGRAPHY.
280
absorbed to some
extent
the permanganate
and
But
thus deadened. is
by
do not
I
through
passing
chemical
their
think
activity
that
this
the true explanation of the phenomenon.
seems more
we have
likely that
It
here a case of
retarded action in the violet and blue owing to the presence of the oxidizing
amply proved
in
It
salt.
has been
former lectures that substances
which tend to prevent the liberation of halogen retard the photo-decomposition of the silver haloids.
The to
action of the permanganate would thus
retard
be
the formation of reduction product in
that very region
where
the
in
absence of this
salt the
photo-decomposition would proceed most
briskly,
while at the red
end
there
would
be
going on photo-oxidation of the reduction product already
formed
The
subsequently. the time
a
final result
normal
distinct
formed by the reversed
by preliminary
violet
would be that by image
and blue
rays,
had a
been strong
image would be produced by the red
rays (Curves IV. and VII.). this
and
exposure
explanation
I
will
In accordance with
remind
you
that
an
REVERSAL IN MINERAL ACIDS. substance
oxidizing perfectly
VII.
to
result as
end
must
look
photo-oxidation
the permanganate
retarding and
normal
solution
is
curve
similar
very
the
upon
at the violet
due to retarded reduction
and
that
a
we
also
which
hydroxyl,
gives
colourless,
Here
like
281
red
at
the
is
very
end.
If
both
dilute,
oxidizing action are so enfeebled reversal
shown by the
as
occurs,
dotted curve in VII.
We
might thus go on
many more
such
curves
understand in
how
and
something
time to
these results
a general way.
VIII.) produced
almost tempts
this
these
enable
may
you to
be dealt with
The remarkable curve
by the
me
learn
But you have probably
from each one of them. seen sufficient by
and
discussing
action
(No.
of mineral acids
to digress further, but
I
will
content myself by pointing out that these acids, not being oxidizing agents (except nitric acid),
do not exert that retarding action
and
blue,
and
this
two maxima of
The
may
explain
reversal
so
in
the violet
why we
get the
strongly developed.
strong reversing action of potassium bromide
THE CHEMISTRY OF PHOTOGRAPHY.
282
shown
curve
in
must
salt
this
emulsion of
II.
washed
be
to
order
in
excess of
all
out
of
a
gelatine
the
insure
sensitiveness
greatest
why
explains
condition
Lecture
(see
IV.,
p.
123).
With regard in
to the chemical actions concerned
these reversals there
that
action
is
distinction
great
and
white light
of
spectrum
a
as
a
important to
is
it
the
some of which tend
regarded as the algebraical
of
the
White
light
undo the work of
to
we have an end
others
the
number of opera-
gives us the final result of a tions
between
action
agent.
reversing
remember
which
result
sum
may
be
of all the chemical
In the spectrum these effects
actions going on.
are differentiated and each set of rays produces its
own
reduction
particular
taking
complicated the
same
exert
place
in
by- concurrent place.
Thus
in
such
as
blue,
action
not at
the violet and
reducing
region
photois
photo-oxidation
and
their
the
that
one
permanganate
potassium transmit
so
action,
solutions
hydroxyl, these
which
rays
unchecked
can
except
PHOTO-REACTION OF REVERSING AGENTS.
action of the oxidizing substances
by the retarding upon the
why
This
silver haloid.
we
in these solutions
is
also another reason
get no normal reversal
the more refrangible end.
at
283
In the
red
rays
the photo-oxidation proceeds without check from
concurrent reduction, and thus gives strong
shown
reversal
in
the curves.
rise to
the
The
de-
struction of the reduction product in the spectrum is
thus
process that
simpler
in
white
phenomenon than
From
light.
would
immersed completely appear
such
play
reversals
that
in
made upon
the solutions,
in
oxygen
atmospheric
an
same
the
the circumstances
have been
these experiments
plates
not
a
important
the spectrum, even
part in
it
does these
in
the case of
reversing substances like the alkaline haloids or the haloid hydracids which are not oxidizing agents
under ordinary circumstances.
.
We
must
in fact
admit the possibility of direct interaction between the reduction product and these reversing agents
under the influence of particular the oxyhaloid formula
rays.
Adopting
we may expect such
actions as those typified
by the equations
:
re-
THE CHEMISTRY OF PHOTOGRAPHY.
Ag4 OBr + 2HBr - 4AgBr +H O 2
2
Ag4 OI + 2KI + H =4AgI + 2KOH Ag4 OBr + 2KI + H O = 2AgBr + 2 Agl + 2KOH 2
2
2
In the
by
such
2
as
salts
manganates, product
of direct oxidation by ozone or
case
the
may
and
dichromates
the
of
destruction
the
be due to indirect rehalogenization
by the oxidation of the halogenized as
explained
the
in
last
lecture,
or
sensitizer it
may
represented as a direct action of oxidation
2
per-
reduction
be
:
Ag4 OBr2 + 2O 3 = 4Ag2 O + 2Br2 + 2O 2 (first stage). 2Ag2 O + 2Br = 4 AgBr + O 2 (second stage). 2
The silver
nature of haloid
termine
the
the oxyhaloid.
is
the substance associated
particular
must
mode
with which the evidently
of destruction
de-
of
APPENDIX TO LECTURE
A
(p.
Shown by
242).
VII.
method of
the usual
placing a card painted with sulphate of quinine in the violet and ultra-violet region of the spectrum
a quartz prism is not available flint-glass must be used in order to get of the electric light. the best
B
If
effect.
A sheet
of paper coated with silver chloride and sensitized with silver nitrate is placed in the spectrum of the electric light as described in (p. 243),
the text.
During exposure the limits of the different
colours of the spectrum are marked out by pencil lines just below the spectrum seen on the paper. When the exposure has been sufficiently long to discoloration, the paper is withthen seen at once by the pencilled lines which region of the spectrum has produced
produce drawn.
visible
It is
the greatest
C
(p.
effect.
248).
The
solutions
matters are placed in sides
flat
of
the
glass cells
and interposed between the
colouring
with parallel
slit in
the lantern
THE CHEMISTRY OF PHOTOGRAPHY.
286
The aniline blue is the nozzle and the prism. " soluble blue of commerce dissolved in water and
"
acidified with a few drops of dilute sulphuric acid.
Instead of
"
malachite green," or almost any of the coal-tar greens can be used, as they all transmit a band in the red. The exact iodine green,
strengths of the solutions must be previously found trial.
by
D
The absorption-spectra of various (p. 250). coloured glasses were thrown on the screen by interposing the media between the slit and the prism in the usual way.
E
The papers
are
prepared in the ordinary way, care being taken to remove excess of silver nitrate by a final immersion in a solution (p.
254).
of the corresponding alkaline haloid. Three long and narrow strips are cut, washed with water till free
from soluble
solution of
salts,
sodium
strips are fastened
and then
sensitized with a
The
nitrite or sulphite.
on a board and exposed
three
for
one
or two minutes, the total width and length of the sensitive
papers being sufficient completely by the spectrum.
to
be
The
covered
strips
are
washed and developed by ferrous oxalate. The distribution of colour is shown (as in Experiment B.)
by
pencil lines
drawn beneath the spectrum during
exposure.
F
(p. 265).
Paper coated with
silver
bromide
is
APPENDIX TO LECTURE
VII.
287
exposed to the electric light till darkened, then brushed over with a weak alcoholic solution of
washed with water, sensitized by sodium nitrite, exposed to the spectrum for one or two minutes, then washed and developed by ferrous iodine,
The spectrum
oxalate.
as before
;
a
maximum
colours are pencilled out appears in the green on
development.
G
(p.
271).
Paper coated with
darkened by exposure to white over with a
silver chloride is
light,
then brushed
of potassium iodide and to the action of the spectrum (See Experiexposed ment I., Lecture VI., p. 233). The experiment can solution
be repeated with
silver
bromide, giving a short
exposure and developing with ferrous oxalate.
H of K in
279).
The
Cr 2 O 7 and
K
(p. 2
the usual way.
absorption-spectra of solutions Mn.2 O 8 are shown on the screen 2
LECTURE
VIII.
Photochemical Decomposition and Absorption of Light. Draper's Law. Effect of Mole-
Relationship
between
cular Aggregation
upon Sensitiveness of
Silver Haloids.
Photography of Red and Infra-Red Rays. Physical Analogy between Emission Spectra and Photographed Spectra. Effects
Photochemical Action probably intramolecular. Orthoof Dyes on Local Sensitiveness.
chromatic Photography.
Photochromy.
IN the present lecture we must tain
set out
fundamental physical conceptions.
compound absorbs some
If
from
cer-
a chemical
of the rays of the spectrum,
the energy of the ethereal undulations producing
those rays must be used up in doing
some kind of
work upon or within the molecules of the compound.
There
may
electricity, or there
be a production of heat or of
may be
chemical decomposition,
an equivalent quantity of the absorbed
light dis-
DECOMPOSITION AND ABSORPTION. These statements
appearing as such. evident to those
who
be
self-
are familiar with the teachings
modern physics
of
will
289
based
they are
upon the
universally received doctrine of the conservation of
At
energy.
the present
moment
chemical decomposition that
with photo-
is
it
we
alone con-
are
cerned.
The
inherent property of the molecule of a
silver haloid
which confers upon
to special rays
is its
This
is
faculty
it
sensitiveness
its
power of absorbing those
rays.
no doubt ultimately dependent
upon the mechanical structure of the molecule, but
is
it
beyond
my
province to deal here with
The proof
these questions of molecular physics.
of this statement does not rest however upon such
a priori mechanical conceptions, but
experimental demonstration.
It
is
capable of
has been shown
by many experimenters that whenever a beam of light
passes through a sufficient thickness
solution or gas in
which photochemical change
induced, the emergent light faculty
of a
of producing
is
is
deprived of the
any change
quantity of the same solution or gas.
in
a
further
The U
special
2 9o
THE CHEMISTRY OF PHOTOGRAPHY.
undulations which are effective for the particular
substance
are
out of the beam, and the
sifted
residual rays are thus
which
is
wanting
in that constituent
capable of affecting the substance being
This has been proved
experimented with. of
case of solutions
ferric
and mercuric
the
in
salts in
the presence of reducing agents as well as for other
mixtures [A].
It
thus be taken as a general
may
law that photochemical decomposition implies the absorption of some particular constituent of the light,
and as
this
was
first
by the American
distinctly enunciated in
physicist
J.
W.
Draper,
well to associate the principle with
and
will
be
discoverer
to speak in future of Draper's law. directly demonstrate the truth of
Attempts to this
its
it
1841
law
in the
pounds as the
case of such photo-sensitive
silver haloids are frustrated
opacity of these
salts,
com-
by the
but there are other reasons
for believing that the
law applies
These reasons
think be easily intelligible
will
I
after our treatment of
the last lecture.
in
these cases.
spectrum photography
in
If thin films of the silver haloids
in suitable vehicles are
examined by transmitted
DRAPER'S LAW. light, it will
are
291
be found that the absorption spectra
complementary to the photographic
Let us understand the
The maximum
full significance
absorption, as
analysis of the transmitted
spectra.
of this
shown by the
fact.
spectral
light, coincides with the
maximum of photo-decomposition as revealed by the This
developer after exposure to the spectrum.
means
that the waves which are the
photographically
are
precisely
absorbed by the haloid
most
those
effective
which are
other words Draper's
in
law of the relationship between absorption and photochemical decomposition has a direct bearing
upon
photographic
This
processes.
not
is
merely inductive leap, but a conclusion which
must now attempt to
a I
justify in detail.
Perhaps the best proof of the existence of such a relationship between photographic sensitiveness
and absorption which
is
furnished
by the
change
optical
associated with the change in the state of
molecular haloids
is
aggregation
during
the
undergone by the
process
of
subject has already been touched lecture (p. 124)
ripening.
upon
in
and we may now resume
U
silver
This
a former its
2
con-
THE CHEMISTR Y OF PHOTOGRAPHY.
292
with
sideration
bromide
silver
unripened state
be remembered that
red
will
it
appears reddish by transmitted
imply
?
What
transmitted.
is
You
in its
it
but as the particles grow by ripening
light,
less
Commencing with
advantage.
will of course
less
and
does this change
be prepared with the
answer that the larger particles absorb more of the red.
But
if
absorption means photochemical de-
composition > as Draper's law leads us to expect, the ripened bromide should be red,
and
this
the spectrum.
is
just
A
what
large
is
more
sensitive to
found on photographing
number of most
carefully
made experiments have been conducted by Dr. Eder and they all confirm
this conclusion.
Here are three
of Eder's curves which will speak for themselves
I
If
G
F
D
C
J?
:
A I.
K J2T,
FlG.
10.
- Si'ECTKA PHOTOGRAPHED ON DIFFERENT FORMS OF SlLVER BROMIDE
OPTICAL EFFECT OF RIPENING. No.
represents the action
I.
bromide and No.
II.
upon the unripened
the action upon the ripened
both being emulsified
haloid,
293
in
The
gelatine.
dotted curves show the effect of short exposure
and the continuous curves the No.
exposure.
III.
shows the
of longer
result
effect of ripening
almost up to the point of decomposition.
These curves are highly instructive taken
in
connection with the other purely chemical con-
which have been dealt with
siderations lectures.
It
normal
the
will be seen
maximum
materially shifted
now why
see
the
for
position
bromide
the effect of ripening
to extend the sensitiveness
We
that the
is
is
of not
simply
more towards the
the ripened bromide
affected
former
in
red.
the more
is
by a wider range of
sensitive
:
colours
than when in the unripened
This
the optical justification of the statement
is
it is
which was made
in
the last lecture
spectral
condition.
(p.
258) re-
specting the superiority of the bromide for rapid
photography.
The ments
general result of these and similar experiis
to
show that the
sensitiveness
of the
THE CHEMISTRY OF PHOTOGRAPHY.
294
silver haloids for particular rays
ent
state
their
upon
This
state
mode
of formation
in
is
largely depend-
aggregation.
physical
turn
dependent
upon the
of the
haloid, the
nature of
its
the vehicle in which
of
is
it
suspended, the state of
is
dilution of the reacting solutions, &c. priate
now
appro-
I
cannot
the details of which
treatment,
stop to explain, silver chloride
being obtained in
of molecular
the
to
it
illustrating
been found
has
that the highly sensitive
ripened
form
much more
difficult
to
bromide collodion
is
than
in
Abney
special precautions however, in
which region
appears is
1
sensitive
of
emulsion
means
blue to
far
the spectrum.
1
obtain in
in
in
collodion
it
is
possible
and
light,
the
infra-red
This special form of
confessedly difficult to prepare
is
the
has succeeded
by transmitted rays
of
taking certain
producing a form of the bromide
which
its
By
gelatine.
and
ripened
As
unripened forms of the bromide. the influence of the vehicle,
capable of
is
states
different
corresponding
aggregation
By
obtain
to
Phil. Trans. Roy. Soc. 1880, p. 653
;
;
by
photographs
Ibid. 1886, Part II. p. 457.
RED-SENSITIVE EMULSION.
295
limit of
of the spectrum far beyond the lowest visibility.
The
coarse-particled bromide
in this
is
form susceptible even to waves of such low frangibility as those emitted
The
water.
action
of
by a
the
vessel of boiling
below
shown
is
:
D
FIG.
this
spectrum upon
and the two modifications of the chloride in the curves figured
C
B
A
ii. SPECTRA PHOTOGRAPHED ON DIFFERENT FORMS OF SILVER CHLORIDE (I. and II.) AND ON THE RED-SENSITIVE FORM OF SILVER BROMIDE (HI-)-
No.
I.
the
represents
ordinary form
of the
chloride in collodion, the film appearing red
transmitted
light.
No.
emulsified in gelatine
red
No.
re-
;
this
II.
is
the
same haloid
and absorbing more of the
form appears grey by transmitted
III. is
by
light.
the photographed spectrum on the red-
296
THE CHEMISTRY OF PHOTOGRAPHY. form of the bromide
sensitive
in
collodion pre-
laid
before you in
pared by Abney.
The
which have been
results
such importance that no excuse
this lecture are of
need be made
for
attempting to get a
insight into the inner
little
further
mechanism of the processes
of absorption and decomposition which have been
The
revealed.
general history of the progress of
knowledge teaches us that the greatest advances are always
made when one branch
croaches upon another.
I
of science en-
might devote a whole
course of lectures to the illustration of this principle.
Consider for example the application of
electricity to the
decomposition of chemical com-
pounds, resulting in the discovery of the compound nature of the alkalies and the isolation of the
metals the
potassium
application
terpretation
to the law of
of
and
sodium
;
or
take
the
properties
of gases leading
Avogadro and the complete
tionizing of the
again
of physical principles to the in-
fundamental
revolu-
conceptions
con-
cerning the nature of chemical atoms and molecules.
Coming
nearer to our present subject,
remember
PROPERTY OF SPECIFIC ABSORPTION.
297
the influence of the introduction of optical methods into chemical
investigation
resulting in
covery of spectrum analysis with at
Looking
consequences.
its
the dis-
far-reaching
these curves showing
the effects of a change in the state of aggregation
upon the
sensitiveness of the silver haloids,
it
is
impossible to avoid coming to the conclusion that
we may have
phenomenon a point of contact
in this
between chemistry and physics which only awaits further
development
order to lead
in
to
results
of lasting importance to both branches of science.
That
inherent
property
molecule which causes
it
to
of
part of the
result of the
The
silver
undergo a
amount of decomposition per particular
a
haloid
maximum
unit of time in a
spectrum
is
no doubt
a
mechanical structure of the molecule.
rays are absorbed because the
molecule or
some constituent of the molecule has a period of vibration which of vibration that
nothing
synchronous with the period
of the ether-wave corresponding to colour.
particular as
is
of
yet
molecules, and
I
the
We
know
internal
absolutely
mechanism
must caution you that
I
of
am
THE CHEMISTRY OF PHOTOGRAPHY.
298
here entering upon speculative ground.
It
would
be rash therefore to attempt to draw any close
known
between
analogy
phenomena
physical
which are capable of being explained mechani-
and that which occurs
cally,
The only comparison
under the influence of light.
which
it
absorption to the
venture
to
safe
is
of light
in
a solid particle
in
these cases
is
analogous
of an air-wave corresponding
absorption
music by a stretched string
to a definite note in
or a
tuning-fork capable of emitting the
note
when thrown
into
case because
its
But even far,
and
if
this
pressed
instance that the
affairs,
to fly
but
corresponds
It
may
it
absorbed
it
off. is
lead
sometimes asserted
is
a
impulses
whole,
the
at length sufficient to cause
constituents
this
[B]..
too closely
molecule to swing as
becoming
string in
analogy does not take us very
astray altogether.
of
sound
period of vibration
with that of the air-wave
same
The
vibration.
tuning-fork can take up the
or
the
that
is
upon
This also
may
cause
us for
the
amplitude
one of the
be the state
possible
that
the
ABSORP TION B Y HALOGENS. absorbed
molecule
the
upon one constituent of
act
impulses
The
only.
lead to the conclusion silver
the
haloids
action
of the blue rays
we must have
to
But we have that
halogen absorbent present or
a
the decomposition
does not take
The photo-decomposition may
place
at
all.
thus be in reality
function of the halogen
a mechanical
is
we know
not the case
is
case of the
the
that in
would
view
former
cause photochemical dissociation. learnt that this
299
atoms
in
contact with a second substance with which they
can combine.
This view appears
probable when
we
haloids and
other photo-decomposable halogen
all
rays,
i.e.
sensitive
for
the blue and
very colours which are most
the
strongly absorbed by
Any
the
halogens themselves [C].
attempt to present a physical picture of
what occurs
in
a
silver
haloid
molecule during
the process of ripening would take us into
the more
consider that both the silver
compounds are most violet
all
the
region
of speculation.
We
still
further
know
for
a fact that the particles grow in size during this process, so that
the
red-absorbing particle must
THE CHEMISTRY OF PHOTOGRAPHY.
300
consist of a larger
aggregate of molecules than
the blue-absorbing
particle.
in
size
(and consequently in mass)
vibrating period
reach of
physical
at
is
affects
An
the
analogy might
employed with
if
the
of the
beyond
present
inquiry.
perhaps be useful here
we
increase
of any one constituent
system of molecules
If
But how
caution.
take a ray of light consisting of waves
of some two or three vibrating periods only, such for
instance
as
the
emitted
light
hydrogen, and examine
its
by glowing
we
spectrum,
see only
certain bright lines in the positions corresponding
These bright
to their respective refrangibilities.
spectral lines are the optical
expressions of the
mechanical structure of the hydrogen molecule they
indicate
that
the
molecule
is
capable of
vibrating in certain periods and thus of emitting
The width
waves of particular lengths. lines
will
of course
depend upon the width of
the slice of light which prism,
ix.
researches
is
passed
upon the width of the
spectroscope.
of
Now
of the
it
has been
Pliicker
and
through the slit
shown Hittorf
of
the
by the and
of
ANALOGY WITH EMISSION SPECTRA. Frankland and diameter
of
and
Lockyer
the
slit
width of these hydrogen
lines
that,
the
unaltered,
the
others,
remaining
goes on increasing
as the pressure of the glowing gas in other
I
increased
is
a real analogy
and the spreading of the
this discovery
photographic spectrum of silver bromide as particles will
become
show
maximum
maximum by
;
the pressure increases.
as
cannot but think that there
between
is
words, the discontinuous spectrum tends
become continuous
to
301
A
larger.
the
that
glance at the curves
position
of
the
normal This
remains unaltered throughout. is
its
the analogue of the position occupied
a bright line in the spectrum of a glowing gas,
and the
effect of
particle
is
an increase
in the size of the haloid
analogous to the effect produced upon
the spectrum of the gas
by
increase of pressure.
In both cases the spectrum widens out in such a
way to
as to
make
the discontinuous spectrum tend
become continuous
:
in
other words, to
special vibrations corresponding to the
of luminosity in
the
the
maximum
emission spectrum
or
of
absorption in the photographic spectrum, pressure
THE CHEMISTRY OF PHOTOGRAPHY.
302
in the
one case and increase of
case, causes
longer
may
shorter
the other
in
of vibrations of
the addition
and
size
periods
than
both
which
those
be regarded as the normal vibrations of the
gas or of the haloid.
Such considerations to
the belief which has already been expressed,
that as
it
is
not the molecule of the silver haloid
a whole
which
The
is
on
go
growing
photochemical action
a
otherwise distinct
we
of
appearance
show that
of this
this
major
the
more
the
size
to
most
seat
maximum
or
not the case
such
with
with
The
the
of
Were
find
associated
is
still
compound.
intra-molecular.
new maximum.
a the
curves
maximum
takes place about G, but
sensitiveness
minor sensitiveness or,
that
a
of decomposition to
in
special
remains while the
should expect
increase
displacement
is
the
seems to point
conclusion
the
to
distinctly
of
maximum
fact that the
particles
responsible for the
sensitiveness
photographic
it
as these lend countenance
there
is
added
a
for the less refrangible rays,
correctly speaking, the feeble sensitive-
ABSORPTION INTRA-MOLECULAR. ness for the less refrangible rays a practically workable pitch size
the
of
this point
add
that,
haloid
silver
home by
order
exposure
the
to
increase
To
particles.
in
bring
may
I
G
photograph requires
has found that
that
necessary,
while
times
thirty-five
The spectrum
an
than
greater is
A
about
region
times
twenty-five
for G.
Abney
the
impress
infra-red
exposure
by the
even with the red-sensitive form of the
to
required
exalted to
is
a practical illustration
collodio-bromide emulsion, in
303
this case
in
the
was
that of bright sunlight at noon.
The
modern photographic the
sensitiveness
orange,
then, so far
present position
and
red
processes,
for
such
be
can
as concerns
that
is
as
colours
with silver salts obtain a plate which
bilities.
Till
this
is
can be prepared which the
same order of
intensity as
representation
till
equally refrangi-
a plate
sensitive to colours in
is
no photographic picture faithful
is
and low
done, or rather
yellow,
we cannot
increased,
sensitive to rays of both high
although
of
will
we
perceive them,
give an absolutely
coloured
objects
the
THE CHEMISTRY OF PHOTOGRAPHY.
304
and
blues
violets
will
still
give
a
stronger
These more
impression than the other colours.
down
refrangible colours can of course be toned
by causing the
medium, such as red
it
of the ideal
is
plate
modern
of
given greater effect by this
lowered
perfection
investigations,
without
shall
actual visual
loss
is
of
intensities
in
be orthochromatic.
its
of
a plate which
sensitiveness
the
the aim
record
colours
Such a
of
plate
the
an
would
has already been pointed out
ordinary processes the silver haloid
all
records
It
is
to have
of
The
consequence.
which
object in their correct values.
that in
less
obvious that the total sensitiveness
is
state
but although the
glass,
are
refrangible rays
means,
through an absorbing
light to pass
colour impressions in quite a different
order to that in which they are recorded on the
human graphy
retina: the object of orthochromatic photois to
bring visual intensity
intensity into
The made
who
first
in
and pliotographic
harmony.
step in this much-desired direction
1873 by Professor H.
W.
was
Vogel, of Berlin,
discovered that the silver haloids could be
made
SENSITIZING A CTION OF sensitive to yellow
D YES.
305
and greenish-yellow by tinting
the films (collodion) with certain coal-tar dyes such as corallin, aldehyde green, cosin, cyanin
and many
This discovery formed the starting-point
others.
of a series of investigations which have been carried
on to the present time by various experimenters. I
cannot stop to recount the different steps
in the
progress of this discovery, but must limit myself to
a brief statement of the general results which have
been arrived
at.
The main
fact,
that
new maxima
of chemical activity can be obtained in the less refrangible regions of the spectrum
by the addition
of dyes to the film, has been confirmed by the work
of Becquerel, Waterhouse, Abney, Carey Lea, Edcr
and is
C.
H. Bothamley.
Now that
gelatine emulsion
so generally used in photography, the practical
aspect assumed
by the problem
is
the rendering of
such films orthochromatic by the addition of able colouring matters.
Immense numbers
suit-
of dyes
have been tried under various conditions, especially
by Dr. Eder of Vienna. pulation which film
may
it is
The only
point of mani-
necessary to explain
is
that the
be dyed by adding a solution of the colour-
X
THE CHEMISTRY OF PHOTOGRAPHY.
306
ing matter to the emulsion plate
may be
dipped
itself,
in the coloured solution
when dyed withdrawn and
dried.
colouring matter employed
is
ance, since too
little
or the coated dry-
The amount
of
also a point of import-
much both
or too
and
act detri-
mentally with respect to special sensitizing action.
According to some recent experiments of Abney's is
it
not even necessary to dye the film, but the same
effects are
produced by coating the sensitive surface
with a varnish containing the colouring matter.
The importance sufficiently obvious
of this
new departure
The
first
bearing of the discovery, these dyes
The
of Eder and
Eder's curves
amley
in the
number
1888, vol.
ii.
(I. to
Journ.
curves (XI. to ference
the course of the
to discuss the chemical
the precise way in which
the photographic spectrum*
following series of curves selected from the
results
1
influence
is
in
thing that must be real-
we can proceed
ized before
be
from the general considerations
which have been submitted present lecture.
will
XIV.)
Abney 1
show how the
X.) are taken from a paper by C. H. Both-
Soc.
Chem. 2nd.
for 1887, p. 425.
Abney's
are selected from a series given in the
of the Journal of the
p. 58.
will
Camera Club, March
Coni6th,
CURVES SHOWING ACTION OF DYES.
307
colouring matters affect the less refrangible end of
the spectrum.
NML
H
FIG. I.
FED CBA
C
12.
Violets; II. Greens; III. Iodine green; IV. Cyanin ; V. Eosin ; VI. Ammoniacal rose Bengal ; VII. Coerulein ; VIII. (_hrysaniline ; IX. Eosin on
XT I. AgCl; X. Eosin + Cyanin XI. Erythrosin on Agl + AgNO3 XIV. Cyanin on AgCl. ErythrosinonAgBr XIII. Erythrosin on AgCl Where the haloid is not specified AgBr has been used. ;
;
;
With mind
respect to these curves
that they
;
it
must be borne
show nothing more than the
X
in
relative
2
THE CHEMISTRY OF PHOTOGRAPHY.
308
of the dyed film for the different
sensitiveness
regions of the spectrum.
of
the absolute
maximum
new is
often
acquired
They
sensitiveness in
the
less
tell
The
of the plate. refrangible O
the expense
at
us nothing
region O
of a general
diminution of sensitiveness at the more refrangible end, so that a longer exposure has to be given to
bring out the special sensitizing action of the dye
:
in
other words the total sensitiveness of the plate
is
lowered.
Then again
for the colouring matters
it
must be observed that
used and under the partic-
ular conditions of the experiments, the
of action
still
is
in the
more
maximum
refrangible
region.
This means that such dyed plates, although tively
more
rela-
sensitive to green, yellow, orange, or red
than they were before, are sensitiveness for violet
still
and
possessed of greater
blue, so that in photo-
graphing a coloured object on one of these plates it
would
and
still
violet
be necessary to tone down the blue
by interposing an absorbing medium,
such as yellow
glass.
chromatic plates screen
is
it
Even with the
best of ortho-
seems that some such yellow
necessary before a coloured object can be
ORTHOCHROMATIC PHOTOGRAPHY. photographed with
all
the colours represented in
Another point
their true gradations of brightness.
which an inspection of these curves brings out the
309
same dye produces
different silver haloids.
is
that
different effects with the
This
will
be seen on com-
paring V. and IX. showing the action of eosin on the
bromide and chloride respectively, and XI.
XII. and XIII. showing the action oferythrosin on the iodide, bromide, and chloride.
In
practical applications orthochromatic pho-
its
tography distinct
is
most
differences
likely to be serviceable
where
of colour have to be repro-
duced, such as in the copying of paintings. will
be readily understood
also that
an
It
ortho-
chromatic plate would be valuable in cases where
we have to employ light,
which
is
artificial light, like
relatively
poor
in the
gas or candle
more
refrangi-
ble rays, because in such a plate the sensitiveness for the less refrangible rays is exalted
of the dye.
by the action
In continuing the experiments in this
direction, Mr. C.
H. Bothamley, of the Yorkshire
College, Leeds, has succeeded in preparing plates
which arc more sensitive to yellow and orange than
THE CHEMISTRY OF PHOTOGRAPHY.
3 io
and violet, and which thus approach the
to blue
ideal
coincidence between visual and photographic inten-
The
sity.
numerous
result of this recent
work
is,
colouring matters tested,
that of the
ammoniacal
erythrosin appears to be the most effective sensitizer for
the yellow, and
orange.
1
It will
ammoniacal cyanin
for the
be instructive to inspect the accom-
panying curves taken from Mr. Bothamley's paper
and showing the sensitizers
N
effects of
some of the most
upon gelatino-bromide emulsion
M
L
active :
ff
.FIG. 13. I.
Gelatino-bromide (undyed) II. Ammoniacal Eosin III. Ammoniacal Erythrosin; IV. Ammoniacal R^se Bengal; V. Ammoniacal Cyanin. ;
1
A
;
number of photographs taken by Mr. Bothamley were proThese showed in a very striking manner the
jected on the screen. difference
between the pictures of coloured
objects, such as flowers,
coloured papers, &c., taken on ordinary plates, and on plates dyed with ammoniacal erythrosin, both with and without the intervention of a yellow glass screen.
THEORY OF ORTHOCHROMATIC ACTION. It
generally admitted
is
by
311
photo-
practical
graphers that the seeds sown by Vogel in 1873 are value likely to develop into results of the highest to
the
art.
But although the
of
utility
ortho-
chromatic photography has been proved in
must be confessed
it
ways,
that,
of the discovery
scientific aspect
is
so
far
concerned,
are at present only on the threshold of an
There
region.
are
many
many as the
we
unknown in
discrepancies
the
very facts themselves, and different workers are by
no means concordant
in
their
From
results.
a
chemical point of view the data require purification not only figuratively, but also
There
literally.
is
no doubt that most of the discrepancies have arisen from
the use
of
commercial
colouring matters instead
of
specimens
of the
the pure chemical
compounds, and the action of the dyes has thus been complicated
in
unknown ways.
For
this
reason the results are hardly ripe for discussion as yet,
and
I
cannot do
much more than
lay before you
the existing views respecting the principles at work. If
we sum up
the evidence at present available
j
the one general outcome which appears to be of
THE CHEMISTRY OF PHOTOGRAPHY.
312
most significance
the
is,
that there
is
a distinct
connection between the specific absorption of the
dye and in
its
In order to find out
sensitizing action.
which part of the spectrum the sensitizing action
will
be exerted,
it
is
only necessary to examine
the absorption-spectrum of the
dyed
film
itself
where the dark absorption-band of the colouring matter appears, there will be a new
maximum
on
exposure to the spectrum and development [D], It
must however be borne
good only special
because
for
It
a
colouring
tize for the region
in
shows
matter it
means
no
by
absorption-spectrum, that
that this holds
matters which act as
colouring
sensitizers.
mind
in
a
where absorption takes place
other words, absorption
instance absorbs
sensitize
definite
will necessarily sensi-
may
or
may
associated with special sensitizing action. for
follows
the yellow,
a film for this colour.
but
not be
Indigo
does
Then
:
not
there
is
another point which must not be overlooked in stating
the
connection between absorption and
sensitizing action,
between
the
and that
is
that the coincidence
absorption-band
and
the
region
ABSORPTION AND LOCAL SENSITIZING. sensitized
is
when we examine the
only true
absorption of the dyed film
itself, Le.
gelatino-bromide emulsion
when
cidence
is
said
313
of the coloured
The
dry.
by Vogel and Eder not
coin-
to hold
good when the spectrum developed on a dyed gelatino-bromide film
absorption-spectrum alcoholic
solution,
is
of or
compared with the true the
in
a
gelatine
plain
The
containing no silver haloid.
the dye with the silver haloid
aqueous or
in
dye
is
film
association said
of
by these
observers to cause a slight shifting of the absorption-band, towards the
maximum
in the
red,
so
developed image
less refrangible side of the
the second
that is
a
little
absorption -band shown
by the spectrum of the colouring matter 1 containing no silver haloid.
in vehicles
But here again
must caution you against receiving these ments as
final,
I
state-
because other workers have failed to
obtain this shifting of the 1
on the
maximum.
This displacement of the band of absorption (and chemical towards the red is believed to be in accordance with Kundt's
activity)
law, which asserts that the absorption-band of a colouring matter
displaced towards the red as the refractive
which the substance
is
dissolved increases.
power
of the
medium
is
in
THE CHEMISTRY OF PHOTOGRAPHY. No
theory of the action of sensitizing colouring
can be as yet
matters upon the silver haloids
regarded as conclusively established. to be
There seems
no connection between the chemical con-
stitution
of
the
sensitizing action
;
neither
is
and
matters
colouring
there
their
any connection
between their fluorescent properties or their power of anomalous dispersion and their action as special
Two
sensitizers.
current,
distinct classes of hypotheses are
one physical
and
the
other
chemical.
According to the older view the vibrations absorbed
by
the dye are transferred to the silver salt and thus
render the latter sensitive in the region of absorption.
Some
such
idea as this
appears to have
influenced the course of experimental early days
of the discovery,
work
and the
in the
colouring
matters were in accordance with this view spoken of as " optical sensitizers."
This physical theory
has however been modified, chiefly through the researches of
Eder,
who
has
clusively that the silver haloid
the
shown most conis
actually dyed
colouring matter, the silver salt
compound of the nature of a
by
forming a
lake with the dycstuff.
THE OR Y OF SENSITIZING A CTION. Whether
these
silver haloid
compounds of the
31 5
with
the colouring matter are truly chemical, or whether
they are
"
molecular,"
t. physical, need not concern
us now, but Eder's experiments clearly prove their existence.
Starting from this
named supposes that the
fact,
the authority just
vibrations are absorbed
the coloured compound, whatever the latter
by
may
be, the energy of the absorbed vibrations being
chiefly spent in doing the
decomposition.
The same
work of photochemical vibrations absorbed
by
the dye alone, in the absence of the silver haloid, are chiefly
converted
into
heat
and
do
but
little
chemical work.
Against these physical hypotheses there to be urged
on a priori grounds, but
it
will
is
much
be safer
to confine ourselves to the results of experiment.
According to Abney the the
a*ction is
purely chemical,
colouring matter undergoing
photochemical
decomposition (by oxidation or otherwise) in the region of absorption and giving rise to products
which act as reducing agents upon the
The
silver haloid.
fact that the best sensitizing colouring matters
are just those which are
known
to be
most
easily
3i6
THE CHEMISTRY OF PHOTOGRAPHY.
affected
by
such as the
light,
group) and cyanin,
is
chemical hypothesis.
strongly
me
Let
phthaleins (eosin in favour of
the
remind you of the
bleaching action of light upon a sheet of paper dyed
with eosin, shown
Now
in the first lecture
(Exp.N,
p. 34).
the chief difficulty which chemists will expe-
rience in accepting this explanation stuff should
is,
that the dye-
by photochemical decomposition give
products which exert a reducing action upon
rise to
the silver haloid.
But
this
difficulty arises
from
our ignorance of the nature of the products formed
under these conditions.
must be remembered
It
that the molecules of these colouring matters are
extremely complex, as ing empirical active
will
formulae
be seen from the followa
of
few of the
most
:
C 20 H 6 Br 4 O 5 Ko C H a Cl 4 T 4 O 5 K 3 C 20 H G T 4 O 5 K 2
Eosin
Rose Bengal Erythrosin
Cyanin (quinoline blue)
It is
.
.
C^H^NoT.
not to be wondered at that
among
the pro-
ducts of decomposition of compounds having such
highly 'Complicated molecules as these dyes, there
should
be
Thus an
ABNEY'S EXPERIMENTS.
317
substances of a reducing
character.
reducing agent, formic acid, has
active
already been stated (page 22) to be
among the
ducts of the oxidation of gelatine
dichromate under the influence of production
of a
pro-
by potassium that the
light, so
reducing agent by the photo-
oxidation of a highly complex molecule
is
not
without a parallel.
There are other considerations which tell in favour of the chemical hypothesis, such for instance as the fact that the addition of
ammonia
increases the
special sensitizing action of the dyes, but
the experiments described by to prove
that
Abney appear
most conclusively that
we must
nomenon.
some of
it is
to
me
in this direction
look for the explanation of the phe-
The
nature of the evidence furnished by
these experiments will be best appreciated from
a brief description of a few typical cases
A
plain collodion film
dyed with eosin was ex-
posed to the action of the spectrum
band appeared
in the
:
;
a bleached
green in the position of the ab-
sorption-band seen in the spectrum of the light trans-
mitted through the
film.
.
The
plate
was then coated
THE CHEMISTRY OF PHOTOGRAPHY.
318
with a collodio-bromide emulsion, allowed to dry,
A
and then developed.
dark band appeared in the
by the bleached band before the
position occupied
On
application of the emulsion and development.
repeating the experiment with cyanin the same re-
was obtained, only the bleached band was
in the
orange and the dark band, after development,
in the
sult
same position.
Then again
other experiments were
conducted with collodio-chloride films tinted with cyanin and exposed to the spectrum
was visibly sis
we
in the orange.
the normal
of photoin
in the region of absorption,
the i.e.
But there was nothing of the kind
maximum
of decomposition
showed
the violet, but the orange band was bleached
as before.
orange
maxima
under these circumstances, one
and the other
itself in
the latter
on the physical hypothe-
should expect to find two
reduction violet
Now
printed.
till
With
short exposure both the violet and
maxima came
out dark on development,
showing that the decomposition of the dye orange had given
rise to
in
the
products which reduced
the silver haloid sufficiently to enable
dark band on development.
it
to give a
Similar experiments
ABNEY'S EXPERIMENTS.
319
were made with gelatine-chloride films with the
same
result,
and, what
is
more
still
found that the dye exerted
its
it
striking,
action
if
was
the plate
was coated with a plain collodion or varnish
film
coloured with cyanin, and then exposed to
the
spectrum and developed. collodion or varnish gelatino-chloride
maximum
Even when the dyed
was washed away from the
film
after exposure, the
orange
could be developed, showing that the
reducing product of the decomposition of the dye
had done
its
work.
Many
other experiments were
made with
the other haloids both with cyanin and
erythrosin,
and
viz.
that
it
is
all
leading to the
same
conclusion,
the action of the spectrum on the
colouring matter in the region of absorption, and
not upon the silver haloid to the second
maximum
itself,
in the
graphed on an orthochromatic that time will not permit
which gives
rise
spectrum photo-
plate.
I
regret
much
me to give a more extended
account of these interesting experiments, 1 but
I
have
1 The original description of the experiments will be found in the Conference number of the Journal of the Camera Club, March i6th,
1888.
320
THE CHEMISTRY OF PHOTOGRAPHY.
described a sufficient
number
that their general drift
is
to enable
to see
you
to disprove the physical
hypothesis and to substitute chemical action.
Before taking leave of this part of the subject
am tempted
to offer a suggestion
which
may
I
be of
The chemical
use in guiding future experiments.
hypothesis of orthochromatic action rests upon the fact that the best special sensitizers are the
Now
fugitive dyes.
there
is
reason for believing
that the bleaching of a colouring matter action of light If this
is
due
most
by the
to photochemical oxidation.
be the case atmospheric oxygen
be
may
essential for the production of orthochromatic effect,
and the formation of a second maximum less
refrangible
prevented
part
of the spectrum
by immersing the
reducing solution, or
in
some
which prevented access of this
dyed
in
the
might be
plate
in
a
inert liquid or gas
air.
Experiments of
kind might easily be made, and
in the green, yellow, or orange, did
if
the action
not take place
under these circumstances, the chemical hypothesis of orthochromatic photography would be raised to the rank of a proved theory, while on the other
COLOURS ON SILVER CHLORIDE. the second
if
hand,
maximum
still
321
appeared, this
hypothesis would not be disproved, because possible that the breaking
down of
it
is
the complex
molecule of the colouring matter by the action of light
might take place
and thus
in the
absence of oxygen,
also give rise to the formation of products
of a reducing character.
Before
we have
spectrum on the
finished with the action of the
have to
call atten-
tion to a special property of the chloride
which has
silver haloids,
I
long been known, and which
is
nection
of
with
problems
the
greatest
of interest in conall
photographic
the direct and permanent reproduction
of the camera picture in
its
natural colours.
me
state at once, in spite of occasional
or
sensational
newspaper
Let
rumours
paragraphs, that this
problem has never been solved.
The only approximative attempts have been rendered possible by
the
fact
certain
that
silver
chloride
is
capable,
under
conditions, of receiving an impression of
the spectrum
in
which the colours more or
approach the natural spectral colours.
Y
less
THE CHEMISTRY OF PHOTOGRAPHY.
322
The
first
observations in the direction indicated
were made by Seebeck
was more Sir
in
and the subject
1810,
closely investigated thirty years later
by
The experiments went
to
Herschel.
John
show that when a
of silver chloride on
surface
paper was exposed to white light violet,
till
it
became
the spectrum then impressed itself on the
chloride, after a
approximating to the have
vestigators different
in
lengthened exposure, natural
conditions,
and
Other
hues.
on
carried
the
have
work
of
photochromatic
in-
under
confirmed
general result that silver chloride can susceptible
colours
the
be made In
impressions.
1847-48 and 1855, E. Becquerel made known his
experiments with polished
silver plates,
which were
covered with a film of violet chloride by a brief
immersion solution,
films
in cupric chloride or other chlorinating
and then exposed to the spectrum
recorded the colours
Herschel's violet chloride
were
obtained
by
in
Niepce
such
same way
the
paper.
;
as
Similar results
de
St.
Victor
(1851-66), by Poitevin (1865), by Zencker (1868),
and quite recently by Carey Lea upon the red
PHOTOCHROMA TIC IMPRESSION. photochloride which has
A
former lecture.
been
alluded
modification
323
to
in
a
method
of the
which has lately been described by G. Staats, 1
me
enables
show you an approximation
to
serve
to
general nature of the results.
A
photochromatic the
illustrate
which
to
printing
will
copper plate has been silvered by electro-deposition,
and the polished surface covered with a
slate-
coloured film by a brief immersion in a solution
of ferric chloride.
been placed
in
Various coloured glasses have
contact with the film and the whole
exposed to sunshine. glasses
it
is
On removing
the coloured
seen that under each glass there
is
a colour approximating some\vhat to that of the glass is
the correspondence
is
not very perfect, but
sufficiently distinct to enable
each
glass
has
given
a
you to see that
differently
coloured
impression [E].
These experiments have not yet led
to
any
practical issue, because the colours cannot be fixed,
but from a chemical point of view the line of work
opened up by them promises to be of 1
interest.
Ber. Dcutsch. Chem. Gesell. 1887, p. 2322.
Y
2
THE CHEMISTRY OF PHOTOGRAPHY.
324
The photochromatic property apparently belongs to the reduction product, which we now have good reasons for believing to be an oxychloride. at
It
may
sight appear improbable that the coincidence
first
between the colours of the spectrum and the colours of the impressed film
although this think that
is
nothing more. is
difficult to
is
it
a
is
an
By
mere accident believe
I
but
;
venture to
accidental
coincidence and
mean
to say that there
this
I
no connection of a physical nature between
the vibration-period colours
assumed by the reduction product
connection of
compounds
spectrum, and
to
the
probably arises from the production
different
these
of the ether-waves and the
it
happens
compounds
those of
parts of the
in different
approach
that
the
colours
somewhat
in
of
shade
the corresponding spectral colours.
In the best specimens of these photochromatic spectra that certainly
I
have ever seen, the colours were
nothing more than approximations to
the pure spectrum spectra
the
colours,
and
some of the coloured
unaltered
ground
colour
even
effect
of
in
these
was due
the
film,
to in
PHOTOCHROMY ON PHOTOSALTS. regions where
some
particular
duced no action at
Of
coloured products
had
colour
pro-
all.
of these differently
nature
chemical
the
325
we know
absolutely nothing.
According to Carey Lea the purple forms of the photochloride do not give such good red
the
produce
forms. distinct
Violet,
and yellow has
Staats
and
red
as
glasses
photochromatic impressions upon
the red photochloride effect,
blue,
results
green produces but
;
capricious in
is
recently
its
little
action.
G.
made some experiments, 1
having for their object the isolation of the different coloured products, but after dissolving the colours off the silvered plate
by ammonia, no other product
than
red
Carey Lea's
means be obtained.
photosalt could
The
by any
coloured products are
destroyed by the action of the solvent, and
when heated on
colours to
By
Staats, converted
allowing thin
chloride solution
were
colours 1
for
a
the
the plate are, according
into the
silver
all
foil
red photochloride. to
float
few seconds
till
in
ferric
distinct
produced, this same experimenter
Ber. Deutsch. CJum. Gesdl. 1888, p. 2199.
326
THE CHEMISTRY OF PHOTOGRAPHY.
succeeded in obtaining films of a violet and red colour from which the excess of silver could be dissolved out
by
nitric acid, the films
retaining their original
colours.
thus treated
Until
analyses of these coloured products
it
we have useless
is
to attempt to speculate as to their chemical nature,
but a survey of
all
the facts available
improbable that we chlorides or altered
may have
it
in these cases
it
not
oxy-
compounds of oxychlorides with un-
chloride
containing varying
of water of hydration this
makes
would be
or
proportions
constitution.
Beyond
at present unsafe to venture in
attempting to deal with the chemical principles of
photochromy.
APPENDIX TO LECTURE
A
(p.
290).
The
VIII.
relationship between absorp-
and photochemical decomposition can be shown by taking two glass cells A B, C D, with
tion
parallel
sides, dividing
each
cell
into
two
parti-
septum and then strapping the two together side by side by means of india-
tions
by a
vertical
rubber bands.
mercuric chloride
(Exp. G,
p. 32)
in
A
B is filled with the and ammonium oxalate mixture
The
cell
one partition B, and with water A. The other cell is filled
in the other partition
with the mercuric oxalate mixture in both partiThe arrangement is shown in tions, C and D. plan below
:
JT2
FIG. 14.
The whole system beam, A
B
is then placed in the electric the light, and exposed towards being
THE CHEMISTRY OF PHOTOGRAPHY
323
the contents of
till
B become
distinctly opalescent.
On
disconnecting the cells and exhibiting the result it will be found that C has remained clear
B
D
has become opalescent, the rays traversing having been deprived of their decomposing
while
power by passing through the mercuric
solution.
D
The
having passed only through rays reaching are active towards the mixture. the water in
A
The
internal diameter of each cell should be at
least
an inch, so that the light
may
traverse this
thickness of solution in passing through the front Instead of the mercuric oxalate mixture, cell.
ammonio-ferric oxalate solution the contents of
C and
by means of potassium
B
(p.
notes
Two
298).
are
in
unison
D
may
be used and
tested after exposure
ferricyanide.
tuning-forks of which the are selected, one being
mounted on its sounding-box. The other fork is then struck and while vibrating is brought as near the fork on the sounding-box as is possible without actually touching. The latter soon takes up the vibrations and emits a note on its own account.
C
The
absorption spectra of chlorine, bromine, and iodine are shown in the usual way by placing flasks full of the gas or vapours in (p.
299).
front of the
slit
in the nozzle of the lantern
and
projecting the spectrum on the screen. E>
(p. 312).
The
absorption
spectra of
dyes
APPENDIX TO LECTURE
VIII.
329
magenta, cyanin, &c.) are shown by interposing gelatine films coloured with the substances in question in the path of the ray o light passing 'eosin,
from the lantern through the prisms of the spec-
trum apparatus. The special sensitizing action of a dye is shown by exposing a sheet of paper coated with silver bromide and dyed with a solution of eosin (i
of
the
gram per 1000 for
a few
c.c.)
to the action
minutes
spectrum developing with ferrous oxalate.
and
then
Two maxima
appear, one near G, and the other in the green. The limits of the spectral colours are marked out in pencil as
E
before during exposure.
(p. 323).
about
5
The
silver plate is
10 seconds in a
immersed
for
5 per cent, solution of
As soon as the surface has acquired uniform slaty colour the plate is withdrawn, washed with water, and dried on a blotting-pad. The coloured glasses are then laid on the surface ferric chloride.
a
and the whole exposed
to
coloured impressions are
formed.
found to be
much more
bright light
till
the
Sunlight was
effective than the electric
(arc) light, twenty or thirty minutes' exposure having been found necessary at the time the plate referred to was prepared. The plate can be used
over again by dissolving off the colours with dilute ammonia, washing, drying, and re-polishing with lixiviated chalk.
LECTURE Post-developmental Processes. cation
IX.
Fixing Agents.
Intensifi-
and Weakening of the Silver Image. Printing Albumenized Paper Process. Emulsion
Processes. Prints.
pounds.
Reduction Products of Organic
Image Transference.
with Gold.
Toning of
Theory of the Operation.
Silver
Com-
Silver Prints
The
Platinotype
Chromatized Gelatine and Pigment Printing
Process.
Processes.
who have worked
IT
is
at
photography that the developed
familiar to all
practically
image has to
be submitted to certain subsequent operations order to obtain a finished picture from
it.
in
The
chemistry of these post-developmental processes is
comparatively simple, and
this
concluding
The
first
after
lecture
thing to be
development
is
to
I
propose to devote
their
done with
to fix the
consideration.
the
image
negative ;
and
this
FIXING AGENTS. operation, chemically speaking,
331
nothing more
is
than the removal of the unaltered silver haloid
from the film by the use of a suitable solvent
which
will
take out the unchanged haloid without
The
attacking the silver picture.
now employed thiosulphate,
both
dissolving the
fixing agents
are potassium cyanide or sodium
these salts being capable of haloids
silver salts
in water.
in the case
the silver haloid
of their
virtue
which are extremely soluble
forming double Thus,
by
of potassium cyanide
dissolved out of the film in
is
accordance with such reactions as these
:
AgBr + 2KCN = AgK(CN) 2 + KBr Agl + 2KCN = AgK(CN) 2 + KI. The
sodium thiosulphate as a fixing
use of
agent was, as already stated, suggested by Sir
John
Herschel "
"
hyposulphite
in
1839.
The
old
name
has been abandoned by chemists
because a lower acid forming a series of
M' 2 SO 2 has been ,
berger,
of
since
described
salts,
by Schutzen-
and these are accordingly the true hypo-
sulphites.
It
would
be well
for
the
sake of
THE CHEMISTRY OF PHOTOGRAPHY.
33^
nomenclature
in
uniformity
would generally adopt
The double
the
sodium thiosulphate
necessary alteration. action
haloid
silver
of a
is
the
silver
:
'
The
photographers
formed by the
salt
thiosulphate upon
-fJNa 2 S 2 O 8
AgBr
this
if
solid crystalline
double
has the formula
salt
AgNaS O 3 H 22
>
It is well
is
that a strong solution of thio-
necessary in fixing
is
sulphate
known
too weak, instead
double
double
salt
salt
there
of the
of the formula
which would remain
extremely soluble
formed
is
another
Ag^Na^
in the
the solution
if
;
film
(S 2
insoluble
O
3
)^2H 2 O,
It
[A].
is
only
necessary to point out in dismissing the chemical action of fixing agents that the potassium
nide of
commerce
is
tendency to soften the gelatine
moreover
has
metallic silver, sity of the
a
cya-
always alkaline and has
slightly
This
film.
solvent
action
a
salt
upon
and thus tends to reduce the inten-
image
in the
medium
reasons sodium thiosulphate
is
tones
:
for these
safer as a fixing agent.
INTENSIFICATION OF IMAGE. sometimes
It
development and fixing cient density for
which
may
a
that
happens
negative after
found not to have
is
from
exposure or
insufficient
under development or other causes, as all photographers know,
I
shall
best
have to limit
my
is
remedied,
by a process of
There are many
fication.
suffi-
This defect,
printing purposes.
arise
333
intensi-
intensifiers in use,
and
remarks to a few of the
known substances employed
for this purpose.
In the old collodion process the image was often intensified
by the application of a
further quantity
of an acid ferrous sulphate or pyrogallol developer to
which a
just
little
before
use.
silver
nitrate
The
silver
enabled to go on increasing process as that It is
by which
image was
thus
density by the same
in
it
had been added
was
originally formed.
evident that this operation
is
nothing more
than a continued development. In
the
case
silver intensifier
tendency salts.
Of
of
of is
gelatine
films the
objectionable
gelatine
the various
to
use of
a
because of the
retain
intensifiers
soluble
now
in
silver
use,
mercuric chloride followed by the application of
334
THE CHEMISTRY OF PHOTOGRAPHY.
other substances tical
is
recommended by many
photographers, and
follow out the chemistry of this process.
negative
immersed
is
If
a
a solution of mercuric
in
chloride the dark image
prac-
be instructive to
will
it
becomes bleached, owing
to the reduction of the mercuric salt to mercurous
chloride
by the
metallic silver, as
by Scott Archer
in
1851 [B]
was pointed out
:
Ag2 + 2HgCl 2 = 2AgCl + Hg The image
is
.
mercurous chloride, both
being white and insoluble, but
not
sufficiently
enable the negative to be used for
to
After washing off the bleaching solu-
printing. tion,
Cl 2
thus transformed into a mixture
of silver chloride and
opaque
2
the white picture
is
therefore darkened
by
being washed over with some other solution which effects the
necessary change in colour.
using a dilute solution chloride chloride
out
dissolved
is
of
Thus, by
ammonia
the
and
mercurous
the
silver
transformed into the dark dimercurous-
ammonium
chloride [C]
:
Hg2 Cl + 2NH 3 = NH Hg 2
2
2
Cl
+
NH
4 C1.
INTENSIFICATION OF IMAGE. Sometimes ammonium sulphide
is
335
used, in which
case the mixture of silver and mercurous chlorides
transformed into a mixture of the sulphides.
is
Or
again, the bleached picture
may
be darkened
application of sodium sulphite [D], which
by the
reduces the mercurous chloride to mercury, or by
which
oxalate,
potassio-ferrous
both
reduces
the silver and mercurous haloids to the metallic state [EJ:
Hg
2
Cl 2
+ Na SO + H O = 2Hg + Na SO 3
2
2
2
4
+ 2HC1 2 AgCl
+ 2FeC 2 O 4 + K 2 C O 4 = Ag2 + Fe 2 (C O 4 2
2
)3
+ 2KC1
Hg
2
Cl 2
+ 2FeC
Such an
2
4
+ K C - 2Hg + Fe + 2KC1 2
intensifier
4
2
2
(C 2 O 4 ) 3
as potassio-ferrous oxalate
thus restores the image in silver and mercury, the total density
again
being obviously
treating
chloride
such
an
much
image
increased.
with
By
mercuric
and repeating the application of ferrous
oxalate, a further increase in density
so the process can
is
given,
and
be repeated any number of
THE CHEMISTRY OF PHOTOGRAPHY.
336
times in succession
Another
obtained.
many workers
for
intensifier
gelatine
of potassio-silver
formed
first
This solution
by mercuric
The
is
silver is
is
plates
nitrate
by adding
of
potassio-silver rise to
but the substance
containing also 1
and
redissolved.
applied to the image bleached
cyanide
is
upon
the formation of
a dark product which contains a large
stituent
the pre-
chloride [F].
action
of chlorine.
a solution
till
all
nearly
mercurous chloride gives
silver,
is
recommended by
cyanide, prepared
potassium cyanide to cipitate
the necessary opacity
till
amount of
a complex mixture
mercury, cyanogen, and a trace
Silver appears to be the chief conits
formation
ing to the reaction
may
take place accord-
:
Hg 2 Cl 2 + 2AgK(CN) = Ag 2 + 2Hg(CN) 2 + 2KCL 2
1
This statement
duct, obtained
is
based on a
series of analyses of the
by allowing a solution of
dark pro-
potassio-silver cyanide to
in contact with freshly precipitated and washed specimens of mercurous chloride for periods varying from seventeen hours to
remain
fourteen days.
J.
The experiments were made
at the
Finsbury Tech-
by two students of the Chemical Department Messrs. M. Smith and J. II. Coste.
nical College
INTENSIFIERS. Another
class of intensifies
is
337
by such
typified
as the ferricyanides of uranium
compounds
lead, the first of these
having been introduced by
Selle,
and the second by Eder and Toth.
silver
image
is
and
washed with a solution of a
If the ferri-
cyanide, the latter becomes reduced to ferrocyanide.
Thus
the case of lead ferricyanide
in
:
2Ag2 + 2Pb 3 Fe 2 (CN) 12 =Ag4 Fe(CN) 6 +3Pb 2 Fe(CN) 6 The
silver
image thus becomes converted into a
denser picture composed of a mixture or possibly of a
compound of Both these
silver.
to darken
the ferrocyanides of lead and salts
are white, and in order
them and render them opaque, the
plate,
after the intensifying solution has been thoroughly
washed
out,
is
treated with a solution of
ammonium
sulphide so as to convert the ferrocyanides into the
dark sulphides of the metals.
uranium
The
action of Selle's
intensifier is similar in principle,
only the
uranic ferrocyanide, being of a dark brown colour, at
once
intensifies the
picture without
the
sub-
sequent application of a darkening agent such as
ammonium
sulphide.
The
metallic ferricyanides
THE CHEMISTRY OF PHOTOGRAPHY.
333
used in these intensifiers are prepared by double
decomposition between a soluble
metal and potassium ferricyanide 3
Pb(N0 3 ) 2
-f
intensifiers
;
12
2
of the heavy
e.g.
K c Fe (CN) = Pb + 6KN0 3
The
salt
3
:
Fe 2 (CN) 12
.
most generally used having thus
served to illustrate the general chemical principles involved in the process,
much
it is
unnecessary to dwell
longer upon this part of the subject.
just point out that of the
numerous
possible
way
by
substituting
metal for the silver of the image. case,
for
chlorides
instance,
and
the
another is
the
pla-tinic
Ag2 + 2 AuCl 3 - Au^ + 6AgCl
and
selection
intensifier
auric
This
in
:
3
The
with
may
intensifiers
proposed by various operators, some act simplest
I
practical application of the
most suitable to any particular kind
of negative
is
a
matter of individual judgment
and experience, but
if I
attempted to deal with
WEAKENING AGENTS. this I
should be going beyond
my
339
present limits,
which, as you are fully aware, do not comprise
photographic manipulation.
The weakening
of a negative which
by over
exposure or over development has given too dense
an image,
another problem which the photo-
is
grapher sometimes has to deal with.
In this case
down by the The chemical
the silver deposit has to be thinned
use
of
an
appropriate
which
conditions
have
solvent.
to
be
met
are
simple
enough, although the practical application of the
method of
skill
is,
as in the case of intensification, a matter
and judgment.
employed
The substances
generally
are those which are capable of partially
converting the metallic silver into a salt which can
be
immediately
dissolved
weakening solutions
of
the
in use will serve to illustrate
the principle of action.
substances as
Two
away.
I
shall
speak of these
"weakening agents"
avoid the use of the term
"
in
order to
reducing agents," which
has a totally different chemical meaning. It is well
known
that a silver plate can be coated
with a film of chloride by immersion in a solution
340
THE CHEMISTRY OF PHOTOGRAPHY.
of ferric or cupric chloride reduces these salts [G]
:
words
in other
:
Ag + 2CuCl = 2 AgCl + Cu Cl Ag + Fe Cl 6 = 2 AgCl + Fe Cl 4 2
2
2
It
silver
2
2
2
2
would thus appear
.
wash the
to
sufficient
image with one of these chlorinating solutions so as to
cover the silver superficially with chloride,
and then dissolve
sodium
chloride with
Such a method of weakening would
thiosulphate.
no doubt be
off the
effective,
but
it
would be attended by
a serious practical difficulty, and that
is
that the
operator would not be able to ascertain to what
extent the chlorinating solution had acted
till
after
the removal of the silver chloride, and then he
might find too far.
late that the action
The weakening agents now
had gone too in
vogue have
therefore been devised with the object of enabling
the operator to see the course of the action of the solution, so as to stop the process at the desired stage.
The two weakening agents which
selected as types have been introduced
and Farmer
respectively,
I
have
by Eder
and they both depend
upon the reducing action of the
silver
of the image
WEAKENING AGENTS. upon a
ferric salt,
and the simultaneous removal of
the silver salt thus formed
Thus
341
by sodium
thiosulphate.
in Eder's process a solution of potassio-ferric
oxalate
is
ferric chloride to
prepared by adding
potassium oxalate, and this solution, immediately before use,
mixed with a
is
On washing
thiosulphate.
mixture the
silver
oxalate, which
thiosulphate
in
the
solution of
the plate with first
this
forms an
place
immediately removed
is
sodium
by
the
:
Ag2 + Fe 2(C 4)3 = Ag2 C 2 4 + 2FeC O 4 Ag C 2 O 4 + 2Na 2 S 2 O 3 = 2 AgNaS 2 O 3 + Na 2 C 2 O 4 2
2
2
Farmer's solution, which
weakening agent
.
generally used as a
is
for gelatine plates,
is
a mixture
of potassium ferricyanide and sodium thiosulphate.
The
silver in
this
superficially into
case
becomes converted
first
ferrocyanide,
and the
then dissolved by the thiosulphate
:
+ 2K 6 Fe 2 (CN) 12 = Ag4 Fe(CN)c +
Ag4 Fe(CN) 6 + 4Na
2
S2
3
latter
K
4
Fe(CN)
= 4AgNaS O 3
+ Na 4 Fe(CN) 6
2
.
is
THE CHEMISTRY OF PHOTOGRAPHY.
342
When
a finished negative has been produced, the
next operation
Of
to obtain a positive print from
is
the printing processes
now
albumenized paper process employed, and
therefore
is
familiar to you, so that
method.
this
printing
is
in use, the
ordinary
the most generally
no doubt the most
we may commence with
In order to prepare the paper for
it is first
coated with a solution of salted
latter substance
albumen, the
being obtained from
the whites of eggs, and the salt used being
nium is
chloride.
sensitized
When
floated for a short time on a
by being
Now
and
dry.
us
the chemical
prepared
in
this
ammo-
dry the albumenized paper
silver nitrate bath, after
is
it.
the
which first
it is
point
allowed to drain that
concerns
nature of the sensitive surface
The ammonium
way.
of course forms
chloride
silver
chloride
by double de-
composition, but the sensitiveness of the surface is
not
due
the albumen
to also
forms
silver
of the
nitrate
been
alluded
to
compound which
chloride
silver
(p. is
a
only,
because
compound with
the
a fact which has
already
The
of the
117).
nature
formed when a soluble
silver
SIL VER salt
ALB UMEN PRINTS.
343
added to a solution of albumen
is
unknown, but
this
mind the
bear in
is
quite
need not surprise us when we fact that
we know
practically
nothing of the chemical nature of albumen
itself.
The
(after
empirical formula generally assigned
Lieberkiihn)
C 72 H 112 SN 18 O 22
;
but there
is
is
really at
present no satisfactory evidence that the substances
found
animal and vegetable kingdom, and
in the
grouped by chemists under the general name of "
definite chemical
albumenoids," are
at
all.
methods of formula of the
to
who
Those
are
organic
a
of
will
having
complexity indicated
deduced from analytical
with
acquainted
analysis
compound
compounds
see
any
the
approach cannot be
above,
results with
that
the
any degree
reliability.
Whatever albumen,
it
may is
its
ble
compound with
this
substance little,
the
true
constitution
at present only essential that
should recognize
matters
be
is
of
you
property of forming an insolusilver nitrate
[H].
Whether
a salt or a molecular
but, like all
compound other organic silver com-
pounds, such as the "gelatino-nitrate" referred to
344
THE CHEMISTRY OF PHOTOGRAPHY.
in a
former lecture
(p.
nS),
light with the formation of a
product, and this
is
The
it
is
decomposed by
reddish-brown reduction
the property which
in the printing process ing.
1
utilized
which we are now consider-
sensitive surface in this process consists
therefore of a mixture of silver chloride tc
is
and
silver
albumenate," together with the excess of silver
nitrate.
The
negative
is
placed in close contact
with a sheet of this prepared paper, and all
know, exposed
as
you
the positive image
is
somewhat deeper shade than
is
to light
visibly printed to a
is,
till
With
actually required in the finished print.
re-
spect to the chemical composition of the positive print at this stage all that can be said
that
is
it
is
formed of a mixture of the photo-reduction products of silver chloride and silver silver nitrate
"albumenate."
The
no doubt acts as a sensitizer towards
the chloride, but
it is
improbable that
it
plays this
part towards the organic silver compound. 1
Certain organic bases belonging to the group of " anhydro" give gelatinous precipitates with ammoniacal silver nitrate
bases
which darken on exposure to light, and in their general appearance and properties are very suggestive of the silver compounds formed by albumen and gelatine. See a paper by the author and F. \Y. Streatfeild, Journ. Chem. Soc. Trans. 1887, p. 699.
-
PRINTING EMULSIONS.
345
Instead of using a printing surface in which the
and organic
silver chloride
formed together, as the silver haloid vehicle
silver
compound
are
the process just described,
in
may be emulsified in some
organic
and the paper or other printing surface Several of these emul-
coated with the emulsion.
Thus a
sion printing processes are in use.
collodio-
chloride
emulsion
was introduced by Wharton
Simpson
in
which
silver chloride is emulsified in
collodion,
and
an organic
citric acid
added to play the part of
A gelatine-chloride emulsion
sensitizer.
has been introduced by
Abney
of silver chloride and citrate tine
in
previously described salts.
which a mixture
emulsified in gela-
manner, and then washed as
the usual
of soluble
is
in
(p.
123) to
remove the excess
For the various modifications
and the modes of application of these printing emulsions
From
I
must
refer
you to the
a chemical standpoint
it is
practical treatises.
important to
re-
member
that the action of light
sions
allowed to continue up- to the stage of
is
visible decomposition,
mation of an
and
is
invisible image.
upon these emul-
not stopped at the for-
The
printed picture in
THE CHEMISTRY OF PHOTOGRAPHY.
346
these cases
all
is
therefore
composed of a complex
mixture of the reduction products of the
silver
haloid and of the organic silver compound.
There which
is
is
another method of obtaining silver prints
now very
frequently employed, and which
combines both printing and development on the
same
In this process, advantage
surface.
is
taken
of the extreme sensitiveness of gelatino-bromide emulsion, paper coated with this emulsion having
been recently introduced by the Eastman Company. It
would be superfluous
for
me
to say anything
further about the chemistry of this method, as the principles have been lectures.
amply
dealt -with in former
This bromide paper can be used
for contact-
printing from a negative in the usual way, only, instead of exposing up to the stage of visible decomposition, a short
exposure
is
given,
and the
image developed by ferrous oxalate
;
invisible
the print
is
then washed and fixed as in the ordinary gelatino-
bromide dry plate process. therefore in this case
and has the
in
The
positive picture
composed of
metallic silver,
consequence a very different
ordinary
albumenized
silver
is
"
tone
prints.
"
to
One
GELATINO-BROMlDE PAPER. advantage possessed by
this
347
bromide paper
is
that
the great sensitiveness of the emulsion for rays of
low refrangibility enables a print to be made by
means of gas it
light,
artificial
such as lamp light or
light,
and the same property of the
film enables
to be used for the production of enlarged prints.
It is
only necessary to put the negative into a kind
of magic-lantern, and throw
its
image, magnified by
the lens up to the desired scale, on to a sheet of the bromide paper and expose, develop, and fix as
With an ordinary
usual.
paraffin
lamp with a
metallic reflector behind it in the lantern, an ex-
posure of three minutes has been found sufficient to give an enlarged
negative area.
image from a quarter-plate
on a sheet of paper 12x10 inches
Some
in
of the results obtained by this method
of enlargement have been forwarded
man Company
for inspection.
these pictures
is
it
In looking upon
interesting to reflect
accumulated experience which possible for the
by the East-
has
upon the
rendered
modern photographer
it
to take a
negative in a very few seconds, and to obtain from it
an enlarged positive
print,
using
only such
THE CHEMISTRY OF PHOTOGRAPHY.
348
sources of light as would have been quite inadequate
any impression on the
to produce
employed
before
the
sensitive films
introduction
of
gelatine
emulsion.
Returning to the question of
composition
composed of
compound
image printed on a surface
the
chloride
silver
of
chemical
of the
and some organic
such as the
silver,
the most obscure point
albumenate,
the nature of the re-
is
duction product of the organic silver compound.
There
is
a wide
field
direction,
because
it
for
investigation
in
this
would appear from certain
experiments which have been made from time to time,
that
we may have
organic silver
reduction products
compounds which
the oxyhaloids or photosalts.
of
are analogous to
This
is
a very in-
teresting point in connection with the chemistry
of silver compounds, and
portant because
we know
it
is
all
the
more im-
absolutely nothing of the
nature of these organic silver reduction products.
The evidence which
justifies
the belief that these
products are the organic analogues of the haloid photosalts
may
be very briefly summarized.
IMAGE TRANSFERENCE. In the
first
349
place an albumenized glass plate
coated with silver albumenate by immersion in a
bath gives an image on exposure
silver nitrate
which can be developed by means of pyrogallol. This observation was made by Monckhoven
and
1863,
in
importance in connection with the
its
present subject consists in the fact that no silver haloid
is
present in the film, so that the image
is
formed entirely by the photo-decomposition of the
we
more
next
place
distinct evidence in the
same
direction from certain
experiments on what
called
albumenate.
In
the
is
"
get
image transference
"
which have been recently made by Carey Lea. In order to give a clear notion of
by
"
image transference," which
experiment
in
Pizzighelli
1881.
I
was
An
what
made
Eder
and
invisible
image
was
silver chloride,
that silver chloride
is
and
was treated
with a solution of potassium bromide.
this last salt
an
by
then, before development, the plate
known
meant
will first describe
formed on a plate coated with
well
is
Now
it
is
decomposed by
:
AgCl + KBr = AgBr+KCl.
350
THE CHEMISTRY OF PHOTOGRAPHY.
The
unaltered silver chloride
and not only
into bromide,
product (photochloride)
is
thus converted
this,
but the reduction
also
transformed into
is
the analogous photobromide
the image becomes
transferred from the chloride to the bromide,
the reduction
and
product of the latter can be de-
veloped as usual after the plate has been washed.
The experiment
is
not striking enough as a lecture
demonstration to warrant but chemically
it
its
repetition before you,
of great importance.
is
Sup-
posing the reduction products to be oxyhaloids the
change
be thus represented
may
:
Ag4 OCl + 2KBr - Ag4 OBr2 + 2
Now
Carey Lea has accomplished
silver
compounds what Eder and
done
for the
chloride.
He
2KC1.
for the organic
Pizzighelli
have
has found that such
salts as the tartrate, citrate, oxalate, benzoate, &c.,
are capable of receiving an invisible
image which
can be transformed into the corresponding haloid reduction product
by treatment with hydrochloric
or hydrobromic acid, ferred
can
be
and the image thus
developed
as
usual.
trans-
The
full
IMAGE TRANSFERENCE significance
351
of this observation will appear
repeat one of the experiments
paper coated with
A
[I].
silver tartrate is
about a minute to the
if
I
sheet of
exposed
for
In accordance
electric light.
with the general notions of photo-decomposition
we may now expect
to have a surface
On removing
reduction product of the tartrate. the paper and dilute
painting
hydrochloric
acid,
formed of the
a design
upon
we have
a
design
photochloride on a background of what
The
provisionally call phototartrate.
pound give
is
capable of development, but
with
it
I
latter it
in
may com-
does not
such a dense image as the photochloride,
so that on tearing the paper in half and developing
one portion with ferrous oxalate the design comes out black on a dark ground.
From
the other half
of the paper the phototartrate can be completely
removed by immersion
in dilute nitric acid,
does not attack the photochloride. ing
and developing
this
which
Now, on wash-
other half, the
comes out black on a white ground.
design
Such ex-
periments as this point to the formation of organic silver reduction
products, and
it
is
possible that
THE CHEMISTRY OF PHOTOGRAPHY.
352
" the darkened " gelatino-nitrate or albumenate of
silver this
consist of such
may
reason that
I
It is
compounds.
for
have directed attention to the
subject of image transference in connection with
the theory of silver printing.
Whatever may be the actual chemical composition
of
the
image
albumenized
this
is
image
This
toning."
a
surface
and
it
is
of
manner
the
in
reddish-brown
the
objectionable,
modified by a "
sensitized
paper
already described,
on
printed
colour
of
accordingly
subsequent operation known last process consists in
as
depositing
on the darkened portions of the print a finely precipitated
powder of reduced
gold
some
or
other metal, which changes the reddish colour of the
mixed reduction products
familiar in finished silver prints.
toning
being
is
now most
first
toning-bath
The auric
then
the tone so
In practice, gold-
generally in
washed and till
into
use, the
immersed
the desired shade
is
print
in
the
reached.
toning-bath contains a neutral solution of chloride,
AuCL,
3
as
its
active
constituent,
TONING OPERATION.
353
the salt being generally supplied in the form of the double
NaAuCl 4 ,2H 2 O, which
salt,
by evaporating a
double
crystallizing
and
neutral,
sodium chloro-aurate,
chloro-auric exists
chloride,
acid,
a
in
common
obtained
and
salt
point.
This
which has the advantage of being
salt,
non-deliquescent as
the
to
chloride
auric
of
solution
is
i.e.
HAuCl 4
,
may
the sodium salt of
compound which
the
acid
hydrochloric
be regarded
solution
of auric
and which can be obtained therefrom by
evaporation in yellow crystals having the formula
HAuCl 4 ,4H 2 O. With process,
respect to the
appears to
it
unnecessary into
chemistry of the toning
me
mystification
some of the
treatises
that a great
been
has
deal of
introduced
on photography.
Con-
A
sider the state of affairs in the toning-bath. film,
composed of the reduction products of
chloride
unaltered
immersed essential
and
silver
silver in
for
albumenate
chloride
and
together
results
that
should be neutral, and the gold
with
albumenate,
a solution of auric chloride.
good
silver
It
is
is
the toning-bath
salt is
accordingly
A A
354
THE CHEMISTRY OF PHOTOGRAPHY.
mixed
with
sodium is
it
such
carbonate,
well
known
substances
as
borax,
chalk,
Now
phosphate, or acetate.
that gold salts are most readily
almost any reducing agent, organic or
reducible
inorganic, will precipitate gold from a solution of
the chloride.
Thus, the action of sulphurous acid
or ferrous, sulphate
may
be taken as typical
[J]
:
2AuCl 3 + 3H 2 SO 8 +-3H 2 O = Au 2 + 3H 2 SO 4 + 6HC1
2AuCl 3
6FeSO 4 = Au + Fe
4-
2
The toning
solution
may
2
Cl 6 4
2Fe,(SO 4 ) 3
therefore
.
be looked
upon as containing a potential deposit of metallic gold ready to be precipitated on any reducing surface
that
same way
may
be bathed by
it
just
in
that the acid developing solution
the
may
be regarded as containing a potential deposit of metallic
silver.
silver chloride
image
The
reduction
products of the
and albumenate forming the
act as reducing agents, 1
positive
and thus become
1
If a reducing agent is put into the toning-bath, it reacts directly with the auric chloride^ and prevents the precipitation of gold on the image. This is why it is so constantly urged in all practical
manuals that no sodium thiosulphate should be allowed the toning-bath.
to get into
THEORY OF TONING PROCESS.
355
covered with the deposit of gold which imparts the
tone
the
to
The unchanged
print.
silver
and albumenate cause no reduction, and
chloride
therefore receive no deposit.
Much
stress
laid
is
upon the necessity
by
keeping the toning-bath
for
and the reason
neutral,
practical photographers
for
this
appears to be
that the presence of free acid checks the depo-
Free hydrochloric acid would
sition of gold. fact
play the part of a restrainer, and since this
must necessarily
acid
of the auric chloride,
some the
in
salt
acid
which
at
and
it
result
from the reduction have present
requisite to
is
once enters into reaction with
forms
a
soluble
chloride
v/ith
the liberation of an equivalent quantity of
some
milder acid, such as acetic, carbonic, &c. the or
of
function
the sodium
other salt which
solution.
doubt altered
in
is
The sodium turn
its
silver
acetate,
This
carbonate,
mixed with the chloride thus
helps to
albumenate
toning
formed no
decompose the unor
free
any
nitrate present in the film, converting these
pounds into
silver
is
chloride which
is
A A
silver
com-
dissolved 2
THE CHEMISTRY OF PHOTOGRAPHY.
356
out in
the
subsequent operation of fixing by
thiosulphate.
The
colour of finely-divided
by reduction from a
gold precipitated
solution of one of
its
salts
depends very much upon the state of concentration of the solution and the rate at which
This
a very old
is
it is
deposited.
observation due to Faraday.
If the deposition takes place very slowly
a red form of gold,
if it
we
get
takes place more rapidly
the gold particles appear blue, these differences
being doubtless due to different states of molecular
Now
aggregation.
albumenate
is
the reduction product of silver
and
naturally red,
the blue form of gold which
is
it
therefore
required in order
to give the print the desired tone.
reason that the toning-bath
is
It is for this
kept neutral
is
;
the
deposition of gold must take place as rapidly as possible consistently with uniformity in order to insure
the
form.
The accumulation
precipitation
of
the
of
a
blue-particled restrainer
hydrochloric acid in the toning-bath to
be
addition
avoided of
;
the
this salts
is
is
accomplished
referred
to,
like
therefore
by
the
and by the
FIXING OF PRINTS.
357
occasional neutralization of the bath solution with chalk.
After the print has been toned
is
it
washed and
by immersion in a solution of sodium thioThe chemistry of this operation has sulphate. fixed
already been sufficiently explained
;
but
is
it
im-
portant to remember that in the silver print at this
stage
reduction
we have an image composed of of
products
chloride coated with
silver
the
and
albumenate
a deposit of gold, the
re-
maining portions of the surface consisting chiefly of silver chloride formed by the action soluble
chlorides
in
the
toning-bath
of the
on
unaltered silver albumenate and the free nitrate film.
which
The
may have been
thiosulphate of
all this silver
chloride, but
retained
the
silver
the
by
course dissolves out
it is
without action on
the reduction product of the albumenate, so that the image
is
not affected by the fixing solution
so far as concerns this organic silver constituent.
But the reduction product of
known
to be
silver
chloride
is
decomposed by sodium thiosulphate,
THE CHEMISTRY OF PHOTOGRAPHY.
358
leaving a residue of metallic silver
inorganic silver constituent (photochloride)
image must therefore be decomposed bath, and the finished print
The
(p. 45).
of the
in the fixing
must be looked upon
as consisting of an organic silver
with
silver
compound coated The importance of thoroughly
1
and
gold.
washing out every trace of thiosulphate in order to
well
is
insure
known
to
after fixing
the permanency of the print
all
One
photographers.
of the
instability of silver prints
chief causes of the
is
the imperfect removal of the soluble thiosulphate or
the
formation of
OV Ag|Na.(S 2 3
owing
thiosulphate or to In
fixing-bath.
destruction therefore
is
of
the
irregularity of
order to
the
to
thiosulphate
to an insufficiency of
last
insure
trace
recommended
of the print
insoluble
action
the
in
latter
in
the
complete
of thiosulphate
after the final
immerse the
sodium
it
washing a
weak
solution of iodine in potassium iodide, the iodine
1
Much
of the i-ediiction product of the silver chloride
is
no doubt
re-chlorinated by auric chloride during the toning process, so that the proportion of metallic silver
extremely small.
left
in the finished print
must be
PLATINOTYPE PROCESS. the
converting
according to the well
2Na 2 S 2 O 3 The
+
I2
substitution of
for the
albumenized
been solved purpose
known
principles
which have been
former lectures.
We may use
salts,
means
in
^Nal.
accordance with the chemical
One
finely-divided platinum,
sufficiently
composed of
and the chemistry of
made
aid of previous
fact that the salts of
discussed
of the most promising of
platinotype process can be
by the
for this
and develop by ap-
these recent methods gives an image
ble
surface
a problem which has
ways.
uranic
ferric or
:
some other printing
silver is
in several
tetrathionate
reaction
= Na5 S 4 O 6 +
propriate
in
into
thiosulphate
359
this
readily intelligi-
considerations.
The
platinum are susceptible of
photo-decomposition has already been alluded to (p. 20).
This property was
by Herschel, and
the
made known
in
1832
photo-chemistry of the
platinum compounds has been since investigated
by Hunt, Gehlen, and many not permit
me
others.
Time
will
to relate the various steps in the
history of the process,
and
I
need only add that
it
360
THE CHEMISTRY OF PHOTOGRAPHY.
has been brought to
by Mr.
tion chiefly
present state of perfec-
its
Willis,
and that
it
has been
'thoroughly investigated by Pizzighelli and Hiibl.
The
first
directed
salts,
that the platinotype process
is
method of
which attention must be
point to
when
not a
Although the platinum
direct printing.
especially
is
the platinous condition,
in
are capable of being reduced to the metallic state
by the
action of light in the presence of organic
reducing agents, this property has not yet been
made
available
platinum
for
the
This
print.
direct
of
a
one of the problems
is
awaiting future solution.
production
The modern
platinotype
process depends upon the indirect reduction of the
by some
compound which first undergoes photo-reduction, and is then made to react with the platinum salt. The principle consalt
platinum
cerned use of
is
somewhat
similar to that
when a negative
chloride
(p. 338).
the image
is
is
which
intensified
by
is
made
platinic
In this case the metallic silver of
the reducing agent, and
if
we suppose
the platinum solution to act for a sufficient time,
the whole of the silver would be converted into
PLA7INOTYPE PROCESS. and the image replaced by
chloride,
in metallic
On
platinum.
its
361
equivalent
fixing with thiosulphate
the silver chloride would be dissolved away, and the
This
left.
image
platinum
the
illustrates
indirect production of a platinotype print [K],
modern process the photo-reducible com-
In the
pound
a ferric
is
of decomposition of which
The platinum
is
is
concerning which
it
familiar to
by
supplied
compound,
platinous
oxalate, the
salt, viz., ferric
desirable to give a
can by cautious heating to 300
two atoms PtCl.2
chloride,
water, but
Just in the
is
and
platinite,
salt
is
insoluble
acid,
H.,PtCl 6
crystallizing,
K.2 PtCl 4
.
in
and the H.,PtCl 4
.
solu-
regarded as containing
of chloroplatinous
solution
,
be made to
same way the hydrochloric acid
chloroplatinic acid,
little
leaving platinous
chloroplatinous
tion of platinic chloride
chloride
last
C.
soluble in hydrochloric acid,
is
contains
solution
of. chlorine,
This
.
chloroplatinite,
Platinum tetrachloride, PtCl 4
further information.
give off
(p. 16).
the reduction of a
potassium is
you
mode
we
.
Now acid
on mixing a
with potassium
get potassium chloro-
In practice this salt
is
con-
362
THE CHEMISTRY OF PHOTOGRAPHY.
veniently prepared by reducing the chloroplatinate
with moist, freshly-prepared cuprous chloride
K On
2
PtCl 6
K
Cu 2 Cl 2 =
+
2
+
PtCl 4
:
2CuCl 2
.
and evaporating the solution the
filtering
crystals of the chloroplatinite separate out.
order
In
printing,
it
to
sized
first
is
paper
prepare
so
for
as
to
platinotype
sensitizing solutions from being absorbed,
then coated with a solution containing late
and potassium
acid with
oxalic
chloroplatinite,
thoroughly dried, and tive in the usual is
to produce an
image
and
ferric
made
sensitized
is
oxa-
slightly
paper
is
then exposed under a nega-
is
The
way.
chemical reduction, a film
The
acid.
the
prevent
effect of this
in ferrous
this
exposure
oxalate by photo-
image being imbedded
in
of potassium chloroplatinite, because the
latter salt
does not undergo any appreciable amount
of decomposition during the short exposure that is
necessary to decompose the
this point the
the process.
water but
is
platinum
Now
salt
ferric salt.
Up
to
has taken no part in
ferrous oxalate
is
insoluble in
soluble in potassium oxalate, so that
DEVELOPMENT OF PLATINOTYPE. on immersing the print (generally used
solved
out,
moment
the
at
a solution of this salt
the ferrous oxalate
warm)
and
in
363
of
its
is
dis-
solution
reacts with the chloroplatinite, reducing the latter
to the metallic state
3K
2
PtCl 4
:
= 3 Pt + + CFeC + Fe Cl 6 + 6KC1. 4
2
2Fe 2 (C A) 3
2
The amount
of ferrous oxalate produced on any
part of the ferric-coated surface ing,
proportional
is,
broadly speak-
amount of
to the
light
The high
reaches that part of the surface.
which lights
of the object, corresponding to the densest parts of the negative, thus correspond with the smallest
amount of
ferrous oxalate,
and the deepest shadows
of the object similarly give rise to the formation of the largest
amount of
ferrous salt, while the half-
tones produce an intermediate quantity of ferrous oxalate. in
ferrous salt,
immersed the
In this
in
manner the image
and the
latter,
is
impressed
when the
print
is
the potassium oxalate bath, reduces
chloroplatinite
to
that the ferrous image
a proportional extent, so is
replaced
by
its
platinum
THE CHEMISTRY OF PHOTOGRAPHY.
364
The potassium
equivalent.
oxalate solution thus
causes the image to be developed, and at the same
time partially fixes unaltered ferric solved out
by removing most of the
it
The
salts.
print with
by repeatedly washing the
dilute hydrochloric acid.
add that an image platinum
latter are finally dis-
is
It is
hardly necessary to
composed of
finely- divided
practically indestructible
by
all
those
agents which are capable of affecting a silver print.
A
number of
printing processes, and especially
the photo-mechanical methods, are based on the action of light (p.
23).
upon a
The change
film of chromatized gelatine
of colour undergone
solution of potassium or
when spread over a to light
ammonium
devised by
Mongo Ponton
in
dichromate
and exposed
surface of paper
was made use of
by a
a printing process
The property
in 1839.
possessed by a mixture of potassium dichromate
and gelatine of becoming insoluble the influence of light was
in
water under
first utilized in
process described in 1852 by
Fox
a printing
Talbot, and the
conversion of such a film into a coloured print by
AUTOTYPE PROCESS.
365
mixing the gelatine with a pigment was l
The
&55 by Poitevin.
effected in
nature of the chemical
change undergone by the chromatized gelatine was first
suggested by
has since been
Swan
in 1870,
and nearly all that
made known concerning
the photo-
chemical action of chromium compounds upon organic colloidal substances
is
due to the
1 gations of Eder published in iS/S.
investi-
A discussion
of the various processes depending upon the use of
chromatized gelatine would take us too
far
from
the domain of chemistry on the present occasion.
One
of the best
known
is
that
made
use of by the
Autotype Company, specimens of whose work have been forwarded for your inspection. as at present worked,
is
This process,
the outcome of a
method
of printing with pigmented gelatine which was successfully applied
by Swan
description will enable
in
1864,
first
and a brief
you to see how the action
of light upon chromatized gelatine
is
practically
utilized for the production of the coloured
prints
before you. 1
Ucber die Reactionen der Chromsaure itnd der Chromate auf
Gelatin, Gtimnri, Zncker, &>c.
Wien, 1878.
366
THE CHEMISTRY OF PHOTOGRAPHY.
In the autotype process the
and gelatine are mixture, and the
first
made
is
spread as a uniform film
over the surface of paper.
dry
is
The
placed under the negative which
The image
at this stage
when
sensitive film
printed from and exposed to
way.
homogeneous
being sensitized with
latter, after
potassium dichromate,
matter
colouring
into a
light in is
is
to be
the usual
invisible because
the insoluble portions of the film do not differ in
appearance from those portions which are unacted
upon
by
chromatized
dependent
Now
light.
gelatine
upon
the
the is
extent to which the
rendered
amount
of
insoluble light
is
which
reaches any part of the sensitive surface.
The
high lights of the object, corresponding to the darkest parts of the negative, therefore give the smallest quantity of insoluble gelatine, the shadows
of the object give the largest quantity, and the halftones an intermediate quantity of insoluble gelatine.
But the whole surface of the the negative
is
obviously rendered
insoluble, so that development
the back
film in contact with
of the film.
When
more or
less
must take place from
the printing operation
A UTO TYPE PROCESS. is
over,
paper
the
latter
is
therefore
support which
holds
367
transferred
it
during
to
a
develop-
ment, the surface which was in contact with the negative being held by the support, and the film
being thus stripped off the paper to which originally attached.
the film
is
now
On
treatment with hot water
that
is
to say the various por-
tions of the gelatine are dissolved
Where
to their solubility.
away according
the light has penetrated
most, there most of the gelatine will be the least light has been transmitted
left
by the
the smallest quantity of gelatine will be forth.
At
was
attacked from behind and develop-
ment takes place
so
it
this
stage the developed
consequently an image in a gelatine film.
relief
:
where
negative, left,
and
print
is
on the surface of
The developed
print
on being
again transferred to a white surface thus gives a coloured picture in which the depths of colour are proportional to the depth of pigmented gelatine
through which the white light has to pass
The high the
lights
thinnest
layers,
and
of
the
layers, the
object
correspond
[L].
to
shadows to the thickest
the half-tones to layers
of coloured
THE CHEMISTRY OF PHOTOGRAPHY.
3 68
gelatine of intermediate
thickness.
the print
colour being of course
is
determined gelatine.
formed,
its
the
by
This
pigment
is
mixed
mode
way
with
explanation will suffice to
intelligible the principle of the It
In this
the
make
of working.
perhaps necessary to add that the image
laterally reversed
by the processes of
is
transference,
but this can be obviated by the use of an inter-
mediate temporary support. this
modification
is
due
to
through whose kindness you tunity of seeing
how
At
Mr. will
introduction of J.
R.
Sawyer,
have an oppor-
the whole autotype process
practically carried out. 1
The
is
1
the conclusion of the lecture a demonstration of the process
was given by a representative of the Autotype Company.
APPENDIX TO LECTURE
A (p.
A glass plate
332).
is
IX.
coated with a film
of collodion salted with strontium chloride, and
bath.
One
is
red light) in a silver nitrate half of the plate (wet with the bath
then sensitized
(in
then immersed in a strong solution of sodium thiosulphate, and the other half in a very solution)
weak
is
solution of the
same
salt.
The
first
half of
the plate becomes quite clear, and the second half receives a coating of the dark insoluble double salt.
B
(p. 334).
A
design in metallic silver
duced, as in
p. 180.
is
pro-
The paper
is Experiment H, washed, immersed in a sodium thiosulphate bath, and then again washed with water. On brushing
over the design with a solution of mercuric chloride gradually disappears. The paper is then washed
it
in water
and torn into
five or six strips for sub-
sequent experiments.
C last
(p. 334).
A portion
experiment
is
of the paper used in the brushed over with dilute am-
B B
THE CHEMISTRY OF PHOTOGRAPHY.
370
monia, when the design again comes out dark on a white ground.
D
Another portion of the paper from
335).
(p.
Experiment B
ammonium
is
brushed over with a solution of
sulphide,
and another
strip
with sodium
sulphite.
E (p.
A solution of potassio-ferrous oxalate
335).
prepared by adding a cold saturated solution of ferrous sulphate to about 3 4 times its volume is
of a cold saturated solution of potassium oxalate. Another strip of the paper from Experiment B is
then brushed
over with this solution, when, as
before, the design comes out dark.
A
F (p. 336). solution of potassium cyanide is run into a solution of silver nitrate until the precipitate strip
from Experiment
this solution
G
formed
first
;
B
just is
dissolved.
Another
then brushed over with
the design comes out dark.
A
(p. 340).
is
silver
design
is
produced- as
in
Experiment B, and the paper is then torn into two strips, one of which is floated on a solution of cupric chloride and the other on a solution of ferric chloride.
H
In both cases the design gradually bleaches. solution of silver nitrate is added (p. 343).
A
to a solution of
albumen
in
water
in
order to show
the formation of a curdy precipitate. I (p.
by
351).
floating
it
Paper is coated with silver tartrate on solutions of potassium tartrate
APPENDIX TO LECTURE and
IX.
371
The experiment
silver nitrate alternately.
is
performed as described in the text.
A
painted on a sheet of paper with a strong solution of ammonio-ferrous sulphate thickened with starch paste. When the design J (p. 354).
is
design
nearly dry the paper
floated, face
downwards, on an ordinary gold toning-bath solution till the marking comes out of a brownish colour. The is
is
experiment succeeds better is
warmed
K
if
the gold
solution
before using.
(p. 361).
A
in
design
paper, as in
silver
is
produced on
The paper
is torn in Experiment one face and half, downwards, for portion floated, some minutes on a solution of platinic chloride.
B.
Both halves are then passed through a
dilute 'nitric
when the
unplatinized portion of the design is completely dissolved away, while the platinized portion is not attacked, showing that the silver of the design has, in the latter case, been acid bath,
replaced
L by
by platinum. The increase
(p. 367).
increasing the thickness
in the
depth of shade
of the coloured film
can be easily shown by placing a thin sheet of coloured gelatine in the path of the electric beam,
and then folding quadruple
it
so
as
to
get
double
thicknesses.
B B 2
and
INDEX.
INDEX. AUTHORS QUOTED. action of dyes, 306 alkaline development, 175
ABNEY,
gelatine-chloride emulsion,
345
UAGUERRE,
early experiments, *5 Draper, J. W., absorption and decomposition, 290
red-sensitive silver bromide,
294
spectrum photography, 253 spectrum on mixed haloids, 259 theory of orthochromatic action, 315
thiosulphate in developer, 1
action of dyes, 306 alkaline development, 176 action of chromates on gela-
EDER,
reversals in spectrum, 272 solarisation, 213, 216, 224
88
tine, 365 development of pressure marks, 191 different forms of silver bromide, 292 size of silver bromide particles
BAILEY and Fowler,
silver sub-
oxide, 42 Beccarius, darkening of chloride, 37 colours on Becquerel,
solarisation, silver
emulsion,
120,
theory
of
216 orthochromatic
action, 315 silver
chloride, 322
Bennett, ripening of emulsion, 121
214
solarisation,
in
124
weakening of image, 341 Eder and Pizzighelli, ammonia process of ripening, 129
image transference, 349 and Toth, intensifier, 337
Blanquart-Evrard, albumen dry plates,
92
calotype, 89,
FARADAY, forms of 90
and Sayce, collodion emulsion, 105 Bothamley, orthochromatic pho-
Bolton
tography, 309
CAREY LEA, development by mercury salts, 165 development of pressure marks, 191 ferrous
oxalate
tine, 364 improved process, 89 prin's on silver chloride, 83 Frankland and Lockyer, pressure and gaseous spectra, 301 Friedheim, silver suboxide, 42
GAUDIK, emulsion proposed
image transference, 349 photochromy, 322, 325 photosalts of silver, 59 i eduction of silver chloride light,
Fischer, silver subchloride, 40 Fox Talbot, chromaiized gela-
developer,
186
by
gold, 356 Farmer, weakening mixture, 34!
43
by, 105 Gehlen, photo- decomponition of
platinum salts, 359 Goddard, improvement of Daguerreotype, 88
INDEX. HERSCHEL, bleaching by
potas-
sium iodide, 209 colours on silver chloride,
Ponton, printing with chromates, 364
322 iron salts, 13 -
photo decomposition platinum salts, 359 sodium thiosulphate for ing, 84,
Hodgkinson,
33
W.
Poitevin, pigment printing, 365 positives on glass, 217 silver as a sensitizer, 150
of
READE, fix-
1
R., silver oxy-
chlcride, 56
Hunt, absorption of oxyren by darkening silver chloride,
J. B., gallic acid developer, 89 Riche, reduction of silver chloride by light, 44
Russell, Colonel, acid
development, 173 alkaline developer, 104, 106 collodion dry plates, 96 tannin process, 98
photo-sensitiveness of plati-
num JANSSEN,
salts,
359
solarisation,
Le Gray, collodion process, 92 waxed paper process, 90 Lermontoff, micro-galvanic deposition of silver, 163
Liebig and Regnault, pyrogallol developer, 1 66 R. L., gelatine emul-
sion, 115
Mansfield, ripening of emulsion, 121
Monckhoven,
Van.,
ammonia
process of ripening, 129
image on 349
silver
of light on silver chloride, 38 photography in spectrum,
SCHEELE, action
214
LASSAIGNE, bleaching by potassium iodide, 209
MADDOX,
and alka-
line
albumenate,
243 Schramrn, action of light on halogens and hydrocarbons, 29 Schulze, J. H., action of light on silver salts, 36 Scott Archer, collodion process, 92 mercuric chloride intensification,
334
Seebeck, colours on silver chloride,
322
Selle, intensifier,
337
Wharton, collodiochloride emulsion, 105 Spring, chemical change by presSimpson,
sure,
192
.
Muthman,
NIEPCE de
silver suboxide, St. Victor,
42
albumen
on
glass process, 91 colours on silver chloride,
Niepce, Joseph Nicephore, bitumen process, 27, 85
Starts, photochromy, 323, 325 Stas, molecular aggregation of silver haloids, 127
Stokes, use of quartz, 250 Stuart Wortley, ripening emulsion, 121
TATJPENOT, collodion dry
PIZZIGHELLI and Hiibl, platinotype, 360 Pliicker and Hittorf, pressure and gaseous spectra, 300 Pditevin, colours on silver chloride,
322
of
Swan, chromatized gelatine, 365 plates,
95 action of dyes, 304 function of sensitizer, 149
VOGEL,
plate in sodium solution, 204
sulphite
INDEX. and Eder, displacement of absorption-band, 313
Yogel
377
Wetzlar, silver subchloridc, 40 Willis, platinotype,
360
\Vohler, silver suboxide, 42
WARNERKE,
development
of
pressure marks, 191
Wedgwood
and
Davy,
early
photographic experiments, 82
287 and reversal, 278 by halogens, 299 intramolecular, 302 specific,
of
silver
Chlorine, liberation from silver chloride, 38
decomposition
of, ii
haloid
agents, 206 as a. substratum, 91
Albumen
343
of,
TO.
Chlorine-water,
molecule, 297 Accretion, development by, 163 Acid development, 158, 172 Acids, minerals, as destructive
formula
Albumenized paper, 342 Alcohol and ether as sensitizers,
Chloro-auric acid, 353 Chloroplatinous acid, 361
Chromates, photochemical decomposition of, 21 Chromatized gelatine, use of, 365 Collodion, chemical nature of, 93 dry plates, 95 plate, reversal in, 220 sensitizing of,
image
introduction
of,
104
process of ripening,
129
Astronomy, applications photography to, 134 Autotype process, 365 development in, 366
of
of,
salts,
Curve of
26
Blue, aniline, light transmitted by, 248
46
visual, of solar spectrum, 25 1 Curves for mixed hdloids, 259 Cyanine, action of, 310, 318 intensity,
DAGUERREOTYPE,
CALOTYPE
process, 89 Cellulose nitrates, 93 Chemical action, reversed, 201 force,
supposed,
spectrum, 245
Chemical photometry,
16, 19
by
light, 27 Colours of natural objects, 247 Concurrent reversal, 264 salts, photochemical decomposition of, 1 7 Cuprous oxychloride, 57 sal's, analogy with silver
Bleaching action of potassium iodide, 209, 211
Chemical
203
in,
introduced, 92 Colour, nature of, 239 Colouring matters bleached
Cupper
BlTUMENOUS substances, photooxidation
94
process, fading of invisible
75
Alkaline development, 166, 170, 186
Ammonia
silver
chloride, 322
SUBJECTS REFERRED ADSORPTION and decomposition,
on
colours
ZENCKER,
in
visible
fading of in-
image process, 86, 88
in,
sensitizer in,
202
150 development of, 156 and Decomposition absorption, 288 plate,
INDEX.
37 8
of
Deposition
silver,
micro-
Developer,
a
test.
189
microchemical
contributes to sensitiveness,
185 function
in solarisation,
of,
Developers, nature
143, 146 acid and alkaline of,
Development, compared, 172
alkaline introduced, 104
by ammonium
pyrogallate,
spectra, 301 Gelatine, action of light on chromatized, 23 as a sensitizer, 131, 153 chromatized, use of, 364 nitrate,
emulsion
with
silver
compared
with
of,
117
collodion emulsion, 119 emulsions, 113 plates, cause of longevity,
206
66
by ferrous oxalate, 186 by ferrous sulphate, 158 by mercury vapour, 156 of pressure marks, 191 Dissociation, photochemical, 24 Draper's law, 290 Dry plates, collodion, 95 lading of invisible image
Dyes,
acid as a sensitizer, 152 of pressure on
effects
compound
227
1
GALLIC Gases,
galvanic, 163
in, 205 effect of,
on photographed
spectra, 306 sensitizing action of, 305
ELECTROLYTIC
decomposition of silver bromide, 174, 175 Emission spectra, analogy with photographed, 301 Emulsion, collodion, 105 collodio-chloride, 345 gelatine-chloride, 345 mass washed, 112 Emulsions for printing, 345 gelatine, 113
ripening
of,
washing
of,
in, 121, 122 108, 123
Eosin, action of, 317 Erythrosin, action of, 310
FERRIC
oxalate, photochemical decomposition of, 16 Ferrous oxalate as a developer, 1 86 Ferrous sulphate as a developer,
.'5*
Fixing agents, 331 Fixing, explanation of, 331, 332 Fluorescence, 242 Fraunhofer lines, 249
of, 114 Gelatino-bromide emulsion, applications of, 133 causes of sensitiveness, 131,
properties
185 , paper, 346 plate, reversal in,
222
ripening of emulsion, 122 Glass, absorption of light by, 250 as a substratum, 91 coloured, light transmitted by, 249 Gold, colour of precipitated, 356 salts,
photochemical decomposition of, 20
reduction
of,
354
toning with, 352 Graphical representation of intensity, 251 Green, iodine, light transmitted by, 248
HALOGENS,
liberation of mixture
263 specific absorption by, 299 Hydrijdic acid, photochemical decomposition of, 1 1 Hydrogen as a sensitizer, 75 of,
and chlorine, action of on mixture of, 9 Hydroxyl, reversal
IMAGE,
in,
light
277
intensification of, 333
invisible or latent, 146
on albumenized
silver,
reversal of, 208
transference, 349
344
INDEX:
379
Images, positive and negative, 145 Instantaneous photography, 133 Intensification of image, 333 Intensifier, ferricyanide, 337 mercuric chloride, 333 potassio-silver cyanide, 336 uranium, 337
Molecular aggregation of silver haloids, 127
representa-
Nitric acid, function of, in collodion emulsion, 120
Intensity, graphical tion of, 251
visual and photographic, 243 Invisible image, destruction of,
198 by mineral acids, 206 by ozone, 205 nature of, 146 relapse of, 197 Iodine, removal of thiosulphate, by, 359
Iron developer, 158
development of, 143 photochemical reduc-
prints, salts,
tion of, 12, 14, 15
LATENT
image, nature
of,
146
Lead compounds, photo-oxida-
NATURAL
of,
OPTICAL change during
ripen-
ing, 291 Orthochromatic
theory
of, 311. 315 Orthochromatic
object
of,
action,
photography,
304, 309
Oxidation promoted by light, 25 Oxidizing agents, function of, in causing reversal, 223 increase of reversal by, 277 retardation of photo-decomposition by, 39 retarded reversal by, 281
Oxygen, absorption of, during darkening of silver chloride, 53
ferricyanide intensifier, 337 Light, components of white, 236
Ozone
nature of, 238 Longevity of invisible image on gelatine plates, 206
colours
Niepceotype process, 91
26
tion of,
objects,
247 Nickel sulphate, crystalline modification of, 8
as
a destructive agent,
205 reversal by. 284
PAPER, albumenized, 342 as a sensitizer, 75
Materia photographica, 6
Maximum
of decomposition in spectrum, 256
Mercuric chloride intensifier, 333 Mercurous salts, analogy with silver salts,
Mercury
46 development by,
salts,
photo-decomposition 24 Mercury vapour, development by, 156 Mineral acid, reversal in, 275, 281 165,
of, 1 8,
Mixed
haloids, sensitiveness of,
261 Moisture, accelerates photo-decomposition of silver chloride,
52
gelatino-bromide, 346 waxed, process, 90 Phosphorus, photophysical modification of, 8 Photochemical action, 7 Photochloride, photochromatic property of, 322, 325 Photochvomatic impression, 323 Photochromy, 321 Photographed spectra, analogy with emission spectra, 301 Photography, astronomical, 134 beginning of, 82 instantaneous, 133 Orthochromatic, 304, 309 scientific advancement of, 6 spectrum, 253 Photometry, chemical, 16, 19
INDEX. Photo-oxidation in spectrum, 269 Photophysical action, 7 Photo-reduction, nature of, 24 Photosalts of silver, 59
Refraction spectrum, characters of, 241 Relapse of invisible image, 197 Restrainers, nature of, 160
Pigment printing, 365
physical and chemical, 161, 185 Reversal and absorption, 278 by ozone, 284
Platinotype, 359
development of, 363 Platinum salts, photo-decomposition of, 20 Polymerisation caused by light, 28 Positives, direct on glass, 217 prints on paper, 342 Potassio-silver
cyanide intensi-
336 Potassium bromide, excess
by potassium iodide, 217 Reversal in hydroxyl, 277 in mineral acid, 275, 281 in mixed silver haloids, 264 in potassium bromide, 275 in potassium dichromate,
277
fier,
re-
quired in emulsion, 128 restraining action of, 168
in potassium
in spectrum, in spectrum
reversal in, 275
in,
277
sensitizer for gelatine,
366 iodide as a bleaching agent, 209, 211 as a reversing agent,
217 photo-oxidation reversal
by,
in
of,
25
spec-
trum, 271 permanganate, reversal in, 277 Preservatives, 98,
267 in
solutions,
272
chloroplatinite, 361 cyanide for fixing, 331
dichromate, reversal
permanganate,
277
no
Pressure marks, development of, 191 Printing process, albumen, 342 gelatino-bromide, 346 pigment, 365 Pyrogallol as a developer, 166
of chemical action, 2OI of image, 208 region of strongest, 269 retarded by oxidizers, 280
Reversing agents, direct action of, 283 Ripening by ammonia, 129 of emulsions, in, 123 of silver bromide a physical process, 123, 125 of silver haloids, optical
change during, 291 action of light on, 9 Sensitiveness, partly due to developer, 185 Sensitiveness, relative of silver haloids, 192, 195 Sensitizer, action of, in solarisa-
SELENIUM,
tion,
219
Sensitizers,
action
in
different
processes, 150
REDUCIBILITY of silver haloids, 193 Reduction product, destruction by iodine, 266 formed by chemical
method, 190 image formed of, 154 products, definition of, 49 organic silver, 351
theory of, 74, 78 Silver bromide, cause of molecular growth, 127 cause of sensitiveness, 258, 293 electrolytic decomposition of, 174, 175
oplical
properties emulsion, 124
in
INDEX. Silver
bromide photo-chemical decomposition, 57 red-sensitive form, 294 size of particles in 1 20,
ulsion,
em-
124
bromo-iodide, 264 chloride, action of solvents on darkened, 45
and
iodide, crystalline
modifications
of,
8
emulsions, 345
photochemical decomposition of, 37, 50 photochromatic property of, 321 transformation
into
bromide, 349 with magof, nesia, 63
compound
growth of deposit, 161, 171, 174 haloid
molecule, specific absorption by, 297 Silver haloids, absorption intramolecular, 302 action of dyes on local sensitiveness of, 309 action of spectrum on
mixtures of, 258 comparative action of light on, 76 different states'of molecular
aggregation,
127 heats of formation
3Si
Silver iodide,
image on, 150 photochemical decomposition, 58 nitrate as a sensitizer, 152 compound with albumen, 343 compound of, with gelatine, 117 oxychloride, supposed, 56 photosalts of, 59 print, composition of ima?e, 357 conditions of permanency, 358 fixing of,
ful,
42
Sodium
chloride as a fixing fgent, 83 chloro-aurate, 353 sulphite, plate exposed in,
204 thiosulphate as a fixing agent, 84, 331 in developer, 188
from
removal 359
optical change during ripening, 291
prints,
Solar spectrum, curve of visual intensity in, 252 fixed lines in, 249
212
Solarisation, 208, of, 82
357
salts, actions of light on, 35 existence subchloride, doubtful, 40 suboxide, existence doubt-
favoured by preliminary exposure, 227 function of developer
in,
order of darkening by light, 76 order of reducibility,
function
]93 of order sensitiveness,
in collodion plate, 220 in gelatino-bromide plate,
79 photo
phases
227 of
sensitizer
in,
219
222 -
decomposition
of, accelerated, 71 relative sensitiveness
of, 192,
when
mixed, 261, 265 spectrum photographed on, 254
214, 220
by
oxidizing
agents, 223
retarded by reducing agents,
195
sensitiveness
of,
promoted
277 Spectra of gases, effects of pressure on, 301
photochromatic, 324
INDEX. action
Spectrum,
of
tures
of,
silver
on mixhaloids,
Toning-bath, chemistry 355
of,
353,
258 characters of, 240 colours of, 238 displacement of absorption-
band
in,
maximum in,
URANIUM
313
prints,
337 development of, 144
salts,
photo-decomposition
of decomposition
of,
inlensifier,
19
256
normal, 241
photographed on loids, 254 photography, 253
silver ha-
photo-oxidation .277
in,
reversal
iodide
by in,
sity,
potassium
271
243
WASHING for, 97,
Water,
of dry plates, reason 08, 122
1
decomposition
by
chlorine, II
Waxed
245 Sulphur, photophysical modification of, 8
Thallous
by, 156 Visual and photographic inten-
269,
reversals in, 267, 272 supposed chemical force in,
TANNIN
VAPOUR, development
as a preservative, salts,
silver salts,
46
analogy
paper process, 90 Weakening agents, 339, 341 White light, composition of, 236
98 with
ZINC
selenate, crystalline fication of, 8
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