Classical Dynamics and Its Quantum Analogues (Lecture Notes in Physics)

Lecture Notes in Physics Edited by J. Ehlers, Menchen, K. Hepp, ZUrich R. Kippenhahn, MQnchen, H. A. Weidenmeller, Heidelberg and J. Zittartz, K61n Managing Editor: W. BeiglbSck, Heidelberg

110

David Park

Classical Dynamics and Its Quantum Analogues

Springer-Verlag Berlin Heidelberg New York 1979

Author David Park Department of Physics Williams College Williamstown, MA 01267/USA

ISBN 3-540-09565-9 Springer-Verlag Berlin Heidelberg N e w Y o r k ISBN 0-387-09565-9 Springer-Verlag New York Heidelberg Berlin Library of Congress Cataloging in Publication Data Park, David, 1919Classical dynamics and its quantum analogues. (Lecture notes in physics; v. 110) Bibliography: p. Includes index. I. Dynamics. 2. Mechanics.3. Quantum theory. I. Title, II. Series. QC133.P37 531'.11 79-23440 ISBN 3-540-09565-9 This work is subject to copyright. All rights are reserved, whether the whole or part of the material is concerned, specifically those of translation, reprinting, re-use of illustrations, broadcasting, reproduction by photocopying machine or similar means, and storage in data banks. Under § 54 of the German Copyright Law where copies are made for other than private use, a fee is payable to the publisher, the amount of the fee to be determined by agreement with the publisher. © by Springer-Verlag Berlin Heidelberg 1979 Printed in Germany Printing and binding: Bettz Offsetdruck, Hemsbach/Bergstr. 2]53/3140-543210

TABLE OF CONTENTS

I.

2.

RAYS

OF L I G H T . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

i.i

Waves,

Rays,

1.2

Phase

Velocity

1.3

Dynamics

of a W a v e

Packet ..........................

1.4

Fermat's

Principle

of Least

1.5

Interlude

1.6

Optics

ORBITS

i

and O r b i t s . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and

on the

Group

1

Velocity ...................

Calculus

8 13

T i m e . . . . . . . . . . . . . . . . . . . 17

of V a r i a t i o n s . . . . . . . . . . . . 19

in a G r a v i t a t i o n a l

Field ....................

OF P A R T I C L E S . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

27 58

2.1

Ehrenfest's

Theorems ...............................

38

2.2

Oscillators

and P e n d u l u m s . . . . . . . . . . . . . . . . . . . . . . . . . .

41

2.3

Interlude

2.4

Driven

on E l l i p t i c

F u n c t i o n s . . . . . . . . . . . . . . . . . . . . 46

2.5

A Driven

2.6

Lagrange's

Equations ...............................

59

2.7

The

Pendulum, ...............................

64

2.8

Planets

and Atoms . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

68

2.9

Orbital

Oscillations

2.10

Orbital

Motion:

Oscillators ................................. Anharmonic

Double

Oscillator .....................

Other

2.12

Bohr

Integral

and

Orbits..77

2.13

The

Forces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Orbits

and Q u a n t u m

Principle

53

and S t a b i l i t y . . . . . . . . . . . . . . . . . 75

Vectorial

Hyperbolic 2.11

50

Mechanics:

of M a u p e r t u i s

and

82

D e g e n e r a c y ..... 83

its

Practical Utility..85

3.

4.

N-PARTICLE

SYSTEMS .......................................

3.1

Center-of-Mass

3.2

Two-Particle

3.3

Vibrating

3.4

Normal

3.5

The V i r i a l

HAMILTONIAN

89

Theorems ............................

89

Systems ...............................

96

Systems ..................................

97

Coordinates ................................ Theorem ................................

DYNAMICS ....................................

4.1

The

Canonical

4.2

Magnetic

4.3

Canonical

4.4

Infinitesimal

4.5

Generating

4.6

Deduction

Equations ...........................

Forces . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Transformations

.........................

Transformations

Finite

.....................

Transformations

106 iii iii i15 121 128

from

Infinitesimal of N e w

i01

Ones..135

Integrals ........................

139

IV

5.

4.7

Commutators

4.8

Gauge

and P o i s s o n

B r a c k e t s . . . . . . . . . . . . . . . . . . 142

Invariance ..................................

THE H A M I L T O N - J A C O B I

THEORY ..............................

5.1

The H a m i l t o n - J a c o b i

5.2

Step-by-Step

5.3

Interlude

on P l a n e t a r y

5.4

Action

the G e n e r a t o r

5.5

Jacobi's

5.6

Orbits

5.7

Coordinate

5.8

Curvilinear

5.9

Interlude

145 151

E q u a t i o n . . . . . . . . . . . . . . . . . . . . . . 151

Integration

of the H a m i l t e n - J a c o b i Equation..IS5

Motion

in G e n e r a l Relativity...159

6.

7.

8.

ACTION

AND

as

Generalization

of a C o n t a c t T r a n s f o r m a t i o n .... 164 ...........................

166

Integrals ..............................

171

Systems ................................

177

and

Coordinates ...........................

on C l a s s i c a l

Optics .....................

PHASE ........................................

6.1

The Old Q u a n t u m

6.2

Hydrogen

6.3

The A d i a b a t i c

6.4

Connections

6.5

Heisenberg's

6.6

Matter

6.7

Construction

Atom

Theory ............................

in the O l d

Quantum

Quantum

Quantum

Waves ...................................... Function ...................

THEORY OF P E R T U R B A T I O N S . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . and P e r i o d i c

192

202

M e c h a n i c s . . . . . . . . . . . . . . . . 206

Mechanics ....................

of a W a v e

192

T h e o r y ........... 200

Theorem .............................

with

180 185

7.1

Secular

7.2

Perturbations

7.3

Adiabatic

7.4

Degenerate

7.5

Canonical

Perturbation

7.6

Newtonian

Precession ..............................

209 219 222 229

P e r t u r b a t i o n s . . . . . . . . . . . . . . . . 229

in Q u a n t u m

M e c h a n i c s . . . . . . . . . . . . . . . . 232

Perturbations ...........................

236

States ............ .....................

240

Appendix:

Time A v e r a g e

THE M O T I O N

OF A R I G I D

Theory .....................

of r n in K e p l e r

248

O r b i t s .......... 255

BODY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

Velocity

245

Angular

8.2

The

8.3

Dynamics

8.4

Euler's

8.5

The

8.6

Quantum

8.7

Spinors ...........................................

289

8.8

Particles

298

Inertia

and M o m e n t u m . . . . . . . . . . . . . . . . . . . . .

257

8.1

Tensor ................................

in a R o t a t i n g

Coordinate

S y s t e m .......... 262

Equations .................................

Precession

of the E q u i n o x e s . . . . . . . . . . . . . . . . . . .

Mechanics

with

of a R i g i d

257 260

Body .................

Spin ...............................

268 275 283

9.

CONTINUOUS 9.1

SYSTEMS ......................................

Stretched

Strings .................................

9.2

Four M o d e s

9.3

Example:

A Plucked

9.4

Practical

Use

of V a r i a t i o n

9.5

More

One

Dimension ...........................

9.6

Waves

9.7

The M a t t e r

9.8

Classical

Than

of D e s c r i p t i o n . . . . . . . . . . . . . . . . . . . . . . . . . String ........................

302 304 311

P r i n c i p l e s . . . . . . . . . . . . . 313

in S p a c e . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . Field .................................. and Q u a n t u m

302

Descriptions

316 322 327

of N a t u r e ...... 332

BIBLIOGRAPHY . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . . .

336

INTRODUCTION The short Heroic age of Physics that started in 1925 was one of the rare occasions when deep considerations application in carrying out physical microphysics

of philosophy found

calculations.

In many parts of

the calculations have now become relatively straight-

forward even if not easy, but most physicists

seem to agree that some

difficulties of philosophical principle remain to be resolved.

This

situation has produced a great effect on the way people think and write about quantum mechanics,

a sort of gingerly approach to the

fundamentals and a tendency to emphasize what 50 years ago was new in the new theory at the expense of continuity with what had come before it.

Nowadays

someone who looks into the subject is more likely

to be struck by unexpected similarities between quantum and classical mechanics

than by contrasts he has been lead to expect,

and the main

purpose of these notes is to bring out the similarities.

It is

intended as a text in classical mechanics for readers who know a little classical and quantum mechanics but not very much of either, to teach them more of each and to emphasize the continuity between them. atom,

Most undergraduates for example,

I know are more familiar with the hydrogen

than with its planetary counterpart,

and since I

believe that historically and conceptually classical dynamics backbone of physics,

is the

I have treated planetary motion in some detail.

Since the relation between wave optics and ray optics is much the same as that between wave mechanics and particle orbits,

it has been

possible to do quite a lot of optics at the same time. Classical mechanics,

quantum mechanics,

and optics--the scope is

so vast that there has to be a principle of selection. mentioned those parts of elementary quantum mechanics the most fundamental interest and utility, of classical mechanics subjects

I have that are of

and explained those parts

that relate to them and illuminate

them.

The

in optics are pretty well determined by those choices.

There are no insects of the kind that walk on a weightless rod, no nonholonomic constraints,

no nonconservative

But the standard methods are h e r e - Lagrangian, Hamilton-Jacobi

together with their relations

spinning

forces even.

Hamiltonian and to quantum mechanics,

and considerable discussion of methods of exact and approximate solution and the role of invariance. theory by seeing how it works, in general relativity,

Believing that one learns a

I have included several calculations

including the deflection and retardation of

light by the sun and the precession of planetary perihelia.

Since

the relativistic precession must in practice be disentangled from the

VL11

precession produced by interaction with other planets, this as an example of classical perturbation quantum analogues, two particles, systems

but Chapters

of particles,

of continua.

including solid bodies,

analogy with the classical Inevitably, and made excuses selection taste.

Guided by the

deals with one or

3, 8, and 9 refer to the motions

The quantum mechanics

also a discussion

theory.

most of the classical mechanics

I have used

and to the mechanics

of rigid bodies

theory and

contrasts

of the roles of spinors

is treated

are noted.

in

There is

in the two theories.

I have discussed parts of physics

that appeal

for omitting parts that I find boring.

is finally not a matter

of

to me

Thus the

of logic so much as of personal

I trust there will be a few who share it.

The discussion Parts of elementary in many texts.

of classical mechanics

is fairly self-contained.

quantum mechanics not explained here are available

To avoid appearance

usually given references

of self-promotion

to my own book

I have not

(Park 1974) I , but all are to

be found there. I should mention a debt of gratitude once anyhow: mechanics problems

that many will recognize

to the book in w h i c h Max Born

(1927)

at

set classical

in order so that he could make a final assault on the of the old quantum theory.

But the assault was never made,

for the situation changed even as the book appeared, us more of the old mechanics

it sought to supersede

and so it tells than of the theory

it was intended to advance. There are a number of historical fewer than there should be.

tists who dared to think cosmically, after Newton's truth.

and in a little over a century

by people who aspired to nothing

They united mathematical

beauty with philosophical Perhaps

precision,

thanks to Karen Brownsword

they were right. for undertaking

difficult typing job at a time when she had more think about. David Park Williamstown,

i

out of

less than eternal

that there were no limits to the future of a civilization

which could produce such work. Special

though probably

death the science of dynamics was constructed

marble and bronze, and believed

references,

Kepler and Newton were the first scien-

The bibliography

is at the back of the notes.

a long and

important things

Massachusetts

to

CHAPTER

i.i

Waves,

I

RAVS OF LIGHT

Rays, and Orbits

Following the historical order of ideas is usually a good way of introducing people to physics, but the historical order is not the logical order.

If it were,

there would be no room for discovery,

since each new development would merely follow deductively from the preceding ones.

New discoveries usually involve radically new ideas

not implicit in what went before,

and deductive connections, when

they can be made at all, must be made backwards. the formulas of relativistic mechanics

You cannot derive

from those of Newton.

can derive Newtonian formulas from relativistic

You

ones by taking a

low-velocity limit, but even this is not a derivation of Newtonian physics,

since that physics takes place against a background of

absolute space and time which Einstein abandoned. contains a lesson:

This example

We may be able to derive the equations of an

earlier theory from those of a later one, but to recapture the theory itself requires

imagination and scholarship.

In this book we are going to establish mathematical between classical and quantum mechanics, optics.

The approach will be to consider classical mechanics as a

limiting case of quantum mechanics, case of wave optics. where necessary, anyhow.

connections

between ray optics and wave

and ray optics as a limiting

The conceptual background will be discussed

but the reader will be fairly familiar with it

One result of this approach will be the revelation that

classical and quantum theory are not so different conceptually as one thinks at first exposure.

Quantum mechanics

content and classical mechanics

is not:

is probabilistic

in

no amount of mathematical

fiddling will cross that gap, but it is often more conceptual than practical. The other transition,

from waves to rays,

is similar in many

ways except that it has largely escaped the rhetoric of twentiethcentury physics.

Of course the question of quanta is introduced

here if we claim that rays are the orbits of photons.

We are then

in the situation that light waves are classical and rays are quantum, while the orbits of particles are classical and their waves are quantum.

Therefore building a bridge between waves and rays will

be anti-historical

either for light or for matter, whichever way we

progress. One of the useful by-products

of this study will be to see

whether there are any useful concepts that can be isolated and

distinguished

in the dichotomy classical-quantum.

We shall discuss

the question later in more detail, but for the moment

it may be

instructive to consider de Broglie's relation ~p = h connecting the wavelength and momentum of a beam of electrons. "classical

The

limit" of such a relation is the one in which h is

replaced by zero. but only that,

This does not mean that h is treated as a variable,

in ordinary units,

either % or p is much larger than h.

There are, in the limit, two possibilities.

Either % is large and p

is effectively zero or p is large and ~ is effectively

zero.

That is,

either the theory contains the word wavelength but not the word momentum or the other way around. are perfectly familiar: mechanics.

In the quantum theory one sometimes speaks of momentum

and w a v e l e n g t h To b e g i n point the

in the at

use of Planck's just

the

varying

index

constant.

us r e c a l l

that

w a v e s and l i g h t era;

they

Further,

from a historical

rays

both

can be d i s c u s s e d

as we s h a l l

see

from SchrSdinger

construction

of light

rays

in

waves

belong without

(1.S), is

to the

the

formally

i n a medium o f

of refraction. condition

for

o f t h e wave s h a l l

and any l e n s e s the

light

classical

same as t h e

wave-length

let

of Newtonian orbits

A necessary

a nd i f

least,

of the

construction

same s e n t e n c e .

our development,

of view,

physics

Both kinds of theory without h

examples are classical optics and classical

or holes

it

any s u c h

construction

be " s m a l l ; "

goes through

index of refraction

varies,

that

is,

is the

that

a r e many w a v e l e n g t h s it

varies

the

beam i t s e l f

relatively

wide, little

o v e r one w a v e l e n g t h :

I~'~'l <<

n

~

3n I << I-~z

kn

k =

=

k/~s

(l.la)

1/~

(1.1b)

The condition on the width of the apertures makes consider diffraction effects. our approximation later.

Condition

It excludes a priori using this theory to

discuss refraction at an air-glass formulas

interface, but we shall find

that apply to this case also.

a single angular frequency m. Fourier superposition.

it unnecessary to

(i.i) will be built into

We shall consider waves of

Other signals can be represented by

Waves

a n d Rays

In explaining how light is affected by lenses and mirrors, draws rays diagrams, faces

(Prob.

1.1).

one

lines which are straight except at the interIf the medium is one in which the index of

refraction varies with position,

the straight lines become curves and

images are distorted--an example is that on clear evenings the sun's disc may appear much elongated just before sunset.

Our first task is

to calculate the rays in such a case, starting from the differential equation of the wave. A component of the electromagnetic

field satisfies

d'Alembert's

equation

c~

-

~t 2

=

where c is the speed of light in a vacuum and where the wave velocity has been written as c/n.

SchrSdinger's

energy to express what n expresses

2--# v

Now a s s u m e

that ¢ ~ e

-i~t

-

equation uses potential

for light,

v(r)¢

+

i~

=

(l.2m)

o

We find for light (0 2

V2¢ + ~ n 2 ( ~ , r ) ~

= 0

( I .3~)

and for matter

2m [E - V ( r ) ] #

= 0

(E = ~m)

(1.3m)

These are of the form V2~ + K2Cr)~ = 0

(1.4)

with

~(r)

= ~ nC~,r)

or

~m [~(~) ~ ~-~

_ v(r)]}½

in which

(until V becomes

produces

the same effects as a varying index of refraction.

larger than E) a varying potential

(1.s) energy

To solve

(1.4) we make the short-wavelength

in quantum mechanics

approximation

that

bears the name WKB (Wentzel-Kramers-Brillouin)

but was in the literature well before

We write the solution

that. I

as ¢(r) = a ( r ) e i S ( r )

where a ,

the amplitude,

phase, varies quickly in a moment),

varies

slowly and the term containing

(we shall establish

and both are real. V2a

(1.6)

+ 2iVa.V8

criteria

Putting

+ iaV2s

(1.6)

into

- aCV8) 2 + KXa

We have traded the complex quantity

s, the

for these words

=

(1.4) gives 0

¢ for two real ones.

Separating

real and imaginary parts gives V2a

- a(Vs) ~ + K2a

2Va.V8

In the first equation,

+ aV28

=

=

(i.7i)

0

if a varies much more slowly than 8, the first

term becomes small compared with the other two. drop

it, postponing

(l.7r)

0

the m a t h e m a t i c a l

We shall therefore

justification

until the end of

this section. The remaining

terms of (l.7r)

(Vs) 2 while equation

(1.7i)

give

=

Equation

(1.8)

(I.8)

= 0

(1.9)

is ?.{a2?s)

in Chapter

K 2

is one of the central

5 we shall see why:

equations

it formulates,

in this book,

exactly,

dynamics of a particle.

But suppose t h a t

space the wave resembles

a plane wave with a propagation

that

is essentially

constant.

* For example,

J. Liouville,

in some small region of

The wave here propagates

@ _~ e / ( k . r

and

the Newtonian constant

k

like

- ~t)

J. Math. pures appl. 2, 16 (1837).

(I.i0)

and B in (1.6) plays the role of k.r. k

= Vs

,

Taking the gradient, we have

k2 =

(Vs) 2 = K2

(1.11)

so that Vs gives the wave's wavelength and direction of propagation. The wavelength of any wave satisfying our equations

is determined by

(1.5), and its direction is determined not by any equation but by the initial conditions:

where the wave comes from.

Many results flow from (i.Ii).

The quanta of a wave of the form

(I.i0) have energy ~m and momentum ~k. momentum of a particle

From (i.Ii) and (1.5)

the

is

p

=

~K

=

{2rn[E

~~rn -+

V(r)

(1.12)

V(r)]} ½

-

so t h a t

Of course,

= ~

(I 13)

the last equation looks like Newtonian mechanics,

but to

see the real connection we must remember carefully the way it was We assumed a wave that is approximately plane in a small

derived. region,

and relations like the last three refer only to that region.

The connection with the Newtonian mechanics

of a particle is

established only if the region is part of a larger wave packet,

and

the potential Y(r) varies only slightly over the entire wave packet. (Otherwise,

different parts of the wave packet would go off in

different directions,

see Fig. I.i).

.a.~ .V(x)

Then p is the momentum

~,~

f

,,,..

"'

Figure i.i Arriving at a sudden discontinuity of the medium, a wave packet splits. It is difficult to understand this in terms of the behavior of a particle.

associated with the wave packet and V(r) is evaluated at the position of the wave packet. mechanics:

Equation

(i.i) also has a meaning within quantum

if the system is in a state of frequency~ and energy ~ ,

a detector placed at r will detect particles momentum.

Note that Planck's

constant

having the given

is no longer present

in

these relations. 2 The

First

Term of

(1.?r).

To end this section,

we return to the justification

the first term of (l. Tr).

Since we are requiring

the wave packet be moving axis parallel dimension.

in the same direction,

to that direction

The relation

to be approximated

a

and the approximation

consists

dx 2

fractional

in assuming

la (2--xx) d8

<<

(1.6) we specified

than the term containing

s.

of

we can take the x

the calculation

to one

is

rdS~ s dsa ~dxJ = K Z a + dx2

d2~

In writing down

and restrict

of dropping

that all parts

This

that

2

(I.14)

that

a varies more slowly

is expressed

in terms of the

change of the functions:

<<

e

~-~ e

or

Differentiating

again gives

It is also natural to ask what is the momentum of a photon passing through a medium of index of refraction n. But since the field is continually in interaction with the medium, only the total momentum of field and medium is significant, and the a t t r i b u t i o n of part of it to the light is to some extent arbitrary. See J.A. Arnaud, Am. J. Phys. 42, 71 (1974).

7

d 2a

dx 2 <<

d~xdS ~

In this o n e - d i m e n s i o n a l

d2s + a

case,

(i.7i)

da ds

is

d2s

so that d2a

and u s i n g (1.15) again gives

Ideal d~2,<< w h i c h is (1.14), and was

aCdS) ~ I d~ I

to be shown.

Finally, we note that

(1.7i)

can be w r i t t e n as

V'(a2Vs) If we w r i t e ¢(r)

in the form

(1.6)

=

o

it is easy to see that

a2Vs = Im(~*V~)

The

expression

mechanics, reduces the

and simply

optical

case

on

the

right

in

the

steady-state

regime

to

the

conservation

of particles.

is,

of

is

course,

the

current

vector we

are

in quantum discussing, The

(I.17i)

significance

in

similar.

Comments Since K is p r o p o r t i o n a l

to ~-i, we see that the a p p r o x i m a t i o n of

small W and large K can be viewed, variable,

even though ~ is not really a

as an a p p r o x i m a t i o n of small W.

For any ~,

it fails close

to a point at w h i c h E - V = 0 and K therefore vanishes. are called turning points,

Such points

b e c a u s e they correspond to those points

in c l a s s i c a l m e c h a n i c s at w h i c h a p a r t i c l e reaches the end of its allowed t r a j e c t o r y and reverses uses an a p p r o x i m a t i o n

its m o t i o n

(See Sec.

2.2).

Here one

for small K, and finds ways to join it to the

large-K form in the i n t e r m e d i a t e region

(Merzbacher 1970,

Ch.

7).

The subject belongs to quantum mechanics,

and we need not pursue it

here. Finally, we note that what has been proved is that a wave packet, within this approximation,

has certain properties

particle as described by Newtonian mechanics,

in common with a

and we shall see in the

next section that the analogy can be pressed much further.

But this

should not be understood

to mean that a Newtonian particle is the same

thing as a wave packet.

Most students of elementary quantum mechanics

go through a period of believing that it is, not understanding the quantum-mechanical

description

Newtonian mechanics has nothing statistical

about it.

have entirely different domains of discourse,

quantum mechanics

(for

wave p r o d u c e s

particles

is

the

inferred,

nothing

t o do w i t h

Problem

I.I.

example Park 1974, familiar and that

effects

The two theories

and all correspondences

between them must be expressed very carefully.

plane

that

is purely statistical and that

§§8.8,

In fact, one finds in

9.5)

that

a uniform

from which the presence

wave p a c k e t s

and particles

of

have

each other.

For practice and review,

draw the ray diagram that

explains the formation of a real image by a converging lens. Problem

1.2.

Draw the ray diagram that explains the formation of a

virtual image by a converging lens used as a magnifying glass. Problem

1.3.

Draw the ray diagram that explains

the formation of a

virtual image by a convex mirror. Problems

1.4,

1.5,

1.6.

For the three cases above, explain the image

not by drawing rays but by drawing a spherical wavefront leaving the object, encountering the lens or mirror, and leaving it as another spherical wavefront having a different center. Problem

1.7.

Prove by elementary vector analysis that the propagation

vector k defined in (i.ii)

is directed perpendicular

i.e. to a surface of constant s.

to the wavefront,

(If the corresponding ray and wave

diagrams requested in the preceding problems are compared,

the

relevance of this result will be apparent.) 1.2

Phase Velocity and Group Velocity In the last section we showed that in the short-wavelength

approximation a wave packet follows a certain path and that, if it is a matter wave, the relation between momentum and energy is the same as in particle mechanics.

In the next section we shall show how to

calculate the paths of light rays and particles.

This section concerns

the rate at which wave packets move,

and leads to considerations

with

w h i c h many readers will already be familiar. In the region valid,

choose ¢

in which, of k.

in which the plane-wave

the x axis parallel :

e i(kx-mt)

in general,

The phase

e i¢

=

¢

k is a function

¢ is constant

approximation

(i.i0)

to the local value of k. =

kx

-

is

Then (1.16)

mt

of m, that is, m is a function

for values of x and t satisfying

kx = ~t + const. or x = ~ t + const. The points

of constant phase

therefore move at a rate

v¢ This

is the phase

velocity.

:

:

m/k

Xw

(i.17)

If we try it for light we get m

c

(1.18)

v¢ = ~ = n(r,m) by

(1.5),

and this

is the usual definition

of the index of refraction.

For matter, thi~ is

~m E v~ :~-~-: F

For a free particle,

for which E = p2/2m,

same as the particle

velocity.

since one cannot

and troughs

like that.

measuring c also m o d u l a t e d

the wave,

precise measurements,

Make

of a de Broglie wave,

In fact,

(see Prob.

of the

the old ways of

and Michelson,

had to be reminded

but the group velocity 3 Vg later.

which is not the

and we must follow instead a m o d u l a t i o n

wave--a pulse or something

To evaluate

v¢ = p/2m,

The reason for this is well-known:

follow the crests

v@ is unobservable,

(1.19)

making

the first

that he was measuring

not v¢

i.Ii).

Vg, we use a construction

that will be useful

a wave packet out of components

of roughly the same

The idea of group velocity goes back to W. R. Hamilton, Proc. Roy. Irish Acad. 1, 267, 349 (1839). For a careful discussion see Brillouin 1960.

10

wave n u m b e r k, ~(x,t)

where A(k)

= ] A(k]ei¢dk

is as in Fig.

m = kx

-

(1.20)

~(k)t

1.2.

~

Ck) k

k Figure 1.2

In general,

A wave packet composed of momenta centered at ~.

the rapid oscillations

of the integrand will cause

integral

to have a very small value,

with k.

In a matter wave,

is as in Fig.

1.3a,

~ varies

the

slowly

for example

=

This

but not where

kx

- ~k2

t

2m

and e i~ varies

as in Fig.

1.3b.

e~

k

Figure 1.3

t k,

A

AR,

vuv

The phase varies most slowly with k at the point kl, determined by d~/dk = O: x - ~kl/m = O.

If kl, where where A(k)

._IA/ \ I/V

the phase varies most slowly,

is large,

coincides with the value

the integral will give an appreciable

value

for

11

the wave packet.

This occurs where

(1.21)

x = - - t m

and the velocity dependence generally,

v of the center of the group now has the right g on the average m o m e n t u m of the group, v = i~/m. More g the point of stationary phase occurs where

d--~=x

-

t=O

whence

ug This can also be written

d0~ =

d--~

(1.22)

as ~d~ dE vg =~-~= d--F

If there

is a conservative

(1.23)

field of force the energy can be written

as a function of coordinate

and momentum;

hamiltonian

(see Ch. 4), and

function

H(p,x)

then it is called the (1.23) becomes

~H

vg = 3-~ an equation we shall encounter

again. V

which

is the particle velocity The index of refraction

physical

grounds)

g

If H = p2/~m + V(x),

this gives (1.24a)

= p/m

in Newtonian physics.

of a medium

as a function

velocity we write ~ = c k / n ( ~ ) ,

c dk

(1.24)

is usually

of the frequency.

given

(on

To find the group

so that

ckn, d~

(n,

dn

and

vg

d~ ~

a/n 1 + ckn'/n 2

v~ 1 + co dn n d~

(1.25)

12

Example

The relation between m and k for waves

1.1

h 4Landau and Lifschitz

1959,

in water of depth

§12) is

= k [ ~ tanh kh] ½

Thus t h e p h a s e v e l o c f t y

is

v¢ = [~ t a n h kh] ½

In shallow water,

kh << I,

this is

(k~ - ~I k3~ 3 + . . . )

= ~[~

]½ = ( g h ) ½ (k -

k3h 2

6

+ "'')

so that when kh << I,

vo

=

I

49'~) ½ 41 - ~ k2h

2

1

~,g = --(gK) ½ 41 - ~ - k 2 ~

+ ...),

2

+ ,..)

or

v o = (gh} ½ 41 - ~%~e + . . . )

,

v

= ( g h ) ½ 41 - ~ - ~ +

and waves move more slowly as they reach the shore.

...)

In deep water,

t a n h kh = I and ~ = 4gk) ½. Thus when kh >> I,

v¢

--

(g/~)~

Long waves move faster, groups

are visible,

a pool and watch Problem

1.8

Problem

1.9

one can produce

depends

-~

½(g/~) ~

and since in water both phase waves a splash by dropping through

of a given frequency,

and wave

a stone into

the group.

show qualitatively

how

on the depth.

When sound passes

electromagnetic

vg

the phase waves passing

For waves

the wavelength

,

down a pipe of square cross section or

waves pass through a square waveguide

of side a, the

propagation

in the lowest mode is governed by the relation

and Lorrain

1962)

4Corson

13

~2

Find v 0 and

Vg and

= 02(k2

particle

of relativity

The relation between

1.10

272 a2 )

note the simple relation between them.

any conflict with the results Problem

+

in special relativity

Is there

theory?

energy and momentum of a free

is

E 2 = C 2 p 2 + (md2) 2 where m is the rest mass.

With E = ~

and p = ~k,

same questions

as

in the preceding problem. Problem

Careful m e a s u r e m e n t

1.11

of w a v e l e n g t h 299707.2

± 0.8 km s -I n =

1 +

m e a s u r e d value

a speed of light equal to

The index of refraction

(27259.9

w h e n k is given in ~m. one forgets

using an interrupted beam of light

X = 0.589 ~m in air yields

~-2

+ 153.50

What correction

in order to find c?

+

of air is l -~) x 10 -e

1.317

must be applied to the

What correction

that group velocity was measured

is obtained

and corrects

if

only for

phase velocity? Problem

A slow electron moves with velocity

1.1~

region enclosed by a metallic K as in (1.5),

1.3

Dynamics

I00 ms -I through the

shell at a potential

of 5 x 106V.

With

find v~ and Vg.

of a Wave Packet

At this point in the discussion, particle mechanics

someone who knew nothing

would have enough information

ing it.

In one dimension,

centered

at x, and ask how p changes with time.

because p = m V g .

we can apply

dV

dz

m

to a wave packet

d p_ =

m

dt

p dx dt = -~ 2-~ vg = -2-~x

In more interesting

parallel

to the momentum,

argument

is instructive

we have

dV

(1.13)

of

to begin reconstructSince E is constant,

dV

cases, when the force is not

to think a little harder but the

and illustrates

the importance

of the phase

from left to right in Fig.

1.4 w h i c h is

velocity. Consider a beam moving deflected by some lateral of constant further

inhomogeneity

s to stay in phase,

than the inside,

in K(r).

For the surfaces

the outside of the beam must move

14

dv~

where

v~(p)dt

v~(p + dp)dt

p

p + dp

p is the radius

v~(p)

+ dp dp

p + dp

of curvature

Solving

of the path.

this for

i/p gives 1 p

Since by

(1.18) v ¢

=

1

~v~

v~ ~p

~p

~/K with ~ constant, this is ~ P

Figure 1.4

~inv~

31nK 3P

Surfaces of constant s in a beam traversing a medium of varying index of refraction.

Now we can compare

the behavior

of light and matter:

Light K

Matter

c n (r)

=

ink

(1.26)

=

inn(r)

1 ~ inn(r) p =3p

K

+

const.

(1.27c)

=

2m ~E" g

i n k = ~1 l n [ E 1 1 3V/Op -p = 2 E-V

-

V(r)]

-

=

(1.27a,

½

Y(r)]

+

const.

1

3V/3p

-2 ½mY g 2

b)

15

so that 2

8V mv Fp---~=.q

(1.28)

P

The first is, as we shall see, a g e n e r a l i z a t i o n of Snell's law; the second is H u y g h e n s ' s Note that -~V/~p,

c e l e b r a t e d formula for centripetal

force

(1659).

the rate of increase of V in the direction p, is

exactly the force transverse

to the beam.

Note also how Planck's

constant got lost in taking the logarithmic derivative.

Example Solution:

Derive Snell's

1.2

Fig.

law for a h o r i z o n t a l l y

layered medium.

1.5 shows the s i t u a t i o n w h e n n depends only on z.

P

Figure 1.5

Since d@ = - d R ~ o ,

Geometry of a curved ray.

we have

1

d@

dlnn

dlnn

~z

or

dlnn dz

From the figure, ~

dlnn

=

dz/d~ - ~ ~z

-cos@, ~

d@ =

0

= sin@ and

+ coted@ = d l n n

+ din sine = 0

or

nsin@ = const.

(1.29)

16

This

is for a medium

with respect

to I.

we may suppose

that varies

continuously with z and not too fast

But I has been lost sight of in this discussion;

it as small as we like,

take place very rapidly,

though not,

the limiting

is Snell's

at a plane

form

(1.29)

interface,

in 1696 seems

derived empirically

case of a continuously

to his argument

in Section

case in which n varies develop

other methods

Problem

1.13

as it sets?

at the moment

varying medium.

We shall

For the still more general we shall have

to

The index of refraction

Assume

of air

that the earth is flat and that

the bottom of the sun's disc appears

to

The calculation will be done for a curved earth

1.14

Assuming

that the sun's angular diameter

is 30' and

the instant of sunset as in the preceding problem,

change in the visual

1.15

Adapt

show directly as occurs

Problem

(1.29) holds

5.47.

defining

Problem

Johann Bernoulli

that

below.

at ground level.

touch the horizon.

Problem

1.5

In

of light

By how large an angle is the center of the sun's disc

sunset occurs in Prob.

in 1621. ~

in more than one direction,

displaced by refraction is 1.000293

in n may

law for the refraction

to have been the first to recognize

in the more general return

and so the change

of course discontinuously.

that

shape of the sun's disc as it sets. the argument

(1.29) holds

at an air-glass

1.16

find the

of the preceding paragraph at a sharp discontinuity

so as to

in n such

interface.

What theorem in mechanics

corresponds

to the optical

law (1.29)?

Expression

of Classiea~

To conclude mechanics.

Mechangcs

in Terms of Phase

this section we forge another

The total

time-dependent

part is <1.6) can be written # =

link with classical

phase of the wave whose spatial

as

8(r)

-

~t

=

~-IW(r,t)

(1.3o)

where

W(r,t)

=

gs(r)

-

Et

Snell's discovery was anticipated by Thomas Harlot, probably before 1618. See J.W.Shirley, Am. J. of Phys. 19, 507 (1951).

17 From (1.8) and (i.5) we have (VW)2-- ~ 2 x 2

and by the definition

~-F +

(vw)2

approximation

vw

(1.32)

equation

these relations

of ~, and from their derivation

to Newtonian mechanics.

we are dealing with a classical But equation

are once

they are some

We might expect the relation

to

formula that has a quantum interpreta-

is exactly equivalent

(1.31)

the orbit of a particle. characteristic

function, 5.

cancel a significant

We have derived by cancellation

the

than to intro-

(1.31) relatively painlessly

by introducing ~ through

backwards

equation

of ~, but to reconstruct (1.30) and following

to derive SchrSdinger's

We shall do it in Section 6.5.

several chapters

called the entirely within

For the moment we note only that it is easier to

from quantum mechanics considerations

laws for

We shall do this in a leisurely way culmin-

number from an algebraic

duce it out of nowhere. quantum mechanics

W, which Hamilton

can be given a definition

system of ideas.

ating in Chapter

to Newton's

It was first derived in 1834 by William

Rowan Hamilton, s and the function

harder.

(1.31)

= o

since W/~ is the phase of a quantum mechanical wave so that

be subtle,

classical

--

derived from SchrSdinger's

more independent

tion.

+ v(r)

~i.12) gives

p

Although

V(r)]

of W this is

~w

Further,

~m[E-

:

to study the properties

equation

the

is somewhat

Before that, we shall take of particle

orbits and beams

of light in more detail.

1.4

Fermat's

Principle

of Least Time

In about 60 AD, Hero of Alexandria rather neat way to describe ray between

two points

the reflection

s

Phil. Trans.

from a plane mirror:

the

takes the path that gets it from one to the

other as quickly as possible. amateur mathematician

noticed that there is a

In 1657, Pierre de Fermat,

and founder of modern number theory,

Roy. Soc. 1834 II, 247; 1835 I, 95.

the great showed

18

that one can derive

Snell's

law for refraction

at a plane surface

from

the same principle.

It is now called Fermat's principle of least time,

but the phrase

to confusing

signal

leads

questions:

that gets there in the least time?

Is it a phase or a (It is a phase wave.)

since the speed is great, whose clock is used to measure (The laboratory ally inclined, to minimize

clock.) leads

This second answer,

if one is anthropomorphic-

to a further question:

its time with respect

how does the ray know how

to somebody

else's

clock?

the reader may be able to think of some simple situations curved mirrors

in which the time is a maximum,

would have saved trouble

and confusion

And

the time?

Finally,

involving

not a minimum.

if he had expressed

Fermat

it as a

principle of stationary phase.

Problem 7.77 equal angles.

Problem 1.18 equivalent

Prove that Hero's principle

is equivalent

Show that Fermat's principle when properly

to Snell's

law for plane optical

implies

the truth of

in the form

(vs} 2 Let P1 in

Figure

medium of varying

=

(~n T) 2

(1.33)

6 be a point source of monochromatic index of refraction.

Figure 1.6 at a certain moment,

The concentric

the crests

of waves which have

the point source and substitute

frequency,

and let P2 be a point on the laser beam.

that the ray from P1 to P2 intersects follows

fronts

light in a curves

represent,

Light ray traversing wave fronts from PI to P2"

Now remove

This

stated is

surfaces.

It is easy to see that Fermat's principle (1.8)

to the law of

Is it true for a concave or convex mirror?

from Fermat's

principle.

issued from PI"

a laser of the same We assert first

the wave surfaces

orthogonally.

The ray must cross all the wave

in the figure which lie between P1 and P2 in the shortest

time,

19

and since n does not vary appreciably

from one wave crest to the next,

the shortest path from each wave crest to the next is the orthogonal one. If the ray is orthogonal parallel

or antiparallel

displacement

to the surfaces

of constant 8, it is

to the vector Vs, and we have for any

Ar along the ray

IA~l But if the w a v e l e n g t h

=

IwllA~l

is ~, then lAs~= 2~IArl/~

locally

and from

2~/~ = ~n/c we find finally

from which follows mentioned:

(1.33).

(To be precise,

an exception

this does not hold if, as in some crystals,

light depends on the direction

should be the speed of

of the ray, but that case will not

interest us here.) Equation

(1.33)

We have derived problem

is called the eikonal

it both from wave optics

is now to solve it. in (1.33)

The necessary

and we shall see in Section

for doing the calculation, to start with Fermat's

(from e~<~w = image).

That is, we wish to construct

a ray through an optical medium. contained

equation

and from ray optics. information

dynamics

but it is more direct and more historical

principle.

(Section 2.6)

we must now develop

1.5

Interlude Figure

The necessary mathematical

refraction n(y),

is the calculus

the necessary

on the Calculus

1.7a

shows passing

is

5.11 a general method

which we shall also have to use in the corresponding particle

The

the path of

tool,

formulation

of variations,

of

and

formulas.

of Variations

a light ray in a layered medium with index of from a fixed point P0 to another

Pl"

If ds is an element of arc along the ray,

wave

to traverse

it is dt = c-ln(y)ds,

fixed point

the time for the phase

and the total time from P0 to

P1 is given by

cT = In(y)ds = In(y)[1+ In this relation, function of x.

(dy/dx)2]½dx

(1.34a)

n is a known function of y and y is an unknown

Alternatively,

this can be written

as

20

(1.34b)

oT = In(y) [i + (Sx/dy)2]~Sy where x is now an unknown function of y. the curve of the ray as that function

Fermat's p r i n c i p l e specifies

y(x)

(or

x(y))

that makes

the

integral for T a minimum.

P,

Figure 1.7

Curve between two points, with coordinates suitable for (a) a ray of light, (b) the brachistochrone.

The following p r o b l e m in dynamics least to Galileo.

Let the curve

y(x)

is classical: in Fig.

it goes back at

1.7b represent a wire

running from P0 to PI' and let a bead slide down the wire w i t h o u t friction.

y(x)

Find the curve

to P1 in the shortest time.

that allows the bead to slide from P0

The curve so defined is called the

brachistochrone

(8pdXIOTOS = shortest,

linear velocity

is

(2gy)½,

XP6~OS = time).

The bead's

so that

st -- ds(2gy) -~ and the time of descent is given by

(29)½2 =

Evidently

this

is

y

Working before

techniques

for

eight

years

setting

later

y-~[1 + (dy/dx)a]½dx

t h e same p r o b l e m as

for n(y).

wrongly asserted

d8 =

that

the

up t h i s

problem,

the desired

the calculus

(1.34a)

invention

y(x)

(1.35)

with a particular

of calculus, much l e s s

Galileo

solving

form

h a d no

it,

a n d he

i s an a r c o f a c i r c l e .

Fifty-

was i n h a n d a n d J o h a n n B e r n o u l l i

21 stated the problem again as a challenge Europe.

Only he had the solution,

since Snell's

law, generalized

to continuously

path of the ray of light and therefore brachistochrone

to the mathematicians

of

and so has the reader of these lines, varying n, gives the

the form of the wire.

turns out to be a cycloid.

The

(Example 1.4 below.

A

cycloid is the path of a point on the rim of a rolling wheel--in case, the wheel most brilliant mathematics

is being rolled along the ceiling.] pieces of analogical

Bernoulli

reasoning

in the history of

has obtained the answer without doing the work.

Newton solved the problem when it was presented solution

to Bernoulli

anonymously

to him and sent the

in a few lines which were, however,

enough to allow him to identify the sender, murmured,

this

By one of the

The lion, Bernoulli

is known by the mark of his claws.

Now we have to do the

work. We generalize

the problem as follows:

some given function useful]

Let f[y(x), y'(x), x] be

of y,y' and x (higher derivatives

in which y(x] is an unknown functional

of y are rarely

relation.

Let

where PO and PI are given points (Xo,Yo) and (Xl,Yl). We are to find the function y(z] that gives I a stationary value, maximum or minimum, subject to the boundary

condition

the given points PO and PI" possible;

Modifications

of this formulation

are

we shall see some below.

The approach notation

that the curve must pass through

is the usual one in calculus:

and then consider

from the correct answer.

first select a good

the effect of infinitesimal

variations

Let y(x) be the desired curve,

and y(x) + 8y(x) be one that is slightly different.

Here 8y(x) is a

X Figure 1.8

away

Fig. 1.8,

A curve y(x) and an infinitesimal variation of it.

22

function whiah is arbitrary

except that it is "small"

that its square can be neglected

in the sense

and that by hypothesis,

fixed points PO and P1 are at (xo,Yo)

and

since the

(xl,Yl), we have

(1.37)

Sy(x o) = a y ( x 1) = o

In

of the correct y(x),

the n e i g h b o r h o o d

to the first order in small quantities

5 I = 6] f [ y ( x ) ,

I is stationary,

meaning

that

I does not vary when we vary y:

y'(x),

x]dx

= 0

(1.38)

0

(1.39)

J

xo

The variation

in the integral

r

is

x1

6I J

x0 Now

,

,

~Y' = Y v a r i e d

so that

(1.39)

-

Ycorrect

d

= ~xx ( Y v a r i e d

- Ycorrect

) = (6Y)'

is x1

I [~ ~y +

~f 3y'

(su)']dx= 0

-x 0

Integrate

the second term by parts:

xI

+ xo

(~y' ~Y)

-

{7 ( ~~ y , )

]dx

=

23

or

,xI

xl ~

,]By

dx +

y,

6y

xo

Because of integral,

(1.37)

the

which is

6y(x).

function

must vanish

= 0 Xo

integrated

zero,

the

A little

part

is

integrand

of x.

And i n t h e r e m a i n i n g

contains

thought shows

for all values

zero.

a small but arbitrary

that the coefficient

We express

of 6y

this by the notation

6 6yf = 0

where

(1.40a)

the notation means

6f _ ~

This new kind of derivative

d

The term implies

value of the function,

(1.40b)

is called a functional

it does not denote a small variation in y.

~

that what

derivative.

Note

in f divided by a small variation

is being varied is not the numerical

the usual dy, but its functional

form.

The

foregoing analysis was given by Euler in 1744. Returning (1.34a)

to the problem of the ray of light, we see that f in

is

fCy,

We can if we wish calculate differential

equation

simplification situation variable

y')

= n(y)(1

(1.41]

+ y'~)~

~f/6y, arriving at a second-order

for y(x),

but it happens

that there is a

we can use here and in many other cases.

defined by (1.34a), x explicitly,

In the

f does not involve the independent

and an integral

of Euler's

differential

24 equation

(1.40) can be found at once.

Consider the function

F(y,

y')

~ f (~y, y , .v') y ,

=

f(y,

(1.42)

y )

Its derivative with respect to x is

dx-

dx

~y'

Y

+

~y,

y

-

y

if f makes the integral I stationary,

-

~y,

by

=

-

(1.40).

y'

=

0

Thus a first

integral of the equation in this case has the form

F

Example

1.3.

=

~f, ~y y' - f

=

(1.43)

const.

Snell's Law.

With f(y, as in (1.34a),

,y') = n ( y ) ( 1 + y,2)½

this gives

n(y)y'2(1

+

y,~)-½

-

n(y)(1

+ y,2)½ = -C(const.)

or n~)

(2 Since y' = -cotO in Fig.

c

C1.44)

+ y'2) ½=

1.5, this is

n(y)sinO = C which is Snell's law (1.29) again. We can easily find an equation for the ray: at some point

in the medium:

C = nosinO O.

y' we find x as a function of y,

Evaluate

Then b y s o l v i n g

the constant (1.44)

for

x

25

=[

dy

(1.45)

~._.M.,Q_) 2

[(noslnO 0

Example

From

1.4.

1] ½

_

The b r a c h i s t o c h r o n e

(1.35)

f ( y , y ' ) = y-½(1 + y,2)½ and

(1.43)

gives

y,2

[1 + y,2]½ const.

=

[y(1 + y,2)]~ This quickly

reduces

C

y~

to y,2 _

1

- I

C2y

which

can be solved easily enough but the answer

To recognize yourself cycloid

it as the differential

equation

is uninformative.

for a cycloid,

that if @ is the angle through which the wheel is rolled,

the x and y coordinates

convince

generating

the

of a point on the rim are

given by x = a(e

- sine)

y = a(1

where a is the radius of the Wheel.

-

I

is satisfied provided

(1.40)

cosO)

Then note that

asinede y' = ~ x = a ( 1 cose)de

and that the equation

-

follows

sine cosO

-

that a C 2 = ½.

Problem

1.19.

Prove that

Problem

1.20.

Find the shape of a soap film forming a surface of

revolution bounded by two parallel

from the steps before

circular

it.

loops of wire on a common

26 axis.

(The physical

hypothesis

is that surface tension causes the

film to assume the shape with the least area.) Problem

Suppose that y depends on several

1.21.

independent

x I ... x n and that the integral in (1.36) is a multiple Show that the Euler equation is X I ... X n •

6f_

~f_

6Y

~Y

n

9

i~1

~xi

variables

integral

over

8f

8(~-~x.)

=

(1.46)

o

"Z.

Problem

Suppose

1.22.

there is one independent

a function of several variables Yl (x)'''Yk(X) derivatives.

Show that Euler's

6Yi

Problem

equations

~ Y i - ~-~ ~ Y i

are now k in number,

0

What if there are

1.23.

n

variable but that f is

and their first

i

= 1 .....

independent

and

k

k

(1.47)

dependent

variables? Problem

What happens

1.24.

if f depends on y, y', y", and x?

case is rare in practice but not unknown.)

Assume

as 6y vanishes

at the ends of the path of integration.

Problem

Calculate

1.25.

independent Problem

1.26.

two points Problem

variable

the path of the light ray taking y as the

as in (1.34b).

Find the path that makes the shortest distance between

in Cartesian and then in polar coordinates.

1.27.

close to i?

What is the limiting

form of (1.45) when n is very

The density of the earth's atmosphere

exponentially with height. of sunlight

Writing n(y)

that enters the atmosphere

1.28.

Consider

the propagation

decreases

= 1 + se -ay,

obliquely

earth at x = y = 0 at an angle 80" (Approximation Problem

(This

that 6y' as well

roughly

find the path

and hits the (flat) for small s.]

of light in a material medium

whose index of refraction n(r)

has spherical

Introducing polar coordinates,

show that

symmetry,

Fig. 1.9.

27

odt = n(r)(r

2 + r'2)½d@

r'

= dr~d@

(1.48a)

and t h a t the e q u a t i o n o f t h e r a y i s

dr @ - @0=

rnCr)) 2 r[( ~ -

/ Figure 1.9

ProbZem

:

= const.

]%

(1.48b)

,

Ray of light entering a medium whose index of refraction has circular symmetry.

1.29.

Show that the result of the last p r o b l e m is equivalent

to

rn(r)sin@

where

=

(1.48c)

a

@ is the angle b e t w e e n the ray at a point at a distance r from

the center and a radial line drawn to that point.

1.6

Optics

in a G r a v i t a t i o n a l Field

According

to the General Theory of R e l a t i v i t y a g r a v i t a t i o n a l

field is d e s c r i b e d not in terms of a p o t e n t i a l index of r e f r a c t i o n

(for particles)

or an

(for light), but in terms of curvature of the

u n d e r l y i n g space-time.

Optics and m e c h a n i c s

thus have a common basis.

We shall see later that out of the geometrical description can be

28

extracted

a potential

conceptual directly

and an index of refraction

link with other parts of physics,

from geometry.

This is not the place

of the general theory of relativity, how to describe

a curved surface

terms of the coordinate

(in any number of dimensions)

they are drawn. coordinates

coordinates

systems

to go further one needs

are conditioned by the surfaces

to a plane,

and longitude

that

But there are many kinds of coordinates

or a plane with the

are used on a sphere.

that can be used on a plane,

and many on a sphere.

Therefore

matter

The rest is imposed by the surfaces.

In the flat Minkowski and t correspond manifold

directly

one can neglect surface

space-time

are used,

in none of which,

distances

measured

the ground. students time.

except

geography

is no constant

The spacetimes

do

show distances measured

and general

and angles on a map r e p r e s e n t

and there

on a curved

Several projections

in a small neighborhood,

is better than others,

but only in Mercator's

is the

a large region

points

of a plane.

that

projection

along

confuses

relativity

They feel that there ought to be a "correct"

Distances

ones,

for representing

on the map directly

or at least one t h a t earth,

but in mapping

It is the element of arbitrariness

encountering

but in a curved

The situation

reading a flat map is easy if

curvature,

in terms of the coordinates

are partly a

relativity x, y, z,

intervals,

is less direct.

a convention

systems

of special

in geography:

the earth's

one must establish

coordinate

to measured

the correspondence

same as one encounters

in

The examples

There is no way to cover a sphere with the

appropriate

of latitude

of convention.

on

imagination.

It is clear that coordinate Cartesian

to launch a discussion

systems which can be drawn on it.

only a little pictorial

a

but we can make a few remarks

to follow will be in one and two dimensions;

on which

that establish

but here we shall work

for the first

representation,

but there is not.

distances

and angles on the

are the angles

the same,

scale of distance.

to be considered

are not very different

and we shall take as a standard of comparison

from flat

the invariant

expression d8 2 =

which defines

an element of proper time in special

the flat spacetime directly

of Minkowski,

to measured

correspondence

(1.49)

c2dt z - dx 2 - dy 2 - dz 2

intervals,

is less direct.

dx,

dy,

dz,

relativity.

and d t correspond

but in a curved spacetime Consider

the

for example the one-

In

29 /

d i m e n s i o n a l map p r o j e c t i o n s of Fig. m a p p e d is an arc of a semicircle, available

I.I0.

The "surface" to be

and among the various projections

to map it onto a flat surface two are shown.

In the

E

/ J X

Figure i.i0

projections

J~

Radial and vertical projections of a circular arc.

the actual distances

de

along the curve are mapped

= Rd@

d i f f e r e n t l y onto c o o r d i n a t e distances dx m e a s u r e d on the map.

In the

radial projection,

x = RtanO

and

dx

= Rsec28d0

Thus

dx

= RdO(1

+ x 2 / R 2)

or

d8

(1.so)

dx 1 + x2/R 2

In the vertical projection,

on the other hand,

x -- RsinS,

dx = R d S ( 1

- x2/R2) %

and dx d8

(1.51)

= (1

-

x2/R2) ~

These examples emphasize the c o n v e n t i o n a l systems, associated

a n d one o f t h e g r e a t especially

nature

of c o o r d i n a t e

problems of differential

geometry,

w i t h t h e names o f Gauss and R i e m a n n , i s

to

30

reconstruct

the curvature

topological properties

of the underlying

space,

and ultimately

as well, when only a coordinate mapping

its

is

given. The same diagrams two dimensions.

can be used to show how the formulas

Suppose

views of segments along its axis.

that the arcs in Fig.

look in

I.I0 are the end

of a cylinder, with y as the distance measured Corresponding

for actual distance measured

to given dx,

dy on the map the formulas

along the curved surface of the cylinder

are

dx 2 ds 2 =

(radial projection)

+ dy 2

CI + x 2 / R 2 ) 2

and

dx 2 d8 2 =

+ dy 2

(vertical projection)

1 - x2/R 2

In the notation usual

in relativity

x I and x 2 and the coefficients and ~2

"

Thus both formulas

theory,

x

of (dxl) 2 and

for distance

and y are called (dx2) 2 are called gll

can be w r i t t e n

as

2 d8 2 = i=~igii (dx i) 2

with appropriate

g's.

In the spacetime

of special

z are again somewhat

arbitrary.

and dz corresponding

to the interval between

on which way the observer defined by

(1.49)

our notation

relativity

the coordinates

The numerical

values

dx,

dy,

a pair of events depend

is facing and how he is moving,

is postulated

t, x, y,

of dt,

but ds 2

to be the same for all observers.

In

this formula becomes

3

d8 2 =

~. g i i ( d x i )2 i=O

with gO0 = e2" gll = g22 = g33 = -I.

In the curved spacetime

(1.52)

of

31 general

relativity

the g's become

in certain situations, coordinates

functions

of the coordinates,

which we shall not encounter here,

are no longer orthogonal

and

(1.52)

and

the

is supplemented

by

terms of the form g i j d x Z d x J with i ~ j. This will be explained discuss

two optical

further when it is needed.

effects,

light signal passing

the deflection

the sun.

and the retardation

Both are capable of accurate

tive m e a s u r e m e n t

and are among the few quantitative

theory.

test,

Another

in Section

the precession

of planetary

orbits,

is discussed

5.3.

plane polar coordinates,

in which

de 2

In special relativity

dt

dr 2

_

(1.53)

r2dO 2

_

is an interval measured on a clock, made on scales

In the gravitational

convenient p r o j e c t i o n

the sun we use

(1.49) becomes

c2dt 2

=

and d@ are measurements

the clock.

and r,

at rest with respect

The function g(r) theory,

takes the form

is related

to the gravitational

and is derived by integrating

equations

much as the Coulomb potential

Maxwell's

equations.

and Coulomb's

laws,

gCr)

where

(1.54a)

=

I

-

comes from integrating

2~/r,

=

constant.

®

Starting

= 1.475

that de 2 in (1.49)

(I.54b)

2

km

from the Lorentz

and t for motion along the x axis,

GM/o

For the sun,

and the second term of g is an extremely

and verify

of

field

as given us by Nature:

G is the Newtonian

1.30.

potential

Einstein's

In these notes we shall take it, like Newton's

h

Problem

to

field of a spherical mass M, a

ds 2 = o 2 g C r ) d t 2 - g C r ) - i d r 2 _ r 2 d @ 2

Newton's

of a

quantita-

tests of the

For dealing with the plane orbit of light passing

dr,

Below we shall

small correction.

transformations

give those for dx,

is an invariant.

dy,

of x, y, z, dz,

and dt,

32

Derive a formula analogous

Problem 1.31.

to the spatial Dart of (1.54)

for some mapping of a part of the earth's quantity ds 2 should represent r, dr, and dO represent

an actual

distances

surface onto a plane.

terrestrial

distance,

and angles measured

The

while

on the paper.

The P r o p a g a t i o n of Light

In special

relativity

all observers

of light in the same mathematical equal to zero.

The same feature

way:

One needs

see in Sec.

5.3.

itself:

The following

ds 2 is set

over into general relativity.

the speed but not the path of

an equation of motion

What comes out is simplicity

the speed of a pulse

the invariant

carries

One again sets ds 2 = 0; this specifies the light ray.

describe

in curved space-time.

Fermat's principle,

as we shall

example will show how the principle

is applied. Gravitational Deflection of Light

Fig. passing

I.ii shows a ray of light originating

in a distant

close to the sun on its way to the earth.

star and

The label r repre-

sents a distance on the diagram but not as it would be measured

Figure i.ii

space. tational

Deflection of a light ray by the sun.

(The reader is invited to ponder

specifying

operationally

field.

Remember

what

on the difficulties

is meant by distance

of

in a strong gravi-

that the motion of light is affected by the

field and that there can be no such thing as a perfectly Setting ds 2 = 0 in (1.54a), we require

ct = I(g-lr2

in

+ g-2r'2)½dO

rigid body.)

that 6t = 0 with

r' = dr~d@

(1.55)

33 Since the term on the right does not contain @ explicitly we can use

(1.43): g-2r~2 [g - l r 2

+ g-2r'2] ½

- [g-lr2

+ g - 2 r ' 2 ] ½ = -~

(const.)

and solving this for r '~ gives r '2 = ~-2r~ - gr 2

The m e a n i n g of a is easy to see here.

(1.56)

Where the ray passes

the sun, r is a m i m i n u m as a function of 0, and r' = o.

(~

:

g

-½rml• n

~-

. CI

+

rl.

closest to

Thus

) rmin = rmln. + I : rmln.

mln

so that ~ is very nearly the beam's

(1.57)

distance of closest approach.

I n t e g r a t i o n of (1.56) gives

dr

(1.58)

@ - @0 =

r2

r(-~Comparing

(1.55) with

21

: + 7-)

(1.48a) we see that r 2 and r '2 are now

m u l t i p l i e d by d i f f e r e n t quantities:

it is like p r o p a g a t i o n

through

an a n i s o t r o p i c m e d i u m in w h i c h the radial and tangential velocities are different.

Comparing

(1.58) w i t h

(1.48b) we find an effective

index of r e f r a c t i o n

n :

(:

(1.59)

+ ~~ 2a ~r 3M ) ½

This averages out the a n i s o t r o p y but its value depends on the orbital constant ~ of the p a r t i c u l a r ray and so it is not a real index of refraction. Because n in (1.59) passes

is so nearly equal to i, a ray of light

the sun in nearly a straight line and its slight deflection is

easy to find. whose curvature

Suppose a light pulse moves p-Z is given by

a distance de along a path

(1.26), Fig.

1.12.

The change in its

34

direction is

d6

=

p - l d s , with ~inn ~p

p_Z

so that, with d s

= dx

=

~inn ~y

3aaGM

(1.60)

c2r s

and r 2 = x 2 + a 2,

I dx

_

p

3aaGM oa

_oo

I

(x 2

dx +

4GM

~2)~2

(1.61)

c~o2

_co

I

,4,/

I C~)

tb)

Co)

Figure 1.12 Geometry for the deflection of light by the sun.

At grazing incidence ~ = R, so that 6 = 4GM Rc 2

4h R

(1.62)

1.75"

It is important to check this number, but very difficult. measurements

Optical

are made during eclipses so that stars near the sun may

be seen, but the image of a star on a p h o t o g r a p h i c plate

is larger

than the d i s p l a c e m e n t to be measured.

(1.62)

An agreement w i t h

to

S percent is claimed for a recent o b s e r v a t i o n carried out under difficult conditions. 6

Probably the best experimental technique to

use is radio interferometry.

Early in October every year the sun

occults the quasar 3C279 and m e a s u r e m e n t s can be taken w i t h no Texas M a u r e t a n i a n Eclipse Team, Astron. J. 81, 452 (1976); B.F. Jones, Astron. J. 81, 455 (1976). A c o m p a r i s o n of earlier m e a s u r e m e n t s is given by S . W e i n b e r g C1972), p. 193.

35

interference from the sun except the r e f r a c t i o n p r o d u c e d by its corona.

This

is variable, but

and by taking m e a s u r e m e n t s A result reported

its dependence on frequency is known,

at two frequencies

it can be eliminated.

in 1976 is 7 1.761" ± 0.016",

8ob s

=

(1.007

or

± O.O09)Sth

Problem

1.32.

Carry out the a p p r o x i m a t i o n s

Problem

1.33.

In 1801,

in (1.60).

Soldner 8 gave a naive p r e r e l a t i v i s t i c

calculation of the d e f l e c t i o n of light w h i c h is amusing h i s t o r i c a l l y and w o r t h looking at here because it emphasizes between group and phase velocity.

Assume

the d i s t i n c t i o n

that light of mass m travels

at speed o in regions far away from the sun.

Then by the conserva-

tion of energy,

E = ½me 2

And,

=

( i .63)

½ m Y 2 + V(r)

in (1.26),

InK : ½ 1 n [ E

- V(r)] + const. GmM.

= ½1n(½mc2 +

r ] + const.

or 2GM.

(1.64)

ink = ½1n(l + r--~T) + const. From this the c a l c u l a t i o n can be completed. On the other hand, we can use the optical approach.

v =

~[F-

From

(1.63)

v(r) ]~

and = n

so t h a t

in

c

2

F = [m-TT(E

-

V(r))]-~

(1.27a),

7

E.B.Fomalont and R.A.Sramek,

8

J.Soldner, B e r l i n e r Astron. Ann. Physik 65, 593 (1920).

Phys. Jahrb.

Rev. 1804,

Letters 161

36,

(1801).

1475

(1976).

See also

36

InK = inn + const. The results calculate

(1.64)

and

(1.65)

the deflection,

= -½1n(1

disagree.

and compare

2GM~ + const

+ r--~ Resolve

the discrepancy,

it with Einstein's

Problem 1.34. The special-relativistic

(1.65)

version of

(1.63)

value. is

[E - VCr)] 2 = o2p 2 + (me2) 2 Calculate

the deflection

the result of general

of light

(1.66)

in this theory and compare

it with

relativity.

Delay of a Radar Signal Passing the Sun With the advent

of interplanetary

radar techniques

in the 1960's

it became possible

to test general

relativity

in another way by

measuring

the retardation

of a radar

signal

a planet

directly

reflections distance,

vary

Mercury

in intensity

as the inverse

planet into

for light to pass

at rl, O I.

(1.55)

Because

from radar

fourth power of the

is chosen.

We divide up the path into four sections required

reflected

on the other side of the sun from ourselves.

from the sun

The formulas

are ready

and evaluate

(O = ½~

in Fig.

to hand.

the time i.ii)

Putting

to a

[1.56)

gives @i

I I g-lr2dO

1

To simplify stationary replace Fig.

this we remember under

a small

(1 + -~-)radO

I°,

that by Fermat's

change

of the path.

the curved path by a straight

1.12z,

the time is

We may therefore

one with negligible

r2dO = ~dx a nd

principle,

error.

By

37

x1

r =

°tl : 10(: + ~)dx which

with

xI

>> a i s

close

(1.67)

to 2x I ,,

et I = x I + 21ln

The second term is the delay. Mercury

(x 2 + a2)½

(1.68)

For a round trip from the earth (~)

(~) with the ray grazing

~t =

the sun

4G__~ in

4r r M ~ ~

c 3

to

(~ : R), the delay is

(1.69)

R2

This amounts

to a delay of 240 ~s, in a round trip that takes 23 min.,

with respect

to the time calculated

without

from the known orbit of the planet

taking the delay into account.

the Mariner

satellites

3 percent.

Radar reflections

interpret because

I km, which is much smaller

from the planetary uncertainty

apparent

frequency

the test worth trying? distance Problem

beach,

of 3 percent surface

to

irregularities.

orbital plane.

source a Calculate

the year.

Could the method be used to determine

how Is

the

to the pulsar? 1.36.

which direction

Ocean waves

approach

do the waves

a straight, an angle

uniformly

shelving

@ with the beach.

curve as they approach

that the waves break when the water reaches

In

the beach? a depth k -z, use

the method of this section to find out how much their direction has changed.

to

of

corresponds

should vary throughout

the line of the waves making

Assuming

are harder

to a distance

Design a test of (1.69) using as a signal

1.35.

pulsar's

surface

amounts

than the planet's

distant pulsar that lies in the earth's the

agree with theory to about

120 ~s, half the delay,

35 km, and the observational

Problem

Recent measurements 9 taking

6 and 7 as targets

The answer

J.D.Anderson

et

is 7.80 tan@ degrees.

al.,

Astrophys.

J. 2 0 0 ,

221

(197S).

CHAPTER 2

ORBITS OF PARTICLES

If a system has only a very few degrees of freedom its equations of motion are often obvious. about solving them.

If they are not easy to solve it is because some

equations are difficult. equations presents

One writes down Newton's laws and sets

In complicated systems, even formulating the

some problems,

and most of these notes are devoted

to more advanced and general ways of writing down such equations constructing their exact and approximate solutions.

and

This chapter is

an exhibition of relatively simple systems chosen so as to illustrate various forms of dynamical behavior. only Newton's

The first few examples require

laws and a little mathematics,

but for the later ones

it will be convenient to introduce angular variables,

and for this

we shall write down equations of motion in terms of generalized coordinates.

This will be done using Lagrange's

technique, which

leads not only to general and useful equations of motion but also to the powerful methods of solution that follow. 2.1

Ehrenfest's Theorems We have seen in Section 1.3 how to get Newton's laws out of

SchrBdinger's

waves, but of course there is a nicer way to do it

that dispenses with most of the talk.

Ehrenfest's

easy to state and prove that I hope some readers,

theorems I are so at least, will find

the proofs not very explanatory and will learn more from the primitive discussion of Chapter i. The theorems relate not to the dynamical variables of quantum mechanics

themselves but to their expectation values.

equation for the time-dependence

dynamical variable A in quantum mechanics

d

~

dt

=

<

The general

of the expectation value of a

^ ^ [~,A]

is

~_A_A> +

~t

(2. i)

where A is the operator representing A, H is the hamiltonian operator, A

^

^^

^^

^

[H,A] is the commutator HA-AH, and ~A/~t is included in case the ^

operator A depends explicitly on the time. tion of magnetic for a particle

v<=)

Postponing the introduc-

fields till Section 4.2, we write the hamiltonian

in a field of force given by a potential

function

as

P.Ehrenfest, Zeits. f{ir Physik 45, 455 (1927). This three-page paper, coming at a time when most physicists were floundering in an attempt to understand the new quantum mechanics, did much to overcome their initial aversion.

39

= ~-~ + V ( r )

(2.2)

2m

We are in the coordinate ates are represented

representation,

by numbers

in which positional

and momenta by operators

according

= -i~V

The basic

commutation

relation

to

(2.3)

is

[~j, Xk] = - i ~ 6 j k It is trivial

coordin-

(2.4)

that A

^

^

[A,B]

^

A

^

= -[B,A]

^

^

(2.5a)

^

^

^

[A, B

+ C) = [A,B] + [A,C]

AA

^A^

(2.5b)

and A

[A,BC]

^^A

= ABC

AAA

A^A

- BAC + BAC

- BCA

or

A ^ ^

^

[A,BC] Now for any component d<x .>

J

=

^

^

[A,B]C

~

^

^

(2.so)

+ B[A,C]

of position we have

= Ki <[ 2~m + V(r)

x j) >

dt

= ~

<[P~ + Py + ~z" =j]

i

~m~

=Y~ 1 <~j>

=j]

40

or 2

d

= m

(2.6)

dt

Thus the relation between expectation values of momentum and velocity is the same as in classical physics.

Now we find how

varies in

time.

d dt

i

<[~_m 2 + V(r),

pj]>

= ~

<~V > =-

~x~

J

or d

dt = -



(2.7)

These identities are extremely general, tation values in any state at all.

for they refer to expec-

Connections with classical physics

can be made only if the state resembles

those of classical physics,

in which we assume that it is possible to specify dynamical variables without uncertainty.

This is an idealization even in classical

physics; ~ in quantum mechanics

it is not even that, since the

indeterminacy relations preclude simultaneous pairs of variables. parameters,

specification of certain

But indeterminacy rarely affects macroscopic

and in all but a few very special situations we may assume

wave packets which are, and remain,

so narrow in all dynamical

variables that the quantum indeterminacy would be swamped by the errors in any physically possible program of measurement. Problem 2.1.

Derive

C2.7) from the basic commutation relations.

Problem 2.2.

A l-gm point mass is dropped onto a target as accurately

as possible from a height of 1 km. rotation,

Neglect air pressure,

the earth's

etc., but assume that a strategy has been derived for ^

is the same number as . difference in meaning:

The notations

suggest a slight

is the expectation value of the dynami^

cal variable A, while is the expectation value of the operator ^

A that represents A.

3

See f o r

e x a m p l e Born 1 9 5 0 .

41

minimizing

the quantum error

attainable

accuracy

contribute

to the error.

with variances

(Aa) z and

the individual

variances.

(2.6) and

of macroscopic

to be made.

if a and b vary at random in a + b is the sum of

that

in appropriate

is the better

Oscillators

of Newtonian mechanics. and more general

theory,

effects which can be similarly

of Newtonian

to apply,

states,

does not require any approximation

(neglecting relativistic the equations

which it was intended

dynamics,

for the

systems

to

agree exactly with it.

and Pendulums

It is not our intention course

we are speaking of macroscopic

that

systems prepared

the derivation

that

Ax and Ap each

Use the fact t h a t

Quantum mechanics

and we now see

2.2

The initial

(2.7) reduce to the basic equations

It is important

treated)

Show that the theoretically

Note:

(~b) 2, the variance

With the understanding parameters

in the aim.

is about 1 fm.

to repeat

in elementary physics

quantum mechanics,

the mechanics

section of a

or to linger over the analogous parts of

but a few remarks here on simple oscillating

systems will be of use later. A simple harmonic

oscillator

by a spring of stiffness

k.

is a mass m bound to a fixed point

For motion in one dimension,

the equation

is m~ + kx = 0 with

(2.8)

the solution

x

:

Acos(mt

For the calculation

-

of sinusoidally

use of a complex exponential generalize

readily

discussed below.

systems

oscillations

like this the

but it does not

like the pendulum

to be

For this reason we shall not use it in this section.

Although nothing integrated,

oscillating

is the method of choice,

to nonlinear

(2.9)

~2= k/m

O0)

could be simpler

it is a prototype

which are appreciably way of integrating to the first order.

harder,

than the equation we have just

of other equations

of the second order

and we should note here that there is a

such equations

that drops

it from the second order

Multiply both sides of (2.8) by x: m~

+ kx~

=

0

42

This can be integrated

at once to give ½m& 2 + ½kx 2 =

(const.)

E

in which the constant E is, of course, energy,

(2.10)

interpreted

as the particle's

and the equation now becomes dx dt

which is integrated

dx (A 2

_

x2) ~

_

~o(2m_i

_2E

(2.11)

_ x2)½

as

-

oJ

I

dt

.2~ .½ A = [m-~J

oJ ( t =

_

t o)

(2.12a)

or

sin -I x / A

=

m(t

x = Asinm(t Several points

in this elementary

-

(2.12b)

to)

(2.12m)

- to)

example

should be noted.

we know when energy is conserved without needing we could have started with second-order E and t0.

(2.10).

equation contains

The general

two arbitrary

to prove

it, and so

solution of the

constants, A and ~0 or

In the second solution we lowered the order of the equation

from 2 to 1 and picked up a constant again and picked up t O .

of integration;

For a system not subject

influences

from outside,

integration

and it is the least interesting,

the arbitrary

then integrated

to time-dependent

t O is always one of the constants

setting of clocks.

from 2 to 1 before solving

it, but more complex systems have more complex equations, their order with the inclusion

means,

of constants

is independent

feature

of these oscillations

of the amplitude;

in the

is that the

that is what "harmonic"

and it comes from the linearity of the equation

In Chapter

and lowering

of integration

equation of lower order will be a useful device.

The characteristic frequency

of

since it refers only to

In this case it is no great thing

to have dropped the order of the equation

remaining

Generally,

of motion.

3 we shall discuss more complicated vibrating

that are still harmonic,

finding that the linearity

systems

is a great help

43 in their solution.

Our next example will be one with a nonlinear

equation. Note

on A r c - S i n e s

In (2.12c),

t may be as large as one likes.

Therefore

this must

also be true in (2.12a),

and how this can be so may be puzzling

one looks at the obvious

boundedness

what

of the integral.

if

To understand

is happening we must go back to (2.11) and note that it is not

really correct, positive

since 4 2 has two square roots,

or negative.

it must go through ±A; we knew that, (2.12a).

For the quantity

zero;

therefore

so the double

The points where

The integral

in (2.12a)

and ~ can be either

(A 2 - xZ) ½ to become negative

it changes

sign as x goes through

sign is not written

the sign changes

is to be understood

explicitly

are called turning points. as going back and forth

along the line from -A to +A, the square root changing be positive when dxis positive negative

(back).

(forth)

in

signs so as to

and negative when

In this way the value of the integral

it is continually

increases. Problem

2.3.

Show that the h a r m o n i c i t y

the linearity of the equation, d4x/dt ~ ~ Problem

-Kx

2.4.

of the oscillation

and that a magic oscillator

comes from obeying

is also harmonic. Find the motion of the oscillator

force proportional

to the velocity.

if it has a resistive

(Note that there is no energy

integral here.) Problem

2.5.

Assuming

A hole is drilled through the earth along a diameter.

no friction,

no rotation,

motion of an object allowed soon does it arrive time between

and uniform density,

to fall from the earth's

at the antipodes?

the same two points

find the

surface.

How

How does this compare with the

for a satellite

in an orbit at

treetop height? The S i m p l e

Pendulum

This p e n d u l u m of length Z. pendulum.

is a point mass m on the end of a weightless

If the mass

is distributed

We shall do so in Chapter

The mass moves

may be taken as x

are not needed to say where

angle @ with the vertical,

suffices.

but w i t h one degree of freedom. in terms of torques

8.

in a plane whose coordinates

and y, but two variables

string

one speaks of a physical

it is.

One,

the

It is a system in two dimensions

To set up Newton's

second law in

is not hard but it is unnecessary,

for we can

44

more easily write down the energy: (2.13)

E = %m£2@ 2 - mgZcos@ where we have taken the zero level of potential suspension.

(This makes E negative

The differential

equation

energy at the point of

for amplitudes

less than 7/2.)

is solved by the integral

(2.14)

(m--~ + c°sO)~ The integration functions

cannot be carried out in terms of elementary

unless we are willing

to assume

that the energy is so small

that @ never gets very large and use the small-angle

approximation

cos@ : 1 - #8 2

T h e n we h a v e

I

de

(~z_.)~.~_

Cm_~-~-z+ ~ _ .to2) "~= which is formally

[2.1s)

I dt

the same as (2.12a).

Problem 2.6.

Complete

the solution

in the small-angle

Problem 2.7.

Starting

from

find the second-order

motion

equation of

in @.

To reduce

the exact equation

angular amplitude so that

(2.13),

approximation.

of swing,

(2.14) requires

@0"

to a standard From

form we introduce

(2.13). with

8= O, E =

the

-mg£cos@ O,

the integral

(cose - cOS@o)½ We have already arc-sine)

seen that t(@) reduces

when @0 is small.

when @0 is small, we write

to something

familiar

To introduce a parameter

(an

that is small

45

cose - cose 0 : 2(sin~½eO

sin2@e)

and finally, to measure sine 0 against the amplitude, sin½e = sin@8osin¢. With this, ½cos%ede

=

k =sin½O 0

kcosCd¢

or

2kcos~d$ de =

(1 - k2sin2¢) ~

SO that finally,

t=

I

2kcos~dO [2k 2(1

sin2¢)(1 - k2sin2¢)]½

-

o

or

I ¢

t

=

(~)½

de

(1

-k2sin~¢) ½

(2.163

0

where we have chosen the limit so that the clock starts as the pendulum goes through its lowest point. The amplitude determines k, and for ordinary pendulums k 2 is pretty small. To find the period T, we note that in a quarter-period ¢ goes from 0 to ~/2: ~/~

T = 4(~) ½ I0

d*

(1 - k 2 s i n 2 ¢ ) ½

(2.17)

= 4(~)½ ]0 (I + ~k2sin2¢ + ~k~sin~¢ + ...)d,

or

T = ~(

~)½ (I

+~

k2

~

+ ~ +

...)

(2.18)

46

As Galileo noted many years ago, the pendulum's period does not depend much on the amplitude.

Even for 00 = ~/2,

with k 2 = ½, the

period is increased by only 17 percent.

Problem

2.8.

This p e n d u l u m may also be regarded as a little ball

that rolls in a trough of circular curvature. curvature is that of a cycloid. amplitude?

How does

It will be convenient,

Suppose now that the

the period depend on the

using the equations

for a cycloid

on page 25, to introduce a new variable u defined by u 2 = I - cos@. The result you are about to obtain was embodied by Huyghens

in the

m a n u f a c t u r e of clocks in 1657, when Isaac Newton was 15 years old. "

2.3

Interlude on Elliptic Functions The integral

that occurs in (2.17)

is called a complete

elliptic integral of the first kind, 5 and the indefinite integral in (2.16) defines an elliptic function.

Since we shall encounter them

again and they are important in many branches

of physics, we shall

b r i e f l y survey them here. If in (2.16) we make the substitution x = sin~,

the integral

takes the form

i

s

t =

dx [(:

- x 2)(:

-

(2.19)

k2x 2)]½

o

where we have omitted the irrelevant constant. standard form. everything

This is another

Let us look at it first in the limit k = 0, w h e n

is familiar.

E v a l u a t i o n of the integral gives

t(s) = s i n - i s The notation suggests

(2.20a)

a more convenient form for the answer,

s(t) = sint since whereas

(2.20a)

(2.20b)

defines a m u l t i - v a l u e d

defines a s i n g l e - v a l u e d

function of s,

(2.20b)

function of t.

Huyghens 1673. The proof involves infinitesimals (as do the proofs in Newton's Principia) but antedates any systematic development of the calculus. It requires a dozen propositions to prove it. s

Formulas and tables in Dwight 1934; W a t s o n 1927.

theory in W h i t t a k e r and

47 If we knew nothing about

it as follows.

differential

about the sine function,

Go back to the integral

equation: dt

1

-~

=

(I

Since we are interested

82) ½

k

in s as a function d8

(1

~ry =

and find the differential

equation

from

(2.19)

that s(O)

The sine is defined by

of t, we invert

(2.21b)

again:

ds

= 0 and

=

(2.21b)

-8

from

(2.21a)

and these boundary

that s(O) = 1.

conditions.

Let us go through the same steps with the elliptic (2.19).

it, (2.21cc)

(1 - ~2)½ ~

-

=

o

for ~ by differentiating s

dr2

=

- 82) ½

d28

It follows

we could find out

and write down its

integral

We find I

dt

[(1 and by the same maneuver

-

(1 + k 2 ) s

.... dt 2

+ 2kZs a

equation and the same boundary

~(0) = I define a periodic

te~

cf. (2.17), its period

(2.22b)

conditions

s(@)

= O,

function of t that was named s(t)

(pronouned e s s - e n

(2.22a)

k282)] ½

as before,

d28

This nonlinear

82)(2

= snt

), by Jacobi

is 4 K ( k ) ,

in 1827.

From our previous work,

where

1

K(k) =

(2.23)

dx [(1

- x2)(I

(2.24)

k ax2)]½

0 (It has another period with respect we shall not need that.) If sn is analogous cosine?

We define

Fig.

to the imaginary part of t, but

2.1 shows snt for

to the sine, what

two values

is analogous

of k.

to the

48

cnt

with

the

same s i g n

cosine.

=

(1 - sn2t) ½ in

conventions

Then by d i f f e r e n t i a t i n g

taking

root

as

for

the

snt dsnt cn--~ --J?--

n

,

/

( X

iO

k = 0.998? KCk) = 4.~6~

k = O. 8660 K(k) = 2.157

Figure 2.1

I f we i n v e r t

square

(2.25)

dcnt d---~- = -

/

the

(2.25)

Jacobian elliptic function snt for three values of k.

(2.22a) dsnt

and w r i t e

it

as

= cntdnt

d n t = (1 - k 2 s n 2 t ) ½

(2.26a)

we h a v e dent --dT-=

These are

easy

analogy

with

(2.26b)

shows

to remember:

sines that

cnt

does not

dt =

dent dntsnt

the

=

-(1

satisfy

relations

and m u l t i p l y

is a s o l u t i o n

dac dt2

Note that

write

and c o s i n e s cnt

(2.26b)

-sntdnt

-

2k2)a

the

you would e x p e c t

by d n t .

Differentiating

of -

(2.27)

2k2c a

same e q u a t i o n

as

snv.

dcnt

--

by

[(i _ c n 2 t ) ( l

_ k 2 + kScnat)]½

From ( 2 . 2 6 b ) ,

49 and since cn(O) = I, this is

dx

t = I '1 [(1

_ =2)(1

(2.283

/<2 + /<2x2 ) ] ½

cnt

Problem

2.9.

for dnt.

Find the differential e q u a t i o n and definite integral

Remember

that

(I - k2) ½ ~ dnt < 1.

By e x p a n d i n g the integrands

in (2.19) and

(2.28),

Problem

2.10.

express

snt and cnt in terms of the sine and cosine to the first

order in k 2 . Solution

for

Expanding

snt

(2.19) and integrating the first two terms gives t = sin-ls + 7I

k2 [sin-ls

(:

-

82)½]

+ 7I k 2 ) s i n _ Z s = t + 7I k 2 8 ( I

-

8 2)½

-

s

or

(I

We reduce this, always omitting higher powers of k2: e = sin[(l - 7: k 2 ) t

= sin(1 - 7I

k2 ) t

+ 7: k 2 e ( : + 7I

k2s(1 _

-

e2) %] s 2 ) ½ c o s ( l - 7I

k2)t

Let ~ = I - 7I k s , and in the small second term let s = sin~t, 1 s = sinmt + ~ k2sin mtcos2mt

so that finally

e = snt = (I Thus,

+ /~ k2)sin~t

+ /~

k2sinSmt + OCk~)

(2.29)

in lowest order, k 2 changes the amplitude and frequency and

introduces an anharmonicity.

The change

in frequency corresponds

the change in the p e r i o d of a p e n d u l u m found earlier. same p r o c e d u r e + cn2t = 1,

to

Now follow the

for cnt and check your results by v e r i f y i n g that sn2t

50

Problem

The general

2.11.

contains

solution of a second-order

two arbitrary constants.

equation

Show that the general

(2.8) can be written either as the sum of two elementary (x = A c o s ~ t + Bsinmt) (x = Csin~(t nonlinear Problem

- to)).

equations,

restoring

Remembering construct

An oscillator

2.12.

x = A.

or as a solution with displaced

force, F = - a x

solutions

origin

solution

of

(2.22b).

is made with a spring having a nonlinear It is started t = 0 with & = 0,

- b x 3.

How will

of

that snt and cnt satisfy different,

the general

Show that its subsequent

suitable ~ and k.

solution

motion

is given by x = A c n ~ t

the oscillator's

frequency

with a

depend on A

for small A? Problem

Show that the perimeter

2.13.

of an ellipse with semi-axes

a and b is

i~/2 P =

4a

where k is the eccentricity, complete

elliptic

integral

kind of function gets Problem

2.14

aided by

(I

- k2sin2~)½d~

k2 =

1 - b 2 / a 2.

t

The integral

of the second kind,

defines

its name.

Starting from the equation derived in Prob.

.

(2.13),

a

and shows how this

derive

(2.22)

[Remember that the constant

2.7 and

directly by change of variable.

factor

(g/h) ½

was omitted

in writing

(2.19) .] Problem

The amplitude,

2.15.

function

am, of the argument of an elliptic

is defined by snt = sin amt,

cnt = cos amt

Show that amt is the ¢ defined by amt =

t + ~1 k 2 s i n 2 ~ t

+

...

d -d~ a m t

2.4

(2.16) and that

~ =

1

- ~1 k 2 +

...

(2.30) = dnt

Driven Oscillators When an oscillator

resonance occur.

is driven by an outside

The case familiar

which the driving force f(t)

force, phenomena

from elementary physics

is sinusoidal

and applied

of

is that in

for a long time.

51 We shall discuss the harmonic oscillator arbitrary f(t)

in the more general case of

and then give an elementary treatment of resonance to

an applied sinusoidal

force in an anharmonic oscillator,

in which

some entirely new phenomena occur.

Driven Harmonic

Oscillator

If a damped harmonic oscillator

is driven by a sinusoidal

it will resonate if the frequency is right.

force

Here we shall discuss

the more general situation in which the force per unit mass is an arbitrary function f(t).

The equation to be solved is

+ 2r~ + ~ x where r represents

(2.31)

= f(t)

the resistance due to friction.

The general

solution for the motion without an applied force is

x(t) = (acosmlt + bsinmit)e -rt

(2.32)

where a and b are constants, ~i = ~

- r21½

(2.33)

and the cosine and sine are replaced by hyperbolic large enough to make ~i imaginary.

functions

We are going to solve

if r is

(2.311 by

assuming that the oscillating particle's present position at time t is produced by the entire past history of the force f(t), and there is an influence

function ~ which tells how the value of f at a particular

past moment t' influences

the present value of x(t).

The obvious

formula that embodies these ideals is

(t

x(t)=

- t')f(t')dt'

(2.541

~

where

the

lower

limit

is

taken

as

-~ for

convenience

only,

any fixed value. Differentiating

~(t)

(2.341 gives

= ¢(O)f(t)

~(t I = ~(O)f(t)

+ f$(t

+ $(O)f(tl

- t'lf(t')dt'

+ I~(t - t')f(t')dt' J

and may be

52

Substitution +

into the original

2 r .~ + ~

equation

= ~(o)~(t) 2r$(t

+

(2.31) gives

[~(o3 + 2r~CO)]fCt) + I [ $ ( t

- t') + o~#(t

and this is satisfied provided

- t')]f(t')dt'

that ~ satisfies

t') +

= fCt)

(2.31) with f = O,

together with the boundary conditions ~(0)

Given the general

= O,

solution

$(0)

= 1

(2.35)

(2.32), this is easy to arrange:

O(z) -- ~'le-rrsinmlr

T = t - t'

(2.36)

I

and the general

solution

for all the oscillator's

x(t)

of (2.31),

assuming

present motion,

Ite_r(t_t,)sinm1(t

=

that the force f accounts

is

-

t')

Note the role of the resistance

r here:

long,

and the corresponding

the exponential

have little forgets

feature

2.16.

that

if the interval

on the present x(t).

its ancient history.

peculiar

Problem

influence

is small,

t - t' is

values

of f(t')

That is, the oscillator

The idealized case with r = 0 has the

such an oscillator

Show that

(2.373

f(t')dt'

(2.32)

forgets nothing.

is the general

solution

of (2.31)

when f = 0.

Problem

2.17.

A hammer blow at time tostarted

the oscillator moving.

The force of the blow was such that the hammer, with velocity v, was brought

Problem

2.18.

additional

A sinusoidally

cube-law restoring

to rest.

Where

is the oscillator

driven anharmonic force

-ex 3.

of mass m travelling

oscillator

now?

has an

Write the equation

of

motion as

+ ~ X = -ex 3 + focos~t and find the first-order solution x 0 without

perturbed

f0 = const. solution x = x 0 + xlby finding a

s and then letting

53

x2(t)

We shall discuss Problem

=

(t - t ' ) [ - E x a ( t ' ) ] d t

a nonperturbative

Let the applied

2.19.

f(t)

(2.38)

'

solution below.

force be a slow push of the form

= ct~le-(t-to)~/t~

centered at to, and let t - t o >> t I so that the push was completed long ago and the upper Discuss

in the light of common experience

according Problem

Discuss

2.20.

driving

Use the example

2.21.

discuss what oscillators Problem

the response

force f0cosmt

with negative Discuss

2.22.

If an anharmonic more interesting we illustrate

the response

to a to the

of a resistanceless

(i.e., nonlinear)

oscillator

is driven by a For convenience

case.

anharmonicity the equation

+ ~x the p a r a m e t e r

to

but they are considerably

than those of the linear oscillator.

so t h a t

oscillator

that was turned on at time t o .

with a simple

force,

to

in which mechanical

Oscillator

Let the oscillator's

be produced by a cubic

of motion is of the form

+ ex 3 = f0cos~t

e will not be considered

damping w o u l d only complicate (2.29)

of a driven harmonic oscillator

force there are resonance phenomena,

restoring

oscillator

r could be arranged.

force f0cos~t

A Driven Anharmonic

where

of the harmonic

(f0 const.), paying attention

life would be like in a laboratory

a sinusoidal

periodic

in behavior

to unity.

that r ~ may exceed m02 in (2.33)

possibility Problem

the difference

as ~Qt I is small or large compared

sinusoidal

2.5

limit of the integral may be replaced by ~.

the picture

(2.39) small.

To include

(Stoker 1950).

Equation

suggests we assume a solution of the form x = acos~t + b c o s 3 m t

Substitute

this

into

(2.39)

and reduce

+

...

the nonlinear

term by trigono-

54 metric -(~

-

+¥3 +

where

keeping only terms of frequency m and 3~:

identities, o~)~cos~t

-

(9o~ ~ -

a 3

g[(a 3 + a2b + 2ab2)cos~t

terms are of frequency

there is coupling between frequencies.

3)

+ b

cos3~t]

5m, 7~, and

the various modes, resonant

9~.

and driving

responses

Evidently the oscillator

at all the higher

Another way to put this is to say that the system has

resonant

frequencies

and can be made to oscillate

driving it at lower frequencies

called subharmonics.

in them by

The multiple

can be clearly heard in the ear, which for protective

purposes

is made highly nonlinear.

(monitor

it with an oscilloscope

still in the linear range!) heard corresponding resonating

+ 2a2b

(2.40)

with frequency ~ will produce

resonances

+ (~

foCOS~t

. . . .

the omitted

several

~)bcos3~t

to a sine-wave

and turns up the volume,

to the excitation

structures

The analysis

If one listens

to make sure that the amplifier of higher

tone is

a shrillness

frequencies

is

in the

of the inner ear.

of an equation like

study only the fundamental

(2.40)

resonance.

is wearisome;

let us

To do this we set b = 0 and

ignore the higher frequency:

(-~+¥s

~a2)a

=

A

fo

=

m2

2

-

¢00

or

3 ~a2 A = 2" This function

is sketched

easily-identified to a horizontal

points

in Fig.

-

f_o a

(2.41)

2.2 for E > 0 and ~

are labelled.

line at A = ~2 _ ~ .

A given value of ~ corresponds If one varies ~2, starting

negative values of A, there will be a steady-state remaining

motion,

at

but with a

finite as long as E is not zero, along the right-hand

branch of the curve.

If one starts

at large positive

there are three values of a possible, marked unstable

does not represent

shall see below that the slightest onto one of the stable branches correspond

> 0, and a few

to different modes,

values of A,

but the part of the curve

an observable

motion,

disturbance will

of the curve.

since we

throw the system

The two stable branches

in one of which the motion

is in phase

55

with the driving force while

in the other it is out of phase.

system is started at positive

\~

A in the out-of-phase

If the

mode and ~ is

#

ks~J

Figure 2.2

Sketch of A(a) with salient points noted.

decreased below the minimum value allowed for that mode, oscillator

will make an abrupt transition

Problem 2.23. Problem 2.24.

neighborhood difficult

Derive Eq.

C2.40).

Use (2.40)

to discuss

of ~1 m0"

CQuestions

the

to in-phase motion.

resonance

of stability

at frequencies

in the

of these resonances

are

and can be ignored.)

Problem 2.25.

Analyze

the nonlinear

taking both the anharmonicity

system by quantum mechanics,

and the driving force as perturbations.

(The way to do this is to let both perturbations

be turned on

adiabatically

from t = -~ and use time-dependent

perturbation

Problem 2.26.

What happens when the anharmonic

force is -ex 2

theory.)

instead of -ex3? The Question of Stability

Imagine that some part of a moving dynamical gently with a hammer. displacement

Three kinds of behavior

from the unperturbed

system is tapped

are possible:

path may become smaller

the

and smaller,

56 so that the effect of the perturbation ultimately disappears.

Or the

system may adopt a new motion that fluctuates around the unperturbed path but never goes far from it. away in a new path which, the old one.

Or finally, the system may wander

in time, takes it as far as one likes from

In this case the motion is said to be unstable;

two represent different kinds of stability.

the other

The criteria for different

kinds of stability have been variously stated and studied by some of the best mathematicians Lyapounov), mathematical

of the last hundred years

(Poincar6, Kolmogorov,

and it would be folly to go into generalities here, but facts known to most readers of this book are enough to

treat the stability of the anharmonic oscillator discussed above, 6 and in Sec. 8.4 we shall briefly mention a simpler case involving the free precession of a solid body. Let us suppose that the motion of an oscillator satisfying has been slightly perturbed, initially small,

(2.39)

so that x(t) becomes x(t)

(2.39)

+ ~(t), with

After the perturbation the system still satisfies

:

+ ~ + codex + ~) + sCx + ~)3 = focoscot If we keep only the first two terms in (x + ~)3 we find that ~, as long as it is small,

+

With x = a c o s c o t ,

(co~

+

(2.42)

and subtract

(2.39),

satisfies the linear equation

zex2)~

=

o

this is "~ +

(co:

3

3

+ "~ Ea 2 + ~

¢a2cOS2cot)(

(2.43)

= 0

The prototype of this equation is known as Mathieu's (Whittaker and Watson 1927, Mathews and Walker 1970).

equation

It is often

written in the standard form

d2~ dx 2 +

(a

+

6cos2x)~

=

0

x

= cot

(2.44)

It is a somewhat advanced topic in the theory of special functions, but the solutions have a qualitative feature that the reader may have encountered in another context.

d2~ + ~ m dx~ 6

Write it as

[E _ V(x)]~ = 0

(2.4S)

For a complete discussion see Bogoliubov and Mitropolsky 1961.

57

where

E

=

~2~ 2m

"

V

It is now the Schr6dinger periodic

lattice,

equation

has solutions

~2~ cos2x 2m

for a particle

8 in (2.44),

in a sinusoidally

x represents

is stable

is not especially

the time,

for large values of t.

series of which a few terms

!

t

-1

E for which the and we see

that,

there are only certain ranges of a for which

the solution

-,Z

(2 " 46)

remain finite in x lie in bands.

that

context,

of stability

Figure 2.3

-

and we know that the eigenvalues

In the present for a given

equation

=

simple,

To derive

these limits

but they can be expressed

are shown in Fig.

as

2.3.

|

0

1

Stable and unstable regions

2

3

~x

of the ~8 plane together with approximate

expressions for their boundaries.

The question before us is to see under what circumstances solutions

of (2.43)

comparing with

are stable.

(2.44) £02C~ =

3 6002 + ~e(~ 2 ,

L028

=

3 ~- c a 2

(2.47)

that ~ lie in the lowest stable band can be

in Fig.

~2~ or by (2.47)

the

and

gives

Since a > 0, the condition read off the curves

Setting x = ~t in (2.43)

2.3, <

~2

_

~

B

-

.

.

.

58

~

By (2.41),

3 ~ 2 < ~2 - ~3

+ ~

and neglecting

+

the higher terms, this is Ea

2

<

-

2

a

We can express f0 in terms of the amplitude the left-hand branch of the resonance

fo = - ~

...

s ~a~

a I in Fig.

2.2 at which

curve has its minimum,

given by

(aI < o)

Thus

a ~ < ~-=

whence

lal 3 < la, l 3

or

I~I for stability. placed

<

I~I

(2.48)

If the oscillator were to start with parameters

it exactly on the unstable branch of Fig.

that

2.2, it would in

principle

remain there, but only in the sense that a pencil can in

principle

(if one ignores quantum effects)

The slightest perturbation stable branches--how

the transition

choice would be an interesting Problem

2.27.

be balanced

on its point.

would cause it to jump to one of the is made and what determines

exercise

in machine

the

computation.

Develop the theory of the driven anharmonic

oscillator

for e < 0. Problem

2.28.

tions made, Problem

2.29.

oscillator

Show that in the region of validity

the entire right-hand branch

of the approxima-

is stable.

Study the effect of damping proportional

considered

to & in the

above. ~

See Landau and Lifschitz 1969; Stoker 1960. nonlinear mechanics is given by N. Minorsky Murphy 1964.

A good survey of in Margenau and

59

2.6

,

Lagrange's

Equations

The last two calculations linear and angular, be used at once, polar

eventually

and in the next one, planetary motion,

since the planet's position

coordinates.

ing successively

have used two kinds of coordinates,

We could perfectly well go on for a while,

more complicated

systems by ad-hoc methods,

the returns would diminish,

start using more general methods. here.

in treat-

but

and it would be necessary

to

We are going to start using them

The first will be a simple and general way of introducing

different

kinds of coordinates

into the equations

of motion.

subsequent

chapters we shall start looking at ways

solutions,

not just the equations,

x, y, and z coordinates

to construct

system in which

function

the

of all the particles

kinetic energy can be written

the forces can

We shail denote

V(x).

giving it an index where necessary:

system's

In

with a minimum of labor.

Let us start with an N-particle be derived from a potential x,

both will

is to be specified

i = I ... 3N.

xi,

the

by the general

letter The

in the form

3N

T =

T__.

(2.49)

i=1 and w i t h this we define the lagrangian

L(x, resembling

function

(z .so)

~] = T(~:] - V(x)

the energy except for a change

in sign.

Newton's

equations

of motion can now be written as

~L ~x i

which we abbreviate

d

~L

- avaxi-~'-i~-'~--= 0

=

0

i

Two facts flow from this formula. a variational

I ....

in our earlier notation 6L 6x.

analogous

i =

formulation

=

3N

(l.40b) 1

. . . .

as

3N

(2.51]

The first is that L can be used in

of the laws of motion that will be closely

to Fermat's principle

fundamental

similarity

description

in terms of waves.

in optics.

of mechanics

We have already

and optics starting

This new analogy

seen the

from their

is historically

far

60

older, and it will enable us to approach from the principles

the same similarity

starting

formulated by Fermat and Newton in the 17th

century. The second important be generalized

fact about

(2.51)

is that it can immediately

to other kinds of coordinates.

f degrees of freedom;

Suppose the system has

that is, suppose that it requires f numbers

ql' ... qf to specify where everything is. If the system is a gas, every atom moves separately and f will be about 1023 If it is a rigid pendulum

Ca real one, not a point mass on a weightless

cord)

there may still be 1023 atoms but the position of every one is determined

as soon as the pendulum's

Thus, f ~ 3N, and in expressing ql'

angular orientation

the coordinates

is given.

x i in terms of

... qf we will usually be able to introduce economies.

obviously

true for solid bodies,

but even for a system

system we shall profit from being able to separate the center of mass,

This is

like the solar

out the motion of

since no aspect of the solar system

that interests

us depends on how the whole thing is moving through space. The remarkable

feature of Lagrange's

equations

that is now to be

proved is that if we write

x i = xiCql . . . . or xCq)

for short,

qf)

the functional

i = I .... derivative

3N

of L with respect

to q

becomes ~N 6L

~qn so that from

i=I

9x. n

=

I ....

f

(2.51) we can conclude

exactly the same form in generalized

SZCq, ~) _6q n

that the laws of motion take coordinates,

o

n

=

i ....

f

In writing down the proof we shall use the summation in any expression

a certain index occurs twice,

be summed over the range of that index:

6L 6qn

6L

convention:

equation

<2.52),

~x i

=

n

6xi ~qn

=

I,

(2.53)

the expression

becomes - -

<2.s2)

~qn

...

f

if

is to

for example,

81

In these expressions summation

i runs

from I to 3N; m and n from I to f.

is over i and not over n.

~L

~L

To change variables we have

~x.

~L

-

~xi ~qn

In the last term interchange

xi

~.

+

~qn

Since

The

~xi ~qn

order of differentiation:

~L

9L

~x.

~qn

~xi ~qn

~L

+

d

~x.

~xi dt ~qn

does not depend on @, we have next

To simplify

~L

~L

~.

~qn

~xi ~qn

this we note that

qm ~qm so that differentiating

with respect

to one of the q's, say

qn'

gives

We can now assemble

~B.

~x.

~qn

~qn

the foregoing

~xz. +

~L

d ~L

~L

~qn

dt ~qn

~xi ~qn

dt

which

is (2.52),

1760 he actually

as promised.

into

~L d 9x.z

d f~L ~xil

~xi dt ~qn

dt \~x i

K/

~qn

When Lagrange

gave these equations

gave more than we have given here,

in

since he included

62 the possibility of nonconservative

forces.

its derivation are given in many books,

The more general form and

e.g. Goldstein

(1951).

Before applying Lagrange's equations we note by comparison with (1.47) the single variational principle by which all f equations of motion can be expressed:

I L[q(t), ~(t)]dt

=

0

(2.S4)

where the q's are not to be varied at the endpoints. was given by Hamilton in 1834. 8 the principle of least action;

the former is more exact because the

integral is not necessarily a minimum. segment of the path minimizes

In this form it

It is called Hamilton's principle or As in optics,

any small

the integral, but the whole path may

make it a maximum or a point of inflection.

"Stationary action" would

be better, but it is rarely used. There is obviously a certain difficulty of physical tion if Hamilton's principle mechanics:

is taken as the fundamental

interpretalaw of

since both endpoints are fixed a system has to know where

it is going to end up before it starts, merely chooses

and the dynamical principle

the right way to get there.

P. L. M. de Maupertuis,

The French mathematician

who made the first sketch of a principle of

least action in 1744, was well aware of the implication and was proud to have shown how the science of mechanics explains the working of God's plan for the universe and so beautiful,

(Maupertuis

1752):

"These laws, so simple

are perhaps the only ones that the Creator needed to

produce all the phenomena of the visible world."

We shall see in

Sec. 6.7 that there is another way to explain the physical content of the action principle:

a particle tries everything.

Suppose we add to L the time derivative

of any function of q and

t:

L(q,q~ ÷ LCq, 4) + FCq, t) Since the integral in (2.54) is not varied,

involves F evaluated at the ends where q

the addition does not change the content of the

equations of motion in any way,

though it changes their form and may,

with suitable F, be used to simplify them.

We shall see how this is

done in Sec. 4.3. Finally, we note that since by hypothesis neither T nor V involves

t, we can use the theorem of (1.43) to derive the existence

of a constant of the motion, 8

W. R. Hamilton,

Phil. Trans. Roy. Soc.

(1834),

II, 247.

63 ~L qn ~

~qn This

(2.ss)

- L = E (const.)

is the energy integral.

Problem

2.30.

coordinates

Verify

Then set up Lagrange's and show t h a t Problem

masses

that if the q's are taken to be the Cartesian

x i of an N-particle

equations

E is again

for the simple pendulum

of the m o y a S l e ~J~LWJ2

total energy. of Sec.

2.2

the energy.

The device of Fig.

2.31.

E is the system's

system,

elements,

2.4,

in which

the numbers

is constructed

and let go.

give the Neglecting

2J JFi2 IWF2W/WI Pl

Figure 2,4

the rotational

inertia of the pulleys,

To ~llustrate ProSlem 2.31.

find the acceleration

of the

5-unit mass. There is another way in which constants found.

Suppose that L does not explicitly

coordinates,

say qm" d

9L

dt

-~qm

Then

of the motion can be

involve

one of the

(2.53) becomes ~L

- O,

= Pm

(const.)

~qm

A familiar example is the flight of a projectile, where the potential energy depends

on the height but not the

horizontal

coordinate x.

Thus

L = ½ m(,~ 2 + #2)

VCy),

and Px = m~ = const.

9L/~x

= 0

64 This is the momentum corresponding general Pm a momentum also; ing to (or conjugate

to x, and in its honor we call the

it is the generalized momentum correspond-

to) the generalized

coordinate

qm"

The missing

qm is traditionally called an ignorable coordinate or a coordinate. We shall look carefully for them in what follows,

coordinate

cyclic

for conservation

2.7

laws are of great importance

in physics.

The Double Pendulum To show how Lagrange's

equations

worked out in complete detail. suspended

are used, here is an example

Suppose that one simple pendulum

from another and both are set swinging

in such a way that they swing periodically other conditions Sec. 3.3.)

is

through small angles,

thereafter.

(There are

after which they do not swing periodically--see

The periodic modes of motion are called normal modes.

Figure 2,5 Ca) shows the coordinates.

To simplify

formulas we shall

O

(b) Figure 2,5

Double pendulum.

assume that m I >> m 2 and that £2 > £I" the Cartesian coordinates x I

=

x 2 =

With respect to the origin 0,

of the two masses

are

h/sine/

Yl

hlsin@/ + Z2sine~

y~ = - (£1cos@l + £gcose~)

=

-

~lCOS@l

and from these we find easily that ,2

Xl

.2

+

Yl

2"2

=

£101

• 2 ,2 2~2 2'2 x2 + Y2 = £1 + £282 + £1£2c°s(01

*

- 02)@102

65 so that the L a g r a n g i a n L = T - V is 2.2

2

2

m2(Z1~)l

L = ½ m1,£101 + ½

2.2

+

,£202

+

£1~2cos(01 - 02)5102)

+ mlg£1cosO 1 + mgg(~lCOS01 + £2COS02) Now we make the s m a l l - a n g l e

approximation.

Retaining only quadratic

terms, we have 2,2

2"2

-

L = ½ m129~i01 + ½ m2(~202 + .£i.%20102)

½ m12g£101

- ½ m2g£2O 2

(2.s6) plus a constant,

where m12 = m I + m 2.

Lagrange's

equations

of motion

are

m12£lO 1 + ½ m2~20 2 + ml2gO 1 = 0

(2.57) m2£20 2 + ½ m2£101 Except

for the small-angle

Now we state that

O1 where

=

approximation,

these are exact.

the desired solution

alcos(mt

@ is arbitrary

(2.57)

+ m2gO 2 = 0

+

¢),

is periodic

in ~,

02 = a 2 c o s ( ~ t + @)

and ~ is to be determined.

Substitution

into

gives

m12(g

- Stlos2)aI - ½ m2£2~o2a 2 = 0

(2.s8) -

For these, at all,

½ m2£1~o2a I + m2Cg - ;L2~o2)a2 = 0

considered

in e2 whose solutions

092 =

as equations

their determinant

/

in a I and a2,

must vanish.

to have any solution

This gives a quadratic

equation

are

{m12(~,1 + ~2 ) + [m;2(~ 2 - ~,1)~ + m12m2~1~2 ]½} (2.59a)

66

Our simplifying

assumptions

allow us to write

I m2 + ~ )

(I 2m12LaZ ~

+-m12(~ ~ - ~ : ) [ :

+

m211£ 2

m12(ft2 - £i)2:

<<

{m12(~1 + ~2) m2~l~ 2 ]} + ... 2m:2(~ 2 _ ~ : ) 2

or

I~

m2

(I +

~2

+ ...)

4m12 ~2 - ~I (2.59b)

Li2

(I -

m2 ~I 4m12 ~2 - ~1

+ ...)

There are thus two normal modes, with frequencies of the individual pendulums. the first

(larger)

move, we set

value of ~2 into the first of (2.58):

a2 = _ whereas

quite close to those

To see how the pendumums

_

al

~2 = 9___

(2.60a)

al

~2 = .q

(2.60b)

for the lower frequency,

2m12 ~2 - ~I

a2

m2 The first one looks

like Fig.

the two normal modes pendulums

~2

i2 2.5(b);

the second looks like

are clearly distinguished,

are exactly

(a), and

for in one the

in phase and in the other they are exactly out

of phase.

Note:

In the following problems

instabilities

potential

may arise as in Fig.

2.6a,b.

energy curves with central In the first case we have

an integral of the form

I

dx

1

(2.61a)

wxI

w)1 I

67 where

k = xl/x 2.

To reduce

this to standard

form, make the substitu-

tion u =

(I

-

k'2v2)

k '2

½

=

I

-

k2

(2.61b)

The second case gives rise to 1

du (2.61o)

[(I

- u2)CZ< '2 + k 2 u 2 ) ] ~

0 In this,

let u =

The 24 possible Tables

substitutions

(I

-

v~) ~

C2.61d)

of this type are given in Peirce's

(Peirce and Foster 1957).

Problem

2.32.

What have

the formulas

the situations

illustrated

Problem

Analyze

2.33.

in Fig.

the behavior

(2.61a)

and (2.61c)

of the system shown

,

VC~i

to do with

2.6a,b? in Fig. 2.6c as

}~

k

m

V(x)

~

E

E

Figure 2.6

F

i

Xi

Xz

~¢

(a,b) Potential energy curve with a central maximum, showing discontinuous behavior as E increases. (c) To illustrate Problem 2.33.

completely

as you can.

Assume

enough so that the springs Problem

2.34.

Fig.

length is ~.

@ and find the equilibrium. equilibrium.

distances

are long

horizontal.

2.7 shows an inverted pendulum of length

supported by a stiff spring unstressed

that the horizontal

remain effectively

(to keep the angles small) whose

Sketch

(approximate)

the potential

points

Find the frequency

at which

energy as a function of the pendulum

of small oscillations

is in

around the

68

"II]IIIII

lllllllilllJll

III

II

e -. . . . . . . . . . . . . ~ , ~ ,JJ ,~..I rJISS" Figure 2.7

Problem 2.35.

Discuss

To illustrate Problem 2.34.

the motion of the system in Fig. 2.7 if the

ceiling height is increased

to 3Z but none of the other parameters

are

changed.

2.8

Planets

and Atoms

The determination

of orbits under a central

inverse square of the radius problem in physics. calculated

is historically

In Newton's

Prineipia,

and observed positions

the agreement

system.

In the history of quantum mechanics formula successively

the entire

it was the derivation

by Bohr using his semi-classical

Pauli and Dirac using quantum mechanics,

as the

of the

of the planets validated

Balmer's mechanics

force varying

the most important

and Schr~dinger

that first convinced people of the importance

of

theory,

using wave of these

theories. In quantum mechanics energies

the calculation

is straightforward.

the planet an equation

of wave functions

In classical mechanics

is at a given time.

scattering

Let us first assume

it was hard to solve

We shall derive an approximation.

if the energy of the system is positive, formula for Coulomb

one asks where

The answer hinges on the solution of

first given by Kepler in about 1609;

then and it is hard now.

and

Finally,

we can derive Rutherford's

as a bonus.

that the sun, or the nucleus,

is clamped.

We shall see in Sec. 3.2 that nothing changes much if it is allowed to move. We choose the origin at the center of force polar coordinates, plane

(why?).

(Fig. 2.8), use

and note that the orbit all lies in the same

The lagrangian

½ m(~,2

is + r202)

-

V(r)

(2.62)

69

where

V(r) is the gravitational

may be some other central

or electrostatic

force altogether.

potential,

Lagrange's

or it

equations

are

W%

9

Figure 2.8

second-order

Particle of mass m orbiting an attractive center.

equations

for r and 8; there are four time derivatives

and there will be four constants as a fourth-order complicated,

system.

of motion.

We speak of the equations

Such a thing is liable to be quite

and we search for ways to solve

it stepwise.

The Angular Motion Let us look first at the equation on 8, @ is cyclic,

in 8.

Since V does not depend

and Pe = mr2e = L ( c o n s t . )

Pe = O,

(2.62;)

The quantity P8 is the m o m e n t u m

conjugate

briefly,

The use of L for the numerical

the angular momentum.

of the angular momentum confusion.

as well

Its conservation

integration.

as the lagrangian

should cause no of

is of the third order.

Problem 2.36.

It

with direction

as well as a magnitude

usual

value

in this case has given us a constant

The remaining p r o b l e m

is

to the angle 8; more

in physics

to equip angular momentum

and make it a vector perpendicu-

lar to the orbital plane by writing Pe = m r x ~ Show that the magnitude

Problem 2.39.

of P8 thus defined

(2.64) is mr2e.

Show that if the force is directed

towards

or away

from the point r = 0,

@8 dt

-

0

(2.65)

70 The angular m o m e n t u m geometrical meaning (Fig. 2.9)

is a dynamical

also.

quantity but it has a

Suppose the planet moves from a to b

in a time dt, so that its radius

Figure 2.9

sweeps out an area

Relation between area and angular momentum.

½ r2dO. The rate at which this area is swept out is dd A t

This is Kepler's

second law

general derivation force;

-

r 2 0• =

½

(const.)

L

(Kepler 1609, p. 165) 9

than the other two,

laws 1 and 3 require

It is of more

for it requires

only a central

that the force be inverse-square.

To find r, we use another constant are usually called integrals

of the motion

of the motion).

= >~ m ( ~ 2 + r ~

and incorporating

(2.66)

the integral

(such constants

This one is the energy

(2.67)

2) + v(r)

just found gives t 2

(2.68)

E = ½ m~ 2 + ~-NF~+ v ( r )

Comparing

this with

taking place

(2.10), we see that it is as if the motion were

in one dimension

instead of two,

in an effective

potential t 2

Vef f = ~

If V(r) is an attractive Vef f looks like Fig. s

potential

2.10.

+ V(r)

(2.69)

of the form -y/r, a graph of

Suppose the energy E of the orbiting

Readers who have momentarily forgotten in almost any elementary physics text.

Kepler's

laws can find them

71

planet

is negative.

oscillator:

The situation

outside

resembles

that of a harmonic

the region between r I and r 2 the kinetic energy

P

E

Figure 2.10

Effective potential for an attractive inverse-square force.

w o u l d be negative. quantum mechanics between r I and r2, there

In classical mechanics the wave function

the planet oscillates

linear oscillator? at a varying appear

rate,

strongly.

back and forth.

is still a minimum r I but the planet How would one have to observe

this is impossible while

decreases

in

Trapped If E ~ 0

is unbound.

the planet

for it to look like a

One would have to stand at the sun and turn around always

to be subject

facing the planet.

The planet would then

to the force d~ff Feff . . . .

L2

dV

mr 3 - d-~

(2.69a)

dr

In terms of angular velocity,

the first part of Fef f is

L 2

mrS2

mr3

This

is the centrifugal

in elementary effects,

an object of confusion

We see that it is a real force, with observable

which one encounters

coordinate

Problem

classes.

force that is sometimes

if one places oneself

in a rotating

system.

2.38.

The planet

in the potential well will oscillate back

and forth at a certain frequency. same as the frequency

If this happens

of the angular motion,

to be exactly the

the planet will return to

its original position with its original velocity

at the end of a cycle.

72 The orbit repeats only vary slightly

and is called re-entrant. from a circle,

Considering

orbits

fit a harmonic potential

that

to the

bottom of the effective potential well and see if this is true for inverse-square

motion.

The R a d i a l M o t i o n

The next step in solving the Kepler problem is to solve for ~ and separate

(2.68)

the variables:

dr

v(r) ) - ~

[~(E-

There are now two reasonable Program

A.

Integrate

]%

programs

t

-

t o

( 2 . 703

that might be followed:

(2.70) to get t(r).

to find @(t) integrate

=

(2.713

o - e o = ~- r ~ [ t )

Program

B.

Then

Invert to find r(t).

~ = L/mr2:

Find the orbit first.

Since dr/dt

= (L/mr2)dr/dO,

(2.68)

-

(2.72)

gives

dr [2mr~ L2 Integrate writing

(E - V ( r ) )

this to get O(r),

r~] ½

=

13

0 0

invert to get r(O) and introduce

t by

L = mr20:

t-to= This gives t(@).

/m

r 2 (O)dO

(2.753

Solve for @(t) and put into r(@) to get r(t).

Program A fails at the second step

(Problem 2.39).

t(r) but cannot solve it (at least, not in closed form) Program B can be carried a little further.

= ~±~ 2 V(r)

=

-x/r

y

L ~Mm

Putting

We can find to find

r(t).

73

we find an integral

that can be e v a l u a t e d and inverted to give

r(O)

= L,2/m,,Y 1 - ecosO

(2.74a)

w h e r e e r e p r e s e n t s not electric charge but eccentricity:

2EL 2 ]½ e =

The orbit is a conic section: 2.41),

[1

+

for E < 0 ,

an ellipse

e < I

(see Prob.

a p a r a b o l a for E = 0, e = 1, and a h y p e r b o l a for E > 0, e > 1.

For b o u n d orbits we have derived Kepler's p.

(2.74b)

mY 2

first law

(Kepler 1609,

28S).

For e l l i p t i c a l orbits

(E < 0), the semi-axes

are

L a =

Y -2E

b =

"

(2.75a,b)

(_2mE)½

From the first one, we see that E = -y/2a;

the energy depends only on

the major axis and not at all on the eccentricity. Bohr theory can derive all the energy

(This is why the

levels of h y d r o g e n by consider-

ing only the circular orbits.)

Problem

2.39.

Verify the failure of P r o g r a m A.

Problem

2.40.

Derive

Problem

2.41.

S t a r t i n g from x2/a 2 + y2/b2

(2.74a,b).

e c c e n t r i c i t y as e = (I

= I and the d e f i n i t i o n of

b2/a2) ½, show that (2.74a) r e p r e s e n t s an

ellipse w i t h the origin at one focus.

Find the expressions

(2.75a,b)

for the semi-axes.

Problem For what

2.42.

Suppose that V(r) varies as a power of r: V(r)= kr n.

(positive and negative)

(i.e., closed)?

integral in (2.72) giving @(r) trigonometric in

values of n are the orbits re-entrant

This is the same as:

functions?

for what values of n can the

[or r(@)]

be expressed in terms of

It will be convenient

to change the v a r i a b l e

(2.72) to u = r -I. Having found the orbits, we must now find how they are traversed.

The total time of r e v o l u t i o n is easily d e t e r m i n e d from the area law (2.66): 2~ym ½

T = 2m x ~ab L

(2.76) (_2E)3~

74

and s u b s t i t u t i n g

-2E

from

(2.75a)

gives m ½ a 3~ (F)

r = 2~

(2.773

The period depends only on the energy or only on the major axis. p l a n e t a r y motion,

y = GMm

and 2~

r

This

is

almost

Kepler's

For

third

= -(GM) - ½ law.

instead of the semi-major axis

a3/2

Kepler

(2.783 has

the

mean o r b i t a l

radius

(Kepler 1619, p. 189), but the p l a n e t a r y

orbits are so nearly circular that it makes

little difference.

To continue with P r o g r a m B, we return to

(2.73), w h i c h w i t h

t o = 0 is

This

c a n be

t =

(:

integrated,

but

-

[

e 2 ) 3/2

the

de

(2.79)

(1 _ e c o s O ) 2

results

cannot

be solved

for

oct),

so

Program B comes to a halt unless we are w i l l i n g to get our hands dirty.

Problem

3.43.

Carry out the integration in (2.79) and expand the

result to show that for small e,

3

~t = @ + 2esin@ +-: e2sin2@ +

•

•

•

4

where ~ is the mean orbital

(2.8o)

frequency (2.81)

Problem

3.44.

Solve

@ =

Problem

2.45.

(2.80)

~t

-

to get

2esin~t

8

+ -~ e 2 s i n 2 ~ t

+

...

(2.82)

Complete Program B by e v a l u a t i n g

r =

(I

- e2)a(1

~2

+

ecose + e2cos2@ + ...) e 2

r -- a(1 + ~ - + ecos~t - ~ - cos2~t + ...)

(2.83)

75

and verify that 0 and r are correctly elliptical

given at the two ends of the

orbit, where they can be evaluated by elementary

At this point we run out of results pencil

and paper.

developments

Astronomers

much further

of great m a t h e m a t i c a l has largely

2.9

and introduced

interest

Oscillations

We have m e n t i o n e d radial

(More c o m p l i c a t e d The situation

methods

in Problem

2.38 that a chosed orbit can be

while

carries

out a whole number of

the angular variable

closed orbits

result

runs from 0 to 2~.

if the angle is 4~, 6~, etc.)

questions

seen in (2.69a)

force is subject

of stability

that a particle

to a radial

orbits, and we are

as well. in orbital motion under

force

L2 ~-T - V' (r)

(m = I)

and the orbit will be a circle of radius a if Fef f is zero, to increase nor decrease

tending

the radius,

n 2

a--~- - V' (a) = 0 To study small variations

(2.84)

from circular motion,

(a << a) and expand Fef f around r = a. equal

that are

and Stability

Fef f =

neither

to

1892), but today the computer

is easily studied for nearly circular

led to interesting We have

computational

(Poincar~

as one in which a particle

oscillations

a central

that are easily accessible

of the last century carried the series

taken over the work of calculation.

Orbital

regarded

geometry.

to 1 for simplicity

Setting

let r = a + a the particle's

mass

gives L 2

3L 2

o r by ( 2 . 8 4 ] , =

-

[v"(a)

+ ka

V'(a)]c~

(2.8s]

If

~osc2 a oscillates

~ V"(a)

+ 73 V' (a) > 0

with a frequency ~osc"

ture from circular motion will

(stable)

If m o s ~ < 0 the slightest

grow exponentially

(2.86) depar-

and the particle

76

will wander

away from its

The orbital

circular

frequency

~orb and one finds frequencies

orbit.

is readily obtained

from

[2.84),

2= L v' (a) a

at once that if V(r)

the orbital

= -y/r,

and oscillatory

are the same.

Suppose now that a slight inverse-cube

the force is not exactly

inverse-square

but has

part,

v(r)

=

-

J

morb

~ r- -

r2

e > 0

(2.87)

We find 2

2

LOOSC = ~

The period of a radial oscillation

T°sc and in this time the planet's

morbTosc

=

_y_ +

2_~

a3

a4

is

~osc angular position

advances

by

= 2~(a__=_~)9(a_~ 3 + 2e]ga,, = 2~(1 + ~_~)2~½ 2~ + Ya

Because morbTosc

> 2~, the orbit has

precessed

forward through an

angle ~8 when r resumes general

its initial value.

relativity

introduces

2~e =

ya In Sec.

5.3 it will be seen that

just such a p e r t u r b a t i o n into V(r),

with =

if, a s here,

the particle

3¥2/o

2

has unit mass.

60 = s n a g ao

2

This yields

a precession

(2.88)

77

an estimate still not exact enough to compare with observation since it applies only to infinitesimal and the orbit of Mercury, appreciably flattened. Sec.

deviations

from a circular orbit,

in which the effect is largest,

is

An exact calculation will be performed in

5.3.

Problem 2.46.

For what power-law central forces are all circular

orbits stable? Problem

2.10

For

2.47.

potential

what values of a a r e

V(r) = -ge-Mr/r

Orbital Motion:

circular orbits

in a Yukawa

stable?

Vectorial

Integrals and Hyperbolic Orbits

We close the discussion of orbital motion by showing that

there

is another integral independent of E and L which can be used to simplify the integration of the orbital equations

even further.

We

start with the equation of motion in vectorial form, r

and the formula

(2.64) for the constant vectorial angular momentum, mrX~ :

L

Form ~XL :

By the vector

m~X[rx~]

-

rx[rx~]

~

identity ax[bxc]

we

:

-- ( a . c ) b

-

(a-b)(

(2.89)

have

I r-7

rxCrx~]

:

- F IT

:

-

[ra~-

(r.~)r]

r.~ [7-

-yr

r]

:

-

d

r

dt

r

(2.90)

Therefore 'rXL =

d r

(rXL)

= Y dt r

Lx~

y r

and so the vector A

=

+

(2.91)

r

is

a constant

vector

in

the

plane

of

the

orbit.

To f i n d

the

78 planetary

orbit,

take the dot product

of this equation with mr.

Since mr-~xL

= mrx~.L = L 2

we have = mA.r = m A r c o s O

-L 2 + m y r

where

@ is the angle between A and r.

Solving

for r gives

LZ/my

r

(2.92)

=

1 - y-IAcos@ This

is the same as

(2.74a)

if A = ye

and we see also from ellipse

in the direction

aphelion, vol.

(2.92)

Fig.

i, pp.

2.11.

160-168.

that A points

of the point

The foregoing LaplaceV~

Figure 2.11 here,

(2.93)

furthest

analysis

analysis

from the "sun," the

is due to Laplace

is essentially

in 1710.

Because

lifetime,

letter commenting lation into modern Hamilton,

terms.

Laplace's Pauli,

What has been accomplished

values.

by so well

of integration were used

we give in Box I Bernoulli's

Lenz,

integral of the equations integrals

analysis

discussion

in a

on an earlier attempt by Jakob Hermann and a trans-

Runge,

vector

is known by every name but

....

here by the discovery

of motion

A, L, and E are specified

mentioned below),

that used

the method used illustrates

the virtuosity with which simple methods during Newton's

(1798),

The vectorial integral A.

but the result is already latent in a brilliant

Johann Bernoulli

his:

from the origin of the

is that,

of a new

if the values of the

(subject to restrictions

there is only one orbit compatible with these

We shall not often be so lucky, but in Sec.

5.7 it will

79 IIIII1111

IIII

II

BOX

From Bernoulli~s

letter to Hermann,

7 Oct.

I

1710"

Dans v6tre 6quation differentio- differentiel~e

-

-

~eddx - - -

(ydx -- xdy) × (xydx -- xxdy): (xxq-yy) ~ je ne mets pas feulement [ comme vous] - - a d x pour l'integrale de _ _ a d d x , mais ~ a d x ~___une quantit~ conftante, c ' e f i - a dire, --adx ~ e (ydx--xdy); pour le retie je le fais comme vous ; de forte qu'en int6grant vbtre pr6c6dente 6quation differentio-differentielle, je trouve ~ ,*dx -+ e ( y d x y (ydx__xdy): s/ ( x x q - - y y ) ~__ (xydy ¢ (xx+yy), ou--abdx: x x -~- el, ( y d x x x ~ ( k x T d ; -- b y y d x ) : x x ~ / ( x x . + y y ) , d o n t l'intbgrale eft a b : x ~___eby : x ~__ c ~ l, q' ( x x - b y y ) : x c'cfi-~-dire ( en prenant k ~ e b , & en reduifant l'6quation) b ~ by ~ c x ~ _ b" ~/( x x "b y y ) : laquelle bquation, quoiqu'elle renkbrme ,by, que la v6tre ne renfermoit pas, e~ ce--xdy)~__--

~yydx): -xd;):

pendant [comme elle] aUK trois Se&ions Coniques. 1:he e q u a t i o n

in x is

m~ = - ~r Write this, for reasons w h i c h will be clear in a moment, rn~ = - -~--~-xQYF:r-3 x'v "~"2 Z2

or

=

-a~

x(~k

-

(y&

= ft/m = const.)

-x~

a

~.)2

=--

r3 This integrates

directly

as

£2

my

to -c&~ = - Y (Yx - x ~ ) + const. r

The trick is to w r i t e the constant as ; e ~ x factor b x - 2 : _ ab~

± eb.

and introduce

y~ - x~ = _ by C~

X2 Once more, everything

- ~)

X2

can be integrated. ab ¥ h ~ = x x

the integrating

- x~)

x2r Let e b = h.

b ~ ± const, x

c

Fhus br

with h and c arbitrary. h = ebcos~,

+- hy +- c x = a b

Take C = ebsin~,

y = rsinS,

m = rcosO

Then a r = I + esin(@ + ~) By introducing the arbitrary constants h and c we have introduced e and ~, w h i c h specify the eccentricity and the direction of the line of apsides.

J. Bernoulli.

Collected Works

~Lausanne.

1742) v. i, p. 471.

80 become clear that even if the orbit is not uniquely is at least restricted within certain

determined,

it

that

limits by the integrals

can be found.

Problem 2.48.

Show that A2

=

2E

y2

L z +

(2.94)

m

It has been mentioned fourth-order

problem,

earlier

requiring

we can count the constants lies in a plane, second one.

L is p e r p e n d i c u l a r

A lies in the plane,

the clock started.

algebraic

stationary

in space;

one introduces (2.99)

easy because

it is very difficult is similar.

amount of calculation

the quantum operator

the solution

the third integral.

is reduced

And

to, the time in (2.92)

had been

algebra.

and energy as is

remains.

that corresponds

to quantum

or impossible. If one character-

atom by angular momentum

a considerable

E is the

the orbit is a figure

the situation

of the hydrogen

usually done,

one integral.

that r(@) could be obtained

in general

Now

Since the orbit

is that all the integrals

process

In quantum mechanics izes states

of integration.

the last one is trivial:

The reason

It was relatively

to it:

is a

but since its length is given by

is independent:

as we have already mentioned,

found.

four constants

that have been found.

L and E, only one component

by a purely

that the Kepler problem

But if

to A (see This

is, in

fact, how Pauli first solved the problem I° in the days before Schr~dinger's

Hyperbolic

equation had simplified

Orbits

When the energy

is positive

tor of (2.74a) vanishes The orbits Fig.

2.12.

the calculation.

and by

or becomes

are now hyperbolas, The asymptotes

negative

i0

e > I, the denomina-

for certain values

of 8.

still with the sun at one focus,

are at the angles cos@ = e -I

By (2.74b)

(2.74b)

this can also be written

±@, where (2.95)

as

W.Pauli, Zeits. f~r Physik 36 336 (1926). A little later Dirac did it independently: P.A.M. Dirac, Proc. Roy. Soc. (A) 110, 561 (1926).

81

tan@ = (==)½~ m At great distances and

from the origin,

L

the energy is entirely kinetic

(2E/m) ½ is just the asymptotic v e l o c i t y Vo, so that VoL tan@ =

(2.96)

IYi 12

Figure 2.12

Hyperbolic orbits corresponding to positive energies.

If y > 0 (attractive force) we must have cos@ > e -l and @ is bounded below.

This is orbit 1 in Figure

the inequality

is the other way,

Problem 2.48.

Fig.

2.13 shows

Figure 2.13

calculations

of scattering:

the scattering angle.

2.12.

When the force is repulsive

and orbit 2 results.

(for y > 0) the parameters used in

Scattering by a center of force.

s is the collision p a r a m e t e r and

The incident particle's

m o m e n t u m is Pas = (2mE)@"

asymptotic

O s is

linear

Show that the angular m o m e n t u m is SPa s .

82 Problem

2.49.

Show that these orbits

Problem

2.50.

Show from the calculations s = ~

The differential

scattering

are hyperbolas. just done that

cot~@ 8

cross

section

is given

(Park,

1974,

p. 316) by d~ e d~ - sin@ Derive

the Rutherford

Problem

Derive

scattering

The vector

2.51.

(2.95) by forming

d8 d@

8

8

formula.

integral

A gives

the product

a simple derivation

p.A and considering

of @ . 8 the limit of

large r. 2.11

Other Forces

Problem

A particle moves

2.52.

force given by the potential and r(@) Problem

in a central

V(r)

=

for a particle projected Calculate

2.53.

-hr -2.

the orbits

Problem

Show in quantum mechanics

Problem

inverse-cube

to find orbits make

inferences

object orbiting

potential

given the force.

Figure

2.56.

through a hole

table moves the system

its original 2.57.

around

of small oscillations.

from a fixed point by a cord of length £.

is slightly disturbed,

oscillations

(Mg/ma) ½ so that

the orbit of m now oscillates

It is set in motion so that it moves motion

(frictionless)

The mass M is now given a

radius a and find the frequency A mass hangs

Deduce

connected by a cord that

The mass on the

equilibrium.

Show that

that has the heavy

Assume p@ constant.

two masses

in a table top.

to

finds a light

instead of in the middle.

energy.

in a circle with angular velocity ~ = tug.

in an

bound states.

Suppose an astronomer

2.14 shows

is in dynamical

sharp downward

Problem

has no stationary

heavy one in a circle

the force law and the s y s t e m ' s

passes

a particle

Show how to invert the argument

the other way. a motionless

that

in this chapter have all attempted

one located on its circumference

Problem

@(t)

at t = 0.

force.

The calculations

2.55.

direction

of particles with E > 0 scattered

inverse-cube

attractive

inverse-cube

Find and sketch r
in a tangential

by a repulsive 2.54.

attractive

in a horizontal

find the frequency

circle.

If the

of the resulting

around the circular path and sketch the resulting motion.

83

Figure 2.14

Problem

2.58.

To illustrate Problem 2.56.

How must the field of a central force vary with r in

order that it be possible for a body to move in it describing a spiral r = (c@) -I, with c a constant? Problem

2.59.

Several physical theories have proposed that the

Newtonian G varies by a few parts in 1011 per year: = -hG How will the radius, period and eccentricity of a circular planetary orbit vary if this is so? 2.12

(Hint:

for e, find A.)

Bohr Orbits and Quantum Mechanics:

Degeneracy

Planetary orbits and Bohr orbits are, in general,

ellipses.

The

particle moves slowly when it is far from the center and tends to spend most of its time to one side of it. expectation values,

<x>

But

That is, in terms of

if A is in the direction of positive x,

>

O,



=



=

0

(2.97)

(Problem 2.61) all these values are zero in any stationary state

that is an eigenstate of the angular momentum.

It is therefore not

clear at first what quantum mechanics has to do with elliptical If the orbit is not re-entrant there is no difficulty, will swing around and, on the average, directions space,

in its plane.

orbits.

for the orbit

spend equal times in all

Keplerian orbits, being stationary

in

are special, but how?

The solution to the puzzle is the degeneracy of the orbits. Degeneracy

in quantum mechanics refers to the existence of different

states of motion corresponding

to the same energy,

definition will do for classical mechanics

also.

and the same For example,

the

84 plane of an orbit can have different to the plane,

this is reflected L 2.

in the 2~ + 1 values

But a re-entrant

orbit has still

given L there are still d i f f e r e n t directions L).

in which

number

orbits corresponding

degeneracy

to different

(always p e r p e n d i c u l a r

in quantum mechanics?

to

In

not only in L z but also in

all orbits with the same value of the principal

A general

discussion

is laborious;

level, which belongs

¢0

quantum

2.60.

functions

=

_~

(I

-

degenerate

2-~o)e-r/~aO

Show that all four of the functions

of L 2.

states:

(2.98a)

(32~)-½a0-~(x'y'z)e-r/2aO

(2.98b)

(2.98)

are eigen-

Show that ~0 and ~z are also eigenfunctions

and that two further eigenfunctions combinations

we look only at the first

to four different

(8=)-%%

=

@x,y,z

Problem

to any with a

are degenerate.

excited

ProbZem

of L corresponding z further degeneracy:

atom there is a degeneracy

L 2 itself:

L , perpendicular

and in quantum mechanics

the vector A may point

What is the additional

the hydrogen

orientations:

can point in any direction,

of Lz,

can be formed from linear

of ~x and ~y.

2.61.

Show that in eigenstates

of ~ Lz,

and L 2, <x> = =

= O. Since the usual eigenfunctions tiation values satisfying The classical

(2.97),

of L 2 and L z do not give expec-

let us look at eigenfunctions

formula for A, A

1 = ~ r - ~ pxL

is not quite ready to take over into quantum mechanics, involves

the product

such a product

of two noncommuting

is itself not hermitian.

try in such cases: Remembering

average

the products

that the vector product

interchanged,

of A.

quantities, There

since it

p and L, and

is a general recipe

to

taken in the two orders.

changes

sign when the factors

are

we write A = Z r - "~" 1 (pxL - t x p )

(2 99)

85 Problem

Verify that this operator commutes with the hydrogen-

2.72.

atom hamiltonian and therefore represents

a conserved quantity.

It is now easy to see that the components of A do not commute, that a state can diagonalize only one of them. tedious calculation using the wave functions

Choose A x.

(2.98)

so

A somewhat

now shows that

^

~x~O where y i s Ax

= -½ Y~x

"

( e l e c t r o n charge) 2

by combining ~0 and

Ax~x

= -½Y~o

Thus we can form two eigenfunctions

of

~x: (2.100)

^

AxCVJo- Cx) By (2.93) we see that these

= ½ Y(¢o

-

Cx)

quantum states correspond to oppositely

oriented orbits with eccentricity e = ½. Thus the spatial degeneracy in the classical theory which allows us to have lop-sided orbits corresponds exactly to a degeneracy in the quantum levels which allows us to combine states with different L to produce a similarly lop-sided wave function.

This happens to be

the wave function for a hydrogen atom polarized by being immersed in an electric field, and there is a picture of it in Park 2.13

The Principle of Maupertuis In its primitive

(1974), p.277.

and its Practical Utility

form, the principle

that a body traces out its orbit between ¥

stated by Maupertuis asserts two given points in such a

way that Iv.ds has a value smaller than it has for any other possible J

path at the same energy. venience,

For most purposes

this proviso

is an incon-

and there is no such restriction on the varied paths in

Hamilton's

principle,

but it sometimes

facilitates practical calcu-

lations as we shall show. In Cartesian coordinates

ofv.

= ofv.

and it is this integral, stationary. path,

E

=

=

+

called the action, which is to be held

is not to vary, nor are the spatial endpoints of the

though the time required for the motion may vary,

schematic manner, principles

In a

showing only one coordinate q, we contrast the

of Hamilton and Maupertuis

in Pig. 2.15.

We have now to

86 prove

that when the path is varied as in Fig.

2.15b the natural motion

~t

1 to Figure 2.15

....

I t,

I

,,

%

t

t,

Natural and varied paths for the variational principles of (a) Hamilton; (b) Maupertuis.

is described by

6

X

(L + E ) d t

=

I<

(q2,~2)dt

-

Jto

Edt

The second pair of integrals

-

Edt

since

unimportant treat

the

L(ql,ql)dt

+

=

0

Jtg

is

E ( t 2 - t o - t I + to)

and we write

r

Jto

Jtg

where

~t

= E6t

the first pair as

the

second

whether first

integral

we w r i t e

integral

as

Ill

has it

in

as

an i n f i n i t e s i m a l a function

Sec.

6L__ 6 q n d t + 6qn

1.5

~L

to

of

q2

get

~q

tl to

value or

of

it

q2"

is We

87

in which ~qn = q2n the figure that

- qln

6qn = 0

and

6qn[tl) Putting

the integrals

61(L +

together

The first term vanishes the second vanishes conclude

if the equations

that if the variation

the

time

of the motion

endpoint

principle.

This

oscillating

system.

Example:

is

of motion

of the as

integral

useful

are obeyed; Thus we

+ E]dt is

a variable,

especially

(2.53)

as specified above.

A = I[L(q,4)

that

the

3L ~n~6 t 8q~ ~ tl

of energy in (2.55).

is p e r f o r m e d

6A = O,

take

it is clear from

gives

from the definition

The f a c t

tl,

-~n(tl)6t

=

6L-~-.6qndt + [E + L 6qn

=

E) dt

At

at t o .

varied

(2.102) means t h a t

as we c a n n o t

in determining

the period

can be w r i t t e n L = ½(~2 _ ~ x 2)

A mathematician approximate

who h a d n e v e r

a half-period

heard

of the x(t)

=

is calculated

from

(2.102) I

a 3

a and b are

chosen

at

function

might

try

bt 2

-

to the half-period x = 0 to

1

2

a s

~0 ~

so as

a

+ ~ E

t o make A s t a t i o n a r y :

~A ~A 0 ~a - ~b and the resulting complete

algebraic

equations yield for the period of a

cycle and the energy

to

by a p a r a b o l a ,

as

A = ~ ~-- - ~

parameters

(2.103)

of a sine

vibration

with which the action corresponding

the

o f an

The Harmonic Oscillator

The lagrangian

x = a/b

we c a n

in Hamilton's

(2.1041

88

T

=

2a b

the m a x i m u m value of

-

x(t)

2 I/-1~ ~0 "

E

=

1

a 2

X2

_

2E ~0 2

is a z

X

-

4b

w h i c h satisfies X 2 =

15

8 The exact solutions T

=

E ~02

are, of course, 2_.[_~ ~0 2 "

(2.105)

The frequency is in error by 0.7 percent.

Problem

2.63.

The h a r m o n i c oscillator will be better solved if we take

x(t)

=

Xsin~t

as a trial function and adjust ~ so as to make A stationary. that

(2.105)

Problem

Show

follows.

2.64.

Show that the lagrangian for a simple p e n d u l u m can be

written in the form

L

=

½[~2

_

~02(02

~

@4

+

...)]

~0 2

=

g/Z

and use the v a r i a t i o n a l m e t h o d to show how the period depends on the amplitude of swing.

I suggest you use more than one trial function.

How can you tell w h i c h one is the best?

CHAPTER 3

Newton's

N-PARTICLE

SYSTEMS

laws really refer only to particles,

reference

to properties

momentum.

The objects

position.

The properties

theory by a process

like size,

elasticity,

described by Newton's of extended

laws have only mass and

of summation or integration.

integrates.

it mentally

into infinitesimal

N means more than one.

there are two classes the bodies

of problems

like pressure, body system.

temperature Chemists,

N and then consider

some general small values.

rigid and elastic bodies, Center-of-Mass

in Figure

in a few-

have to deal with

These calculations them here.

are often

In this chapter

theorems valid for all values of Large values,

as exhibited

in

8 and 9.

at the center of mass.

m 7.

I

The condition

I'}'I~,

I

I

I

X

A loaded weightless beam balanced at its center of mass.

3.1 is

mlg(.~

or

and astronomers

starting

quantities

Theorems

mI

balance

are very different,

will occur in Chapters

A loaded beam balances

Figure 3.1

generally

interest:

and density have no counterparts

engineers,

and we shall not discuss

first prove

In physics

to ask--macroscopic

in w h i c h N is in the dozens.

very difficult,

3.1

of volume and

say up to 4 or 5, and when there

The situations

with the kind of question one wishes

we shall

and sums over them, elements

that are of special

are few in number,

are about 1022 of them.

situations

in the

Either one thinks

In that case one does not speak of N.

In this chapter, where

angular

objects must be included

of the object as being composed of N particles or one divides

for they make no

and internal

-

Xl) +

m2g(x

-

x2)

= mSg(X 3 -

~,)

for

90

mlx I + m2x 2 + m3x 3

(3.1)

=

mI + m2 + m3 We take this a s

the definition of the center of mass and write the

general formula as N

N

Let us suppose that the jth particle has two sorts of forces acting on it:

a force fij exerted by the ith p a r t i c l e and a force fj

exerted from outside the system.

The total force on the jth p a r t i c l e

is then

Fj = f. F +. E. j ~j

(3.3)

i/j Linear Momentum Let us write

the total m o m e n t u m of all the particles of a system

as

N

By

P = E mj~j j=1

(3.4a)

P = Mr

(3.4b)

(3.2), this is

Its rate of change is

j

i/j

The last sum involves pairs like f12 says that this is zero.

Further,

+

f21' and Newton's

the sum of the external

third law forces

exerted on all the particles of the system is the total force from outside,

91

We have now

= M~ = F and we see that if Newton's

(3.6)

laws hold for each particle

(or element of

volume)

of a body or set of bodies,

whole.

This is why one can treat planets as if they were point

particles,

they apply to the motion of the

and incidentally it provides

the experimental v a l i d a t i o n

of the third law.

Angular Momentum If we p u s h an extended

object the object's center of mass moves

off, but also, unless the line of action of the force passes

through

the center of mass, the object will begin to turn. Let ~. be the g angular m o m e n t u m of the jth p a r t i c l e around an origin of coordinate located arbitrarily, mass,

Fig.

and let ~. be that taken around the center of

3.2:

~j = mj~j×3j

£j = m j r j x ~ j ,

...:..

q-r

0

/ Figure 3.2

Coordinates used to locate the center of mass (_circle) and the jth particle.

To see the r e l a t i o n between them, write

(3.7) Then the total angular m o m e n t u m around 0 is L = ZZj = Zmj(pj + ~ ) × ( ~ j +

~)

= Zmj~j×~j + ~xZmj~j - ~'×Zmj~j + r×~Zmj

92 In the third sum,

zmjpj = by ( 3 . 2 )

and t h e

vanishes

also,

second

Zmjrj

-

(3.8)

~ zmj = o

term involves

the

derivative

of this

sum w h i c h

so t h a t L = A + [ A = Zkj,

The angular m o m e n t u m

(3.9a) [ = ~ x P

(3.9b)

is the sum of that around the center of mass and

that of the entire system around the fixed point 0. The rate of change of L is x p$ = ~ r j . x f j . +

[ = _v~ ~ r $

r .J x

Z~

f .~J .

i/$ The double

sum represents

internal

stresses,

particle

forces

angular m o m e n t u m created by the system's

and it vanishes.

This is easy to see if the inter-

lie along the lines of centers,

sum come in pairs

in the

like

r I x f12 + r2 x f21 = ( r l

The more general

for the terms

case requires

can hardly be in doubt:

- r2)

x f12 = 0

a closer examination, I but the result

a skater cannot start to spin by standing

still and flexing his muscles.

By (3.7),

the remaining

term of

gives [ = Zp$ x f.j + ~ x F

If a force f acts on a particle torque,

or moment,

at the point r it produces

about the origin of coordinates

The first term in (3.10)

(3.10)

is the sum of the moments

applied forces about the center of mass.

a

defined as r x f. of all externally

Calling this M , we write O

(3.10)

as I[ = M

0

It is often useful

+ ~ x F

to choose the origin of coordinates

E. Gerjuoy, Am. J. Phys.

I?, 477

(1949).

(3.11)

at the center

93

of mass.

Then r = 0 and only the first term of (3.11)

A final N-particle

remark will be useful

system,

center of mass In studying

system,

specifying

about a fixed point

particles

the point

LQ, = ~imj[(rj P = 0.

Problem

3.1.

or a system

translational

discuss

it in coordinates

is at rest.

In such a system

Q is independent

around which

it is taken.

If LQ and LQ, are the two angular momenta,

because

an

of Q, and

speak of the angular momentum of such a system

and if Q' is at a constant

distance

+ ro)Xrj]

The proof takes about Q and Q',

r 0 from Q, then = LQ + r 0 x p = LQ

Prove that the force of attraction

for a spherical planet exactly

for we naturally

to which its center of mass

one can therefore one line.

of a gas of interacting

stars and planets we do not consider

the angular m o m e n t u m without

in considering

and motion about the center of mass at the same time.

motion of the whole with respect

Usually,

one does not need to bother about motion of the

the behavior

of interacting

later.

survives.

of a spherical

is directed along the line of centers

inverse-square.

(5.12)

sun

and is

(This is a problem from elementary physics

but a very important one.)

Kinetic

Energy

The final theorem of this set concerns write

the kinetic

energy of an N-particle

it breaks up according

kinetic

If we

to

T = ½ Zmj6} + ~.Zmj~ 5 + ½ ~ or, using

energy.

system as

Zm 5

(3.8), '2

r = % zmj~j + % ~ 2 Once more,

there is a term corresponding

as a whole

and another corresponding

(3.13)

to the motion of the object

to its internal motions.

94 The results

just proved

dynamical problems,

lead to simplifications

if we are interested

in the internal motions

system attached

to a system's

already:

that

of a system we need not

bother about its motion as a whole and vice versa, coordinate

in solving

for they tell us what we suspected

and that a

center of mass has special

advantages. The formulas hydrogen atom,

developed

above are very general,

applying

a container of gas, or a spinning baseball.

to look more familiar

if we apply them to special

baseball

spinning

for example,

with angular velocity

~.

cases.

around the z axis through

~, its linear velocity

axis,

then

~y = o~px

total kinetic

T

=

½

p

(3.14]

Px =-~°Py" and the baseball's

the

its center

is

= ~xp

z

They begin Consider

If one of its particles with coordinates

moves with angular velocity

If ~ is along the

to a

energy

Zmj(pj~

is

pjy )

•

+

•

½

I~ 2 +

2

+

½ Mr 2

or

T

=

½

(3.15a)

Mr 2

where

(3.1Sb] is the baseball's of mass.

moment of inertia about an axis through

The internal part of the angular momentum A = T,m j p j X l ~ j

=

~:mj[pj2o~

Working out the components

its center

is

= ~]mjpjx[Loxpj]

-

(~.pj)pj]

by (2.89)

of A with ~ parallel

to the z axis gives

95

A x = -~ozmjpjzPjx

,

Az =~o zmj(Pjx2

Ay = -Zmjpjzpjy

+ pjy2 + Pjz 2 - Pjz2 )

or

A For a spherical

distribution

z~

(3.16)

of mass A

and A vanish by symmetry so x y to the angular velocity m. Note that

that A is in this case parallel this is not always

=

z

the case, however

(see Chapter

inertia of a sphere of mass M, density

p, and radius

M

I = ] p(x2 + Y2)dv If the density

is uniform,

I =

Example from rest.

3.1

dr

=

of the slope

The moment

of

R is

4 ~R3o

~

this is

d@

d~(r2sin2O)rZsin@

= ~ MR a

(3.17)

A sphere rolls down an incline of height h, starting

How fast is it moving when it reaches

Solution.

Energy is Mgh.

is conserved. The kinetic

½I ~2+ ½M~ 2, where V = ~R.

Problem

8).

With

3.3.

A hoop and a solid cylinder

y

by

(3.14)

is

this gives ~2 = _g7h . 1 0

Show that A

and A

energy at the top

energy at the bottom, (3.17)

3.2.

x

the bottom?

The potential

are zero for the baseball

discussed

above.

Problem

rolled down the same slope. reaches

the bottom?

Problem

3.4.

the period

3.5

are

Find 2/3

the ends.

around a horizontal

The mass

acceleration

a) at the end and b) at a point

A rope of negligible

end is wrapped middle.

of the same diameter

is the hoop when the cylinder

A uniform bar of length £ is used as a pendulum.

if it is suspended

the way between

Problem

Where

is allowed

of the mass.

mass supporting

a mass m at the

log of mass M with an axle down the

to fall and the rope unwinds.

Pind the

96

Problem

3.6.

Find the p o s i t i o n

of the mass m in the p r e c e d i n g

as a function

of time

if the mass

Problem

A small

cylinder

What

3.7.

is the p e r i o d

of small

as a useful

generalized

serve

Figure 3.3

3.2

Two Particle We treated

vector

planetary

as usual,

if M and m are the masses

Mr

Solving

these

+ mr

e

for r e

energy

a large one,

about

motion

in Chapter

3.5. 0 will

p

be at rest

2 on the hypothesis

the assumption. at the origin,

that

Let the center

and let r be a

from the sun to the planet.

Then by

(3.2),

of sun and planet,

: O,

r

- r

p

and rp, we can calculate

: r

s

the total

(3.18)

kinetic

as

is w r i t t e n

2 = ½

Mm

½ ~2

I _ I + ! M

~ is called

the reduced mass.

= m(1

and when,

~2

as T =

where

Fig.

equilibrium?

To illustrate Problem 3.7.

2 + ½ m~

This

inside

coordinate.

We can now relax

of the two bodies running,

rolls

oscillations

problem

is not negligible.

Systems

the sun is clamped. of mass

of the rope

as w i t h

atoms

(3.19)

m

We can write

it as

m - M---C--~m)

and p l a n e t a r y

systems,

m << M, we see that

97 is slightly

less than the smaller mass.

The lagrangian

is

(3.20)

L = ½ Vf:2 _ V ( r )

and the

only change

Problem

3.8.

from

(2.62)

is

the substitution

The t w o - b o d y H a m i l t o n i a n

o f ~ f o r m.

in quantum mechanics

is

~2

Change

the variables

factors

to r and ~ and show that the wave function

into a term describing

and a term describing

the motion around the center of mass

the motion of the atom as a whole.

Show that

the effective mass enters here just as it does in classical

3.3 Vibrating

Systems

In several branches molecular motions vibrate. pendulum

theory.

chemistry,

of study,

from structural

it is important

engineering

to know how to analyze

to

the

of a system whose parts are coupled together so that they can We have already seen an example of this in the double of Sec.

2.7, where we found the modes of motion in which it

moves periodically.

In this Section we shall study the periodic

motions

in more general

situations,

motions

that are not periodic.

be only a generalization

and then see how to deal with

The first part of the discussion will

of what we have already done.

Suppose there are f degrees of freedom with coordinates qn' and that the system has some position of stability around which small oscillations

take place.

The potential

energy of the entire system

is V(q), and at the position of stability, where q = q0' V(q) has an absolute minimum or at least a local one, at which it is smaller than at any neighboring

points.

@-K 'V I @qn

Since V is a minimum at q0' we have

= 0

and if we expand V in the neighborhood double pendulum)

n = I ....

f

(3.21)

0

of q0 (as was done with the

the linear terms in the Taylor series vanish and we

have

V(q 0 + y) = V(qo)

+ ½ ~ f E m, n=1

~2V Bqm~qn

I qo

YmYn

+ ...

98

where the y's measure the system's departure from equilibrium. first term is a constant and we can ignore it.

The

The second t e r m

involves a set of constant coefficients w h i c h we shall call Vmn , so that

(3.22)

V(q 0 + y) = ½ VmnYmY n ~... in which the summation c o n v e n t i o n is used. The kinetic energy is T=

½ Z m.&. 2

in which the Cartesian components x. are some functions of the q's and therefore of the y's.

Since

x i = x i ( Y 1 ... Yf) we have 8x.

~Yn and the kinetic

energy will

be some q u d r a t i c

function

of the ~'s,

(3.23)

T = ½ Tmn~m~n In (3.22) and (3.23),

the arrays V mn

and T

are not n e c e s s a r i l y mn

symmetric in m and n to begin with, but in (3.22) we have

VmnYmY n = VnmYnY m = VnmYmY n so that

VmnYmY n = ½ The coefficient

½(Vmn

+ Vnm),

enters the calculation,

~Vmn + V n m ) Y n Y m

the symmetric part of Vmn , is all that

and so we may assume that Vmn'

and Tmn , are

symmetrized to start with. For small oscillations,

the lagrangian of the system is

L = ½ T m n Y m Y n - ½ VmnYmY n To take the derivatives, we vary the variables one at a time,

dL = ½

(Tmn~md~n

+ Tmn~nd~m

= TmnYndY m - VmnYndYm

- VmnYmdY n - VmnYndYm ~

99 so that

the equations Tmn~n

of motion

~L/6y m = 0 are

+ VmnY n = 0

m = I ....

This is a set of linear homogeneous cients.

Their solutions

form A c o s ( ~ t

equations with constant coeffi-

depend on time through expressions

Since boundary

+ ~).

(3.24)

f

of the

conditions will involve us with

different values of ~, it is s t r a t e g i c to consider Yn as the real part of an a ne i(~t + ~n) with complex an. Now e i~n can be absorbed in the a and all motions of the system have the same n Substituting this form of Yn into (3.24) gives

constant

time dependence.

(3.25)

(Vmn - ~ 2 T m n ) a n = 0

which is a set of f linear homogeneous solutions

only if the determinant

equations

IVmn - ~2Tmnl

This is called the characteristic Its solutions

give us nothing new,

to the system's eigenvalues values of

of the equations

of

normal modes of

are ~the normal mode frequen-

of the system.

(3.25) can be simplified.

m. are zero,

is,

frequencies

frequencies

system.

values or, more

and since negative

are called the system's

and the corresponding

Equation that

to be equal)

there are f solutions

These solutions

cies, or characteristic masses

equation of the vibrating

There are in general f different

~2 (though some may happen

motion,

(3.26)

They are called c h a r a c t e r i s t i c

commonly, eigenvalues.

It has

vanishes,

= 0

are the values of w z that correspond

periodic motions.

motion.

in f unknows.

of the coefficients

If we assume that none of the

it can be shown that the matrix T

it has an inverse.

Multiplying

is nonsingular, mn (3.25) by this inverse gives

[(T-iV)m n - ~26mn]a n = 0 and the characteristic

equation

I(T'lV)mn The simplification Further,

and positive. e

is

- oS28mnl = 0

(3.28)

is that m 2 now occurs only along the main diagonal.

this standard

readily available

(3.27)

form of eigenvalue

computer programs.

This follows

equation is solved by

The eigenvalues

from the conservation

~2 are all real

of energy:

had an imaginary part the energy would mysteriously

disappear.

It can also be proved from the mathematical

if e in

augment or properties

100

and Vm n " 2

of the matrices T m n Example

~I = 5, ~2 = 8. that

The double p e n d u l u m of Fig.

3.1.

2.4 has m I = 3, m 2 = 2,

To find the frequencies of the normal modes, note

from (2.56), T = 12S 2

=

so t h a t

the matrices

T

~2 6 + S4 "~ I + 4°ei 2 e2

--01+

for T and V are

= mn

V ~ 20

64

"

= g mn

0

o1 8

and

T-I mn

=

3SO----~

-20

125

"

(T-iV)ran = g

- -

The c h a r a c t e r i s t i c

~

~5/

e q u a t i o n (3.78) becomes 2 8

~2 g

2 45 =

5

5

o~2

72

36

g

0

of w h i c h the solutions are

g

as can be v e r i f i e d from

4" 9

(2.59a).

Once the eigenvalues have been found, we can put them back into (3.25) and determine the relative sizes of the amplitudes a n as in Sec.

2,2.

(There is an arbitrary scale factor that is d e t e r m i n e d by

the initial conditons.)

Since all the c o e f f i c i e n t s

real,

are real or, if not, have the same complex

phase. 2

all the amplitudes

in (5.25) are

Thus all parts of a system in a normal mode vibrate exactly in

See for example Goldstein

(1951).

~0~ or exactly out of phase with each other.

Problem 3.9. with masses

Figure

3.4 shows a model of a linear triatomic molecule

and spring constants

longitudinal

3

Z

k.

relations

Coordinates in one of its normal modes,

its

move in or out of phase with each other with definite between

the amplitudes.

system so that these conditions conclude

zCz

To i l l u s t r a t e Problem 3.9.

If a system is oscillating components

of

7

6

Figure 3.4

Normal

Find the frequencies

oscillations.

~-

3.4

as shown.

that we would have

What happens

if we start the

are not satisfied?

to start to calculate

a glance at an example we have already The double p e n d u l u m of Sec.

A pessimist might all over again, but

studied dispels

such fears.

2.7 had two characteristic

frequen-

cies

:

~z

and, correspondingly, the amplitudes

: (-2-) %-

£I :

~2)

=

£Z

4m12 £2

two alternative

)

(3.29)

£2 - ~1

m2

(I

~2

~2

) £i

conditions

to be satisfied by

of motion,

a(1)

d

m2 4m12

(~--)½-- (1 + ~1

2(~ 2 - ~z) ~m12 ~2 - h m2

The t i m e b e h a v i o r

(ii __ aI =

. (i) -Ala 1

(3.30)

~c2~z ~ ~ 2 ~ 2~

£2

assumed there

could just as well have been e

was o f t h e

±i~t

form cos(~t

+ ¢);

it

The point is that the equations

102 of motion are linear;

any linear combination

and e ±i~t = cos~t ± icos(~t

solution,

and superpose solutions most general

corresponding

such superposition

Ol(t ) = A e ~ l

of solutions

- ~/2).

is again a

But we can go further

to different values

of ~, the

being of the form

t + Be-i~l t + Ceil2 t + De-i~2 t (3.31)

= _ k l ( A e i ~ l t + B e - i ~ l t ) + t 2 ( C e i ~ 2 t + De-i~2 t )

02(t)

where A, B, C, D are arbitrary (2.56)

constants.

The original

equations

are a set of the fourth order, which we know to require

arbitrary

constants

solution;

nothing more than the normal modes need be found.

Suppose hand,

for its solution.

for example

displace pendulum

release

that we hold pendulum

-kl(A

+ m2(O -

four

is the general

1 vertical with one

This gives four initial

A + B + C + D = O B)

(3.31)

2 through an angle 80 with the other,

them both at t = 0.

ml(A -

Thus

+ B)

and

conditions,

+ k2(C

+ D) = O0

-hlml(A - B) + ~2~J2 (C - D) = 0

D) = 0

with solution

@ 0

A = B = -C = -D

2 ( l I + 12) and so the motion satisfying

the given boundary

conditions

is

@0

@ICt) = - ~i + h2 (C°Smlt - c°sm2t)

(3.32) 82(t)

The pendulums periodically modes

@0 - hl + X2 ( I I C O S ~ I t + 12COS~2t)

swing w i t h varying amplitudes,

and the upper one returns

to rest w i t h an angular frequency ½(ml

of motion are taking place

simultaneously,

- ~2)"

The two

and we are seeing

the phenomena of beats.

Problem

3.10.

Fig.

3.5 shows an arrangement

oscillators

that can very easily be made.

parameters,

calculate

the two basic

of coupled torsion

Assigning

suitable

frequencies when one bar is held

103

still and the other is allowed to oscillate. other needed parameters,

discuss

the motion

In terms of these and that begins when both

bars are initially at rest and one is given a sudden displacement. Then build the thing and see what it does.

A

Figure 3.5

Problem

To illustrate Problem 3.10. A torsion oscillator consisting of two weighted staffs supported by a wire.

3.11.

Figure

a weak spring.

3.6 shows

Analyze

two identical pendulums

coupled with

the motion when they are started a) in phase

with the same amplitude,

b) out of phase with the same amplitude,

c) with both vertical but one in motion. Vll.~v l/llllli#llll

! IIIIII/II

II!I/Jll////l

II I I

t

Figure 3.6 Problem

cords,

3.12.

Fig.

Three equal masses

3.7.

corresponding

To illustrate Problem 3.11. elastic

of normal oscillations

and the

normal modes.

Figure 3.7 Problem 3.13.

are connected by identical

Find the frequencies

To illustrate Problem 3.12.

A mass m is suspended

from a spring of s t i f f n e s s k and

104

swings

like a pendulum

the pendulum Comment

moves

on special

equal or nearly conclusions

through

in a plane, cases

equal

small

angles.

b) when

Find the motion,

it moves

that may arise when

to the pendulum

a) when

in three dimensions.

the spring

frequency,

frequency

is

c) Verify your main

by experiment.

Normal Coordinates The theory coordinates,

in Section

lar set of q's or y's. Suppose

for example

we had chosen designed

3.3 was set up in terms of generalized

and there was no necessity that instead

linear combinations

to produce

of starting with any particu-

But some choices

quantities

are better

than others.

of @i and @ 2 in the double pendulum of the two solutions

in (3.31)

each of which oscillates

at a single

frequency:

u I = 82 - 1281 = 80cOsmlt

(3.33a) u 2 = 82 + ll@ I = @0cosm2t with

l's as in (3.30).

U2 uI l I + 12 "

@i We would have

With these variables, llU I + X2u 2 82 = l I + 12

found u I to have the single

for u2, as if there were no coupling can be seen if we use terms of u I and u 2. m12

(3.33b) Omitting

~

between

to express small

m2~2(2ii-~2).

+ 4m12 (~2-~z)2[(I

like the lagrangian

+

of two uncoupled

(2.55)

in

we find

@ _

2 1 2

.

~]

q (1 + 4mlm(f~m_~l)2)u2 ]J

oscillators.

calculation

we find that u I and u 2 oscillate

m2 given by

(2.59b).

The new variables

How this occurs

@ m2%1~ 2 ~i (I + 4m12(~ 2- il)2U~] - --

~

m2]~i(21%2-9~i)] 4m12(f~2.£1)2Ju22 •

them.

m I and similarly

the lagrangian

terms,

L = 2(~i + x2)~ ~ i ~ [(I + 4mlZ(~2_£1)2J

m2

frequency

(3.33b)

with

u I and u 2 are called normal

By the simplest frequencies coordinates,

~i and and

105

there to

is

find

a mathematical a set

for

Our p r o c e d u r e constructed it

is

reduce

to

do i t

encounter

discussing Problem

here

the normal

easier

We s h a l l

theorem

any s y s t e m

the

Problem

3.15.

Problem

3.16.

a nd d i s c u s s

was b a c k w a r d s - - w e

the

normal

other

Do t h e

but

solved

for

K

system.

coordinates

3

systems

methods.

9.2 while

o f P r o b l e m 3.10, an d v e r i f y

the

use

them t o

frequencies.

Problem 3.8. solution

occurs

m

Figure 3.8

always possible

t h e p r o b l e m and t h e n

in Sec.

general that

is

more c o m p l i c a t e d

again

same f o r

the motion

it

of a continuous

t o a sum o f s q u a r e s ,

Find the

that

way by a d v a n c e d a l g e b r a i c

coordinates

the normal

lagrangian

states

k i n d we h a v e b e e n d i s c u s s i n g .

coordinates,

oscillations Find

3.14.

the

that

of the

if

the

for

the system

system

k'

is

of Fig.

initially

at

3.8 rest

rn

To illustrate Problem 3.16.

and the r i g h t - h a n d cart is struck towards

the right w i t h a hammer.

What are the general and special solutions when the left-hand spring is missing,

i.e., what are the limiting forms of your solutions w h e n

K=O? Problem

3.17.

Fig.

the CO 2 molecule.

3.9 shows a scheme for the linear vibrations

of

The following steps will lead to a d e t e r m i n a t i o n of

ml

k

M

,

k

i

,

m

1o

11

I X Figure 3.9

3

To illustrate Problem 3.17. Mechanical model for the linear vibrations of CO2. The ~'s measure the stretch of the two springs, to left and right respectively, from their equilibrium positions.

Ter Haar 1961, Ch. 3. The use of symmetry to simplify a p r o b l e m is d i s c u s s e d in Corben and Stehle 1960, App. III.

106

the normal modes and thus to the entire solution.

You should work

them out in detail. i.

The lagrangian

is

L = ½(M + 2m)& 2 + m(~ 2

2.

"2

~1)~ + ½ m ( [ l ~ +

g2 ) - ½k(%12 + ~2 )

Since the momentum of the system is conserved,

the coordinate ~ will have special

significance•

(3.34)

one can guess that The transformation

m

(El

x = ~ + M + 2m

- ~2 )

eliminates x and gives m 2

L = ½(M

2

+ 2 m ] ~ 2 - ½ M + 2m •

.

•

(~i - ~2 )

+ ½m(~l + ~ ]

½k(~ 1 +

.

To remove

3. The terms in ~2 x and {i = are gone but [i~2 remains. rotate the ~ axes by ~/4,

u I = 2 - ½ ( { 1 + ~2 ) •

it,

u 2 = 2 - ½ ( { 1 - ~2 )

tO g e t L = ½(M

4.

+ 2m)~ z + ½ m~iZ

The lagrangian

the corresponding

(X,

El,

Problem

is now decoupled. normal modes,

$2 ) tO ( 7 ,

the

foregoing

just discussed

Find the stationary

3.5

problem

describe from

directly

from the

lagrangian

with those just found.

Write down Schr6dinger's

3.19.

vibrations

Find the frequencies,

and find the transformations

(3.34) and compare the frequencies Problem

+ u22 )

u 1, u 2 ) .

Solve

3.18.

+ ½ M Mm + 2m ~2 z _ ½ k ( U l 2

equation

for the CO 2

and transform it to the variables

E, ul, u 2.

energy levels of the molecule.

The Virial Theorem The methods

described

in this chapter become useless when N is

very large unless the particles organization,

have some specially

as they have in a solid body.

simple spatial

They are useless because

the calculations

are too complicated

results anyhow.

If the system is a gas, it would not be interesting

to know the positions

and velocities

and because nobody wants of all the particles,

could, because what we want to learn are the properties

the

even if one

of gases in

107

general, not those of a p a r t i c u l a r start in a p a r t i c u l a r way.

sample in which the molecules

We want a statistical

theory of specific systems.

We cannot in this book make a serious

d i s c u s s i o n of s t a t i s t i c a l mechanics, theorem,

theory, not a

the virial theorem,

but there is a simple statistical

that illustrates

view one adopts w h e n N is large and permits

the changed point of

some useful averages to

be obtained. Consider a finite, b o u n d e d N - p a r t i c l e w i t h respect to the origin,

system at rest as a whole

and define the quantity

N

G =

Since no p a r t i c l e wanders

ever reaches

infinitely far away,

Z i=1

Pi.ri

(3.35)

an infinite value of m o m e n t u m or

G remains finite.

Further,

if we shift

the origin by r 0 the new G is

G' = [ pi'(r - r O] = G - r 0

E Pi = G

and so G does not depend on the choice of origin.

The time derivative

of G is

= Z (Pi.ri

=

2T+

~

+ ~i.r£)

F.-r.

where T is the kinetic energy and the quantity W = ~ F.*r. was called by Clausius

the virial of the system.

w h o l e remains at rest,

W, like G, is independent of the choice of

If the system as a

origin of coordinates. Let us find the time average of 2T + W.

It is

Gdt = Lim~7

Li~ ! T ._~oo T

0

But we have noted above that G(z)

- G(O)

always remains

finite;

the limit is zero, and the r e l a t i o n b e t w e e n time averages =

-

½~'

thus

is (3.36)

108

This is the virial

theorem

(Clausius,

Ig70).

The theorem has a useful application square forces--for evolving clusters in (3.3),

example,

to systems bound by inverse-

an atom, certain plasmas,

of stars.

Introducing

or slowly-

the interparticle

forces as

we have

Y

EE f . . . r .

=

i~j

~J

J

A typical pair of terms is

f12"r2

If the interparticle

+

~1

potential

"rl

= f12 "(r2

"

~1 )

=

V12

is

v12 --

Y -

Ir 2

rll

-

the force is YCr 2 -

f12

rl)

Ir 2 - rl I~

and Y f12-(r2

-

rl)

= _

Thus, Y = V, the total potential

Since by hypothesis

the system's

-

rtl

energy of the system, = -

conserved,

Ir 2

and we have

½~

(3.37)

total energy ~ + ~ = E is

this gives also

(3.38)

E = -~ = % F

Clusters

of Galaxies

The virial

theorem has an important

mass of a cluster of galaxies. of order R, the gravitational

application

in finding the

If the cluster has a mass M and a size potential ~" = -

G-~M2 R

energy is of order (3.39)

109

if v ~ is the mean square velocity of a member of the cluster,

then

and the virial theorem gives M

The n u m b e r s larger

right

does not further

a large know a t

(3.4o)

can be m e a s u r e d ;

t h a n w o u l d be e x p e c t e d

Apparently

Ideal

on t h e

= R Vs2

from the

the masses

luminosity

amount o f n o n l u m i n o u s

present

what

form it

mass

takes.

is

come o u t much

of the present,

See P e e b l e s

clusters. but

one

(1971)

for

details.

Gas The virial theorem also gives insight into the behavior of gases.

In an ideal gas the only force on a molecule is that exerted by the walls of the container.

In magnitude

and direction this is given by

dF = -PdA where P is the pressure and dA is a directed element area.

of

The virial is

W = -PIr.d

A

Evaluate this by Gauss's theorem:

W = -PIV.rdV where V is the volume of the container.

= -3PV The virial theorem now gives

3

= ~ PV

(3.41)

a relation familiar from elementary physics but here proved rather neatly.

Problem

3.20.

How is the result

(5.38) generalized if the force

follows an inverse-nth power law?

Problem

3.21.

Let the system be a hydrogen atom (N = 2) and the

electron and proton in circular orbits around their common center of mass.

Problem

Verify that the virial theorem is satisfied. 3.82.

If the system considered above is immersed in a uniform

magnetic field B, the force on each particle is augmented by evxB. Show that the virial theorem for charged particles now reads

m

110

where L is the system's total angular momentum. Problem

3.23.

It is generally true that expectation values in quantum

mechanics correspond to time averages

in classical mechanics.

and prove a virial theorem for quantum mechanics. (3.41) take in the quantum-mechanical

State

What form does

theory of an ideal gas?

CHAPTER 4

HAMILTONIAN DYNAMICS

The Lagrangian procedure of motion and simplifying and their constant

is very helpful

them through the use of cyclic coordinates

conjugate momenta.

is up to us to solve the equations. more powerful methods which will

and except

not get involved

in fact a large class of calcula-

5 to the evaluation

are of an altogether

for the chapter

on perturbation

to choose

the right variables

problems

in dynamics--our

depended

on the use of polar coordinates A solution

We need a technique cyclic coordinates improvement quantity.

as possible.

hamiltonian connections

There momentum

there is one more small is not an ordinary physical In the Newtonian

to be developed here start with the

that is with the energy, which than the lagrangian,

is a more funda-

and of course

in its usual

they lead to

formulation.

Equations

are two general ways to depict the time behavior

conjugate

a q, t diagram and a q, p diagram, to a given qn"

Pn equations

(2.53)

=

is defined as (4.1)

BLCq,~)

Bqn

Bqn

oscillator

(a) is a graph of x = acos(mt + ~). (2.10),

(4.2)

aLCq,~)

Fig. 4.1 shows how a simple harmonic of the energy equation

of a

where Pn' the

then become

Pn = Diagram

would be far harder.

so far it was simple to find, but this

with quantum mechanics

system:

Lagrange's

for example,

so as to find as many

it is not measured.

The techniques

function,

The Canonical

dynamical

Finally,

The lagrangian

we have performed so.

for solving

to give us the cyclic angular

coordinates

for changing variables

mental part of physics

4.1

in cartesian

It is not conserved;

is not always

order of

theory we shall

solution of the Kepler problem,

to be sought.

calculations

of a few integrals.

different

in them.)

It is important

coordinate.

it

later lead to the solution of problems

tions will be reduced in Chapter (Problems not so reducible

But once this has been done,

In this chapter we shall develop

with a m i n i m u m of equation-solving;

difficulty,

in setting up equations

is described

Diagram

in each.

(b) is a graph

the ellipse

~2

2mE + ~

X2 = /

(4.3)

112 It represents

time behavior because p itself represents

The point P representing on (a); on ~)

it moves

the oscillator's

clockwise

state moves

time behavior.

to the right

(why?) around the ellipse.

Lagrangian

P

/k/ ca) Figurg 4.1

Trajectory of an oscillator, (a) in

dynamics,

and the Hamilton-Jacobi

use the

q,t

representation.

The hamiltonian

qt

space; (b) in qp space.

theory to be developed

Hamiltonian

in Chapter

5,

dynamics uses q and p.

function corresponding

to a given lagrangian

is

defined as

H(p,q) (summed).

Pn4n

=

-

L(q,~)

(4.4)

To see why we call it a function of p and q, imagine

the system is varied, i.e., changed so

that p, q,

that

and ~ all change

slightly:

6H by

(4.1) and

=

(4.2),

pnB~n

+

~nBPn

3L

-

9q---~6qn

~L -

•

Bqn

~'---'~

this is

BH

~n~Pn

=

-

~n6qn

(4.5)

so that we need specify only the p's and q's in order to evaluate H. Changing one p at a time and one q at a time gives Hamilton's equations I ~H qn

=

~H

~Pn

The first of these,

"

Pn

=

anticipated

-

~qn

n

in (1.24),

=

I ....

H(p,q).

again, .the generalized

second law.

these equations i

(4.6)

tells how ~ is related

q and p; we need this in order to write form of Newton's

f

The second is

are no great advance over Lagrange's

Phil. Trans. Roy. Soc. 1835, Pt. I, p. 95. them many years earlier without recognizing

to

(4.2)

Computationally, equations.

Lagrange had published their value.

113

Formally however,

by virtue of their transparent structure,

first-order equations, they open the laws of dynamics.

they

from here,

Example

being 2f

way for a profound study of the

To express the fact that all further studies start

are called the canonical equations.

4.1.

Set up the problem of plane orbits by Hamilton's

equations.

Solution.

Use the coordinates r, 8.

L(q,~)

Then

= ½ m(~ 2 + r202)

- V(r)

The momenta are ~L/a~n , or t

p@ = mr2@

Pr = mr,

The Hamiltonian function is (2.67) expressed in terms of p and q,

(4.7)

H = --~ (pr 2 + po2/r 2) + V(r) and Hamilton's

equations

Pr =

--"

m

~

are

PO =

mr

2 "

PO

=

Since 0 is cyclic, PO is constant.

O,

Pr

po 2

3V

mr 3

~r

Further solution takes us along

essentially the same path we have travelled before. To investigate

the rate

at which energy in a system changes,

let

us consider the general situation in which the external interactions are time-dependent and H is a function of p, q, and, explicity,

t.

We have

d~ - ~Pn aH Pn + as'-'k'-qn + ~_A dt aqn ~t From

(4.6),

this is

dH dt and if the interactions

-

~H ~t

(4.8a)

are not time-dependent, dR

d---{ = o

(4.8b)

The system moves in such a way that its energy is conserved. That L sometimes has physical meaning even if it is not conserved can be illustrated by the example of special relativity. dimension,

In one

the kinetic energy of a free particle can be written as

114

=

ma2[(:

-

v2/o2)

-%

_

1]

(4.9)

m = rest mass

The relation w i t h L is

E = - ~dL v-L

L

=

U

plus a c o n s t a n t m u l t i p l e

I ~Edv

=

mc211

-

(I

-

V2/e2) ½]

o f v which we can omit

(4.10)

{Prob.

4.1).

There i s

an important point that can be made if we drop the irrelevant additive constant in L and write the action as

W =-mc2

I [ 1 - v2/c2]½dt = - mc2 I [dt2 - c-2dxZ]½

This is

(4. l l a )

W = -me 2 I d s and the law of motion becomes 6W = 6 I d s

= 0

(4.11b)

where d8 is the invariant element of proper time.

Let us suppose that

the integrand to be varied in (2.54) were not a relativistic

invariant.

Then we could make the integral larger or smaller by evaluating one coordinate system or another, some p r e f e r r e d coordinate system. are covariant

The only way to have results that

(independent of the coordinate system)

is to have the

integrand an invariant,

as has h a p p e n e d here automatically.

is an interaction term,

it too must be an invariant.

be noted again following Eq.

Problem 4.1.

If there

(This fact will

(4.15).)

Show that no generality

multiple of v that appears

it in

and setting 6W = 0 would pick out

in L.

is lost by omitting the constant

Set up the equations

problem and sketch their solution to the point where

for an actual

it can be seen

that the extra term does not matter. Problem 4.2.

Show that H and L are equal in the low-velocity limit of

the relativistic formulas just given.

Problem 4.3.

(This and the following problems

are d e s i g n e d to allow

the reader to explore one aspect of the relation between classical and quantum mechanics.)

Suppose that the equation of m o t i o n for matter

waves is taken to be of the general form

i~ ~

= H(p n, qn)~

n = 1 ... f

115

where the p's and q's are q-numbers does the ordinary probabilistic

and H is a function of them.

Why

interpretation of ~ require H to be

hermitian?

Problem 4.4.

Assume t h a t

[pm,qn ] = -ig6mn , and prove

[pm,Pn ] = 0

that

[qnk,pn ] = ki~qnk-1 = i~ ~-~--qnk ~qn Problem 4.5.

Show via Taylorts

series that

[f(qn),Pn] S u p p o s e now t h a t differentiation

Problem

f

is

a function

be c a r r i e d

4.6.

=

i~

~f(qn ) ~qn

of the p's

and q's.

How s h o u l d t h e

out?

Prove that

d

-ZY--

i

-- ~

<[H'Pn]>

-- - < ~ H

>

~qn provided that the differentiation

Problem 6 . 7 .

is carried out properly.

Show that

d

4.2

~H ~Pn

Magnetic Forces We have not yet considered the effect of an applied magnetic

field because it does not fit obviously into considerations energy.

based on

This is because the force on a charged particle F =

(e/c in Gaussian units)

is perpendicular

hence cannot affect its energy.

(4.12)

evxB

Further,

to the particle's motion and since we do not introduce

electric forces into the lagrangian formalism by means of the field, we should not expect to do so for the magnetic forces. of force,

it is the potential

Electrostatic by E : -V~.

For both kinds

that we must use.

fields are given in terms of the scalar potential

Magnetic fields are formed from a vector potential A by B =

If the potentials (in MKS units)

VxA

are time-dependent,

(4.13a)

(4.13a) still holds and E becomes

116

E =-V@

-

@A

~)---{

(4.13b)

Since the lagrangian is a scalar, A must enter as a dot product,

and

since the forces are v e l o c i t y - d e p e n d e n t we form the product with the velocity x.,

Let I be a constant to be determined later. L = ½mx 2 -

Suppose that

XA.~<)

e(~-

We h a v e ~A. ~L • Pi = ~x. = mx + eXAi,

3L - e( ~ ~x. = ~x.

- X

xj)

In taking the time derivative of 3 L / ~ i we must remember that a moving p a r t i c l e encounters a changing A even if A is time-independent, so we consider A. as a function of x.(t)

d

9L

and t:

~A.

~A.

J and the Lagrange equations are

mxi

Let i = i.

9A. ~j+ + el( m-~.

~A. ~ ~t

~A. • ~ . mj)

~ + e ~.

= 0

Then in this e x p r e s s i o n

~A i

~Aj •

8A I

~A~)~2

@Ai _ 8A 3 .

-- -B3& 2 + B2& 3

= (B×~)I=-

(~×B)I

and the equation of m o t i o n is

m~ : e ~ x B

@A

- e CW + ~ ~-~)

117

If we take

k = 1 this becomes

the equation

for a charged particle

in

MKS units, ./~ = exxB + eE

whereas

Gaussian units come from taking

The n o n r e l a t i v i s t i c magnetic

lagrangian

(4.14)

~ = c-*

of a particle

in an electric

and

field is therefore

L = ½ mx 2 -

In special

relativity

-

A.X)

the first term becomes

we know gives a relativistically contribution

e(@

of the interaction

invariant

C4.15)

-moZCl

-

X2/O2)½

contribution

to w.

which The

term is

Wint = -e [ C@- A'x)dt = -e [ (¢dt - A'dx}

Since

(¢,A)

forms one four-vector

(dt, x)

Win t is already invariant in form and need not be changed

is another, in writing

(Jackson 197S, Ch. Ii) and

down the relativistic

To find the h a m i l t o n i a n

version of (4.15).

corresponding

to (4.15) we calculate

@L

"~- = p = mx + eA

C4.16)

so that the energy is

E = :x. Cmx + eA)

- ½ m x 2 + eC@ -

A.~:])

or E = ½ mx 2 + e@ The magnetic

field seems

this expression

to have disappeared

for E merely repeats

change the energy.

(4.17) from the theory, but

that a magnetic field does not

To find the h a m i l t o n i a n we use

(4.16)

to express

E in terms of p:

H = 2-~ (~p -

eA~)2 + e@

I[4.18)

118

Here

p contains A though the energy does not.

in the historical

development

that it turned out to have a visible

(potential)

part.

field is rxp

(and not,

and an invisible

as one might perhaps

Show that the relativistic

Problem 4.9.

to (4.18)

(kinetic)

energy was

We can see now that the same is true of momentum.

Show that the angular m o m e n t u m of a particle

Problem 4.8.

magnetic

One of the difficulties

of the concept of mechanical

hamiltonian

think,

in a r×(p - eA).

corresponding

is H = c[(p

- eA) 2 + m c 2 ] ½ + e~'

(4.19)

An Electron Lens

It is not easy to find calculations by the use of Hamilton's example.

Fig.

equations.

4.2 shows a simplified

&

that are materially

The following

shortened

seems to be an

electron lens made of a single

I

0

Figure 4.2

circular

loop of wire.

use cylindrical

Loop of current serving as an electron lens,

Since the electron follows a spiral path, we

coordinates,

p, 8, z.

ring is given by an intractable the axis is approximated by z

Jackson,

1975, p. 177.

The vector potential

inside the

expression 2 which for points near

119

the axis

is a p p r o x i m a t e d by

p A@ = Iza a

p

z2]~/2

[(a + p)2 +

= I~a 2

(4.20)

(a2 + 2 2 ) ½

The l a g r a n g i a n is

p2~ L = ½ m(p 2 + p2~2

+ ~2)

+A (a 2 + z 2)

(see P r o b l e m 4.11),

and the h a m i l t o n i a n

A = I~a2e

h

is AP 2

H = I

(pp2 + pz 2) + ~ 1

Here 0 is a cyclic coordinate

[Pe

(4.21)

From ~ = dH/dpo

we have

+ 22)

and p@ = const.

2

3/2]

-

Ap e

[Po - (a2 + 22)3/2 ] This shows how far the h a m i l t o n i a n m o m e n t u m can be from one's idea.

intuitive

If you ask the e l e c t r o n why it is spiralling around the axis it

will answer that

it is conserving

its angular momentum.

Let us assume that far away at the object the beam originates the axis.

It then has 0 = 0 and so p@ = 0.

on

During the subsequent

mot ion, A = _ inca 2

+ Z2) 3/2

Since the m a g n e t i c field does no work, constant,

the electron's speed remains

and since the rays stay close to the axis this means

that z

is very nearly constant. To study the orbit, we have

dpp

=

_

dt and w i t h ~ = u -~ const,

dpp dz Assume

~H

~p

=_

A2p,

mC¢ 2 + z2) 3

this gives = dpp d__~t= _ A2p dt dz mu(a 2 + zZ) 3

that while passing through the ring the electron's

constant at b.

Then the total change in pp is f co AZb I dz App = - mu I (a2 + 22)3 _co

-

3~ A2b 8 muaS

p is about

120

From Fig. that

4.2,

tan# 0 = (pp/mU)initia 1 a n d tans i

tan# 0 + tan# i

and since tan¢ 0 = b/Zo,

tan¢i = b/Z i

=

_

(-pp/mu)final

=

so

,

&PPmu

this is

/_ I _ 3~ A2 3~ (eI~] iO + £i 8 m2u2a s - 8a - m u This is the equation

for a thin lens of focal length

8a

mu

f = ~

2

(e---~--~)

(4.22)

When the lens forms a real image it is not simply electrons

inverted,

for the

all spiral at a rate

de

de dt

A

S-; = S-? 2 ;

so that the total

rotation

=

=

In terms of the focal

+ z2)3~2

is

dz

2A

a 2 + z~3/2

mua 2

A

e

mu(~2

- m--J

length,

this is

e =-

. ~a)%

4t~f

If for example f = 3a, then O = -61 °. Note particularly differential

equations

that we have got these results but just by evaluating

first step in the direction we shall take in Chapter give a systematic way of reducing more or less difficult canonical

equations

developments,

Problem

4.10.

This

is a

5, which will

a large class of calculations

integrations.

is that

not by solving

integrals.

But the principal

they form the basis

to

merit of the

for further

formal

as the rest of this chapter will show. Use the first form of A e in (4.20)

and discuss

the

aberration produced.

Problem

4.11.

cylindrical

The construction

coordinates

Verify the formulas

Problem

4.12.

of L and H involve procedures

instead of the cartesian

with

ones used heretofore.

given in the text.

Show that

if a magnetic

field 8 is uniform and in the

121

z direction,

a possible A

x

= -%

By

Express

the h a m i l t o n i a n

Problem

4.13.

observed

(but not unique) A

To find the equations

the kinetic

hamiltonian

Problem

of Larmor's

Canonical

phenomena

z = z'

H =

p,2 _

in terms

and show that the

~'PO

the results

+

V(r)

(4.24)

of the last two problems, charged particles

of the same system without rotating

compare

in a magnetic

a magnetic

system of reference.

field

(This is the

Transformations

If a h a m i l t o n i a n

dynamical

order of the remaining

problem contains

are constants differential

to symmetries, are used.

important

cyclic coordinates

and can be used to lower the

equations.

Cyclic coordinates

but they only show up when appropriate

(In the Kepler problem,

leads to the conservation

use polar coordinates therefore

dynamical

theorem.)

their conjugate momenta

symmetry

(4.23)

0

Show that when written

is unchanged,

of a system of identical

field with the behavior

coordinates

=

y = x'sin~t + W'cos~t,

lagrangian.

Comparing

4.14.

correspond

governing

energy

but viewed from a suitably

4.3

z

becomes

the behavior

subject

A

let

- y'sin~t,

and find the transformed of momenta

= ½ Bx

y

is

in this case using the angular momentum.

on a merry-go-round,

x = x'cos~t

vector potential

for example,

of angular momentum,

but one has to

in order to get the cyclic coordinate.)

to be able to study the symmetries

ian and to capitalize

circular

on them by shifting

It is

of a hamilton-

to appropriate

coordinates

when one is found. With this motivation, canonical

equations.

the fact, m e n t i o n e d from Hamilton's

let us see how to change variables

The place

to start is Lagrange's

above but not yet used,

variational

6

in the

equations

and

that they are derivable

principle

L[q(t),

q(t),

t]dt

= 0

(4.25)

to provided

that the variations

end points.

The integral

in the 6q's are made to vanish at the

is known as Hamilton's

principal

functionjW,

122 and

(for fixed lower limit)

W(q,t)

it is a function

of the point q at

which all the paths arrive at time t.

In terms of coordinates

momenta,

is

the varied

integral

6

in (4.25)

IJt 0{pnqn•

- Hip(t), q(t), t]}dt

where we allow time-dependent difficult

to do so.

because whereas to vary

p's

interactions

We cannot at once

in varying

and

in H because

set it

(4.25) we set ~

and q's independently.

(4.26)

equal

to

= (6q)',

it is no more zero, however,

in (4.26) we wish

We must therefore proceed more

slowly. It will be useful requirement

that

in later work if we drop for a moment

the 6q's vanish at the limits of

perform a general

infinitesimal

variation.

integration

Denoting

constant)

the momenta,

the energy

and

the integral

before by W, we vary the path of integration with respect coordinates,

the as

to the

(which need not be considered

and the time at which a given point in the path is reached.

The first term of (4.26)

~[Pndqn ,

is

but we keep the time variable

for a moment:

6 I Pnqndt

= I [qn6Pn + Pn6(qn)]dt = (6qf, so

We have already noted that 6(5 )

that this is

I [qn6Pn + Pn(6qn)'] dt = I (~Pndqn + Pnd6qn) The second term of this integral as a change

dqn

in

(defined as

Returning

to

fPndqn that qndt) over

arises

from changing

and interpreted

the widths of the strips

which the integration

(4.26) we write

6W =

fPn6dqn

can be written

is carried

out.

the second term in the same way,

(6Pndqn

+ Pnd6qn

-

~Hdt

-

so

that

Hd6t)

~t 0

Integrating

t h e s e c o n d and f o u r t h terms by p a r t s

gives

6W = [pn6qn - H6t] tto + I~6Pndqnto Now suppose

6qndPn - 6Hdt + 6tdH)

that the path being varied

is what we shall call a

123

natural path,

one that is physically

the canonical

equations.

~H dt ~Pn

dqn = while by

possible

and therefore

satisfies

Since

~H--~--dt dPn = - ~qn

and

(4.8a) ~H ds = ~ d t

the last integral

is

it

_Jto~(3H 6Pn + --~qn~H6q n + ~3H 6t - ~H1dt = 0 Thus only the integrated part remains,

6W = [pn~qn if the variation

(4.271

H6t] t to

is away from a natural path, whether

or not the new

path is natural. Hamilton's lagrangian

principle

is stationary

that the variations selves

(4.251 asserts

vanish at the endpoints

are not varied.

and we have justified provided

of the

of q(t) provided

and the endpoints

them-

Under these restrictions 6w =

in (4.261,

that the integral

for arbitrary variations

the more general

0

(4.z81

form of the principle

expressed

in which the p's and q's may be varied independently

that the same restrictions

are observed.

Transformations Now let us adopt a new set of coordinates them to be functions

and momenta,

supposing

of the old ones and the time, pn(p, q, t) and

Qn(p, q, t). We assume that these relations are soluble to give pn(P, Q, tl and qn(P, Q, t). Further, we require that the equations of motion in P and Q shall again be canonical; that is, that when the changes

of variable have been made we again have

][PnQn - K(P, Q, t)]dt = 0 where K is the new hamiltonian of integration. preserve

called canonical

and 6Qn, like ~qn' vanish at the limits

Transformation

the canonical

(4.291

of this very general kind which

form of the equations

transformations.

of motion are properly

Today they are usually known as

124 contact

transformations,

somehwat

different

the subset consisting from changing

a term introduced by Hamilton

long ago in a

context, 3 and we shall use the term.

Q(q) and P(p,q)

of transformations

only the spatial

By contrast,

coordinates

that arise

are called point transforma-

tions. The final requirement natural path in (p,q) natural path. initial

for a contact

should,

(P,Q)

into

This will be so if, for corresponding

conditions,

same for all values

the integrals

is that

transformation

when translated in (4.26)

and

choices

(4.29)

of t O and tl, that is, if the integrands of a function whose variations

the limits of integration.

Since the variations

El(q,

of the

are exactly

most by the time derivative

such a function is the time derivative

there,

every

again be a the

differ at

vanish at

of q and Q vanish

of a suitable

function

Q, t):

6 I t~1(q, Q, t)dt = 6[FI (q' Q, t)] t = 0

(4.30)

to to Writing

out the time derivative

of F (q, Q, t), we have aF 1

Pn~n - H(p,q,t) which

is satisfied

= PnCn - K(P,Q,t) identically

provided

aF 1 .

(4.31)

~i (q' Q" t) ,

~qn

Bt

that

~FI (q" Q" t) Pn = -

aF 1

- --Bqn qn - ~Qn Qn

P

-

n

(4.32)

~Qn

and

~F1(q,~,t) H = K +

(We can also introduce (4.31) by different

9t

(4.33)

scale factors by multiplying

constants,

but what results

the two sides of

is only changes

in the

units of measurement.) There are other forms possible (4.30)

could solve the resulting

in a function F(q,

equations Pn = Pn (P'Q)

and reduce F to a function

To get a new transformation,

3

provided

it satisfies

it can be a function of any two of the variables p, q, P, Q,

but not more than two because

pn(p,Q)

for F:

For a condensed explanation (1923), p. 547.

Q, P), for example, we and qn = qn (P'Q)

for

of q and Q. replace FI(q,Q ) by a new function

of why the term is used,

see Sommerfeld

125

F2(q,P ) = Fl(q,Q )

where P is considered

as a function

will vanish at the endpoints. Pn~n

- H(p,q,t)

Then

= Pn$n

PnQn

of q and Q so t h a t (4.31)

- K(P,Q,t)

@F2 ~ BE2 - ~Pn " n - @qn qn As before,

this is satisfied provided aF 2

Pn

(q, P ) Qn

~F 2

"

H

=

K

+

(4.34)

at

n

In a similar way,

we can form two more functions

and generate

the

from

~F 3 (p, Q, t) aQ n "

Pn

• - QnPn

that

BP

@qn

transformations

aE 2 , ~t - PnQn

aF 2 (q, P ) "

=

its variation

is

aF 3 (p, Q, t) ap n ,

qn

H = K +

aF 3 (p, Q, t) at

(4.35)

and BF 4 (p,P, t) qn =

3F 4 (p,P,t)

@Pn

Example

I.

•

Qn =

3P n

BF 4 (p,P, t) ,

H = K +

Bt

Let

(4.3?)

F3(P,Q,t ) = PnQn

Then

(4.35)

gives

Pn = Pn" so t h a t as

it

this

is

sounds;

Example

2.

(4.36)

the

identity

we s h a l l

H=K

Qn = qn" transformation.

encounter

it

(This

is

not

as u s e l e s s

later.)

Let F l(q,Q)

= qnQn

We find Pn = qn"

This

is not very interesting

and coordinates

are merely

Qn = - Pn

computationally,

but it shows

that momenta

labels which we bestow on certain variables

126 for historical reasons.

Nothing is changed if we switch the labels

around. Point transformations

to new coordinates Q(q)

are often conven-

iently generated by F 3(p,Q)

since from

=

(4.38)

Pmfm(Q)

(4.35), ~fm

qn Example

3.

=

fn (Q)"

Pn

=

Pm ~Qn

To transform from C a r t e s i a n to polar coordinates

in a plane,

let x = Rcos@,

Px = m~,

y = Rsin@,

py = m~

SO that

F3(Px,Py,R,@ ) = R(PxCOS@

+ pySin@)

and along w i t h x and y we get

PR = Px c°sO + pysin@ = (XPx + ypy)/R PO = R(-PxSin@ yielding

the expressions

Problem 4.15.

+ pyCOS@) = Xpy - YPx

for radial and angular m o m e n t u m at once.

Find the t r a n s f o r m a t i o n from rectangular

to spherical

polar coordinates.

Problem

4.16.

Find the generator F3(P,X ) that caries out a rotation of

plane cartesian axes through an angle a: X = xcosa - ysina

P

= PxCOSa - pySina x

Y = xsinm + ycos~

The usual point t r a n s f o r m a t i o n s as are the infinitesimal

(4.39)

Py = PxSin~ + pyCOSm

are expressed in terms of F3's ,

transformations

to be discussed

in the next

section, but we shall encounter other forms in subsequent chapters. In particular, we shall be interested in canonical that leave the h a m i l t o n i a n invariant, as it was of p,q.

transformations

i.e., the same function of P,Q

This is what defines invariance.

127

Problem

4.17.

The hamiltonian of a simple harmonic oscillator ~(p,x)

= ~-~ + ½ 2m

is

~x 2

Carry out the contact transformation

FI(X~X ) = _ ½ m~x2cotX Find the new coordinate, oscillator

Problem

momentum,

~z = k/m and hamiltonian,

(4.40) and solve the

in the new variables.

4.18.

Find the F representing a transformation to a system of

coordinates rotating around the z axis, and verify that the hamiltonian in the rotating system is (4.24).

Problem

4.28.

coordinates

A point transformation

in terms of the new ones.

gives the new coordinates

Problem

4.80.

functions conditions

in the form (4.38) gives the old Find the transformation that

in terms of the old.

Show by comparing second derivatives

that a transformation

of the generating

is canonical if it satisfies certain

among which are

( n)q=

-

(%~m n) ~

Find the rest of these conditions.

Problem

4.81.

Show that the transformation Q = q½cos2p q =

p2 + Q2

P = q½sin2p

tan2p

=

P/Q

is canonical.

Problem

4.82.

generates

Find by integrating

(4.32) the form of Fl(q,Q)

that

the transformation of the preceding problem.

(Answer: FI(q,Q ) = ½ [ Q ( q _ Q 2 ) ½

+ qsin-1(Qq-½)]

Note that in all the examples given except that of Problem 4.18 the transformations

are independent of t and therefore, by

its later analogs, K(P,Q) = H(p,q).

(4.33) and

In the exception we are looking

at a system from a moving frame of reference and would not expect the energy to be the same.

128 4.4

Infinitesimal

Transformations

There are many transformations sequence

of infinitesimal

familiar

examples,

transformations

steps.

Rotations

and we shall encounter

are discontinuous,

polar coordinates.

Infinitesimal

interest because of their formal considerations invariance

that can be carried out in a and translations

others

in quantum mechanics,

and closeness

and because

to

are of special to analogous

the criterion

under such transformations

of the h a m i l t o n i a n

Some

that from cartesian

for example

transformations simplicity

are

less familiar.

for

is very easily

stated. Infinitesimal

coordinate

cases of infinitesimal displacement

transformations

canonical

of an object to the right

of coordinates

for rotations,

(or a displacement

to a

of the origin

£

the infinitesimal

X = x - ey,

f(x,y)

A function

and simple

Corresponding

to the left) we have

x+X=x+ whereas

are familiar

transformations.

and by infinitesimal

(4.41a)

form of <4.39) Y = y + sx

(4.42a)

is transformed

by infinitesimal

f(Z,Y)

+ ~f 3x

rotation

f(X,Y)

is

= f(x,y)

displacement

into

(4.41b)

into

--- f ( x , y )

(4.42b)

+ C (x ~f~y - y ~ )

Quantum M e c h a n i c s The application elementary.

of these formulas

The last two equations

in quantum mechanics

can each be written

is

in the form

f(x,z)

= (1 + ~ ) f ( x , y )

(4.43a)

f(x,y)

= (1 -

(4.43b)

with the inverse

where D is the appropriate

~(x,y)

is some dynamical

satisfies

a relation

~)f(z,z)

differential

variable

operator.

Suppose

in quantum mechanics

of the form aCx, y)f(x,y)

=

gCx,y)

~

that

and that

it

129

Operate with

cD)

(I +

on this equation

(1 + s D ) a ( x , y ) f ( x , y ) = By (4.43b),

(1 + e D ) g ( x , y )

this is (1 + e D ) a ( x , v ) ( 1

Thus the operator playing (x,v)

- sD)f(X,Y)

= g(X,Y)

the same role in (X,Y) that ~(x,y)

did in

is (1

which we may call A ( X , Y ) ,

+ eD)a(x,y)(1

[D,~]

-

(4.44)

sD)

and to first order this is

A(X,Z) where

= g(X,Y)

is the commutator

= ~(x,y)

D~-~D.

+ ~[D,~]

(4.45)

If D commutes with ~, then

A(X,Y) = ~(x,y) and we say that ~ is invariant under the transformation. If ~ happens

to be the hamiltonian

defines

a dynamical

factors

of i to make D hermitian

of measurement,

variable

we write

(4.43a)

f(X,Z)

operator

that satisfies

of some system, a conservation

and ~ to introduce

then law.

Adding

conventional

units

as

= (1 + ~

(4.46)

G)f(x,y)

where = - i~D

In contrasting designate

classical

operators. =

-

(4.47)

and quantum mechanics we generally use hats to

The two examples

given above give

^ Px

(displacement

i~

l~

=

in x)

(4.48)

and

= Xpy - YPx respectively,

which are recognized

angular momentum. invariance

The situation system is supposed wave function,

the quantity

are closely

$, called the generators

same as the operators

is especially

simple

which depends

(4.49)

of linear and is conserved.

Thus

linked in quantum mechanics. of the transformations,

giving the conserved

to be specified

in xy plane)

as the operators

If H is invariant,

and conservation

The operators

(rotation

dynamical

in quantum mechanics,

as completely

are the

variables. because

as possible by its

only on the coordinates

and time, f + I

a

130

variables

in general,

in classical variables. classical

while

theory require

the more closely specified coordinates,

Thus we may expect

momenta,

and

that the corresponding

systems

imagined

time, 2f + 1 formalism

in

dynamics will be a little more complicated.

Unitary Transformations In the two examples generator

given above

in (4.48) and

G turned out to be a hermitian

this was to be expected. ~' = (I + ic~-IG)~ translated

If ~(x,y)

describes

make no difference

operator.

describes

another

or rotated with respect

identical

the

Let us see why

a certain system

to the first.

to the n o r m a l i z a t i o n

(4.49),

system,

then

infinitesimally

Clearly

this can

of the wave function;

we must

have

I = ; ~'*~'(dx) =I~I + iE~-IG)¢(I + iEh-IG)~(dx) and only if, for all ~,

will we have

= [ ~*~(dx) = I Transformations

of the form

and their defining fundamental

property

eigenvalues, physics

hermitian

motion. laws:

operators

is that they have real with analogues

relation:

by hermitian

corresponds seen,

baryon number,

charge and so on.

a unitary

dynamical

leaves

particles,

electron number,

the hamiltonian of the

statement.

Physics,

is rich in conservation

muon number,

Each of these corresponds

by a

and vice

is a constant

is the converse

of elementary

theory and so provides

represented

transformation

variable

in classical

Thus we have a

variable

if the transformation

interest nowadays

the physics

operators.

to every dynamical

the corresponding

Of more

underlying

A

variables

As we have

especially

are called unitary,

of hermitian

operator

invariant,

(4.46) with G hermitian

is that they preserve normalization.

and so all dynamical

are represented

reciprocal versa.

property

to first order

charge,

hyper-

to some invariance

a clue as to its eventual

of the

structure.

131 Classical

Mechanics

An infinitesimal

transformation

is defined as one which differs

only infinitesimally from the identity

transformation.

the identity is F 3 = P n Q n (it is also F 2 = the same results). We write F3

where

e is infinitesimal,

function of p and q.

P

n

= Pn

e

-

noting

From

~G , 3Qn

PnQn

=

i,

that leads to

- eG(p,Q)

that in the limit e ÷ O, G becomes

(4.35), we have

= -Qn

qn

In Example

, but

-qnPn

~G J ?Pn

-

a

to order e

H(p,q)

=

(4.50)

K(P,Q)

Again to order e, this gives

APn

so that,

= P

Pn

n

3G

= - e

9qn"

Aqn

=

3G

e

(4.51)

9Pn

for any function a ( p , q ) ,

Aa

=

(4.52)

(a, G )

~

where we define

Ca, G) : This combination S. D. Poisson Obviously,

~a

~G

~Pn

~Pn

3qn

of derivatives

was

introduced

by comparison with the foregoing [D,~], although

G = - i~D

expresses

3G

~qn

that

into dynamics

significance,

by saying

generated by G means

invariance

it corresponds

one usually

that

[G,~] corresponds example,

formulas,

by

of a and G.

since it is not D but the hermitian

has physical

the correspondence

As a special

(4 53)

in 1809 and is called the Poisson bracket

to the commutator operator

3a

to i h ( G , a )

of H ( p , q )

under

(4.54)

the transformation

that

(G,H)

=

(4.55)

0

The result of Problem 4.24 shows that if this is so, the numerical value

Problem

of G remains

4.23.

dynamical

constant.

Verify

variables

the correspondence

familiar

(4.54) using some pairs

from classical

of

and quantum mechanics:

132

Pi (linear momentum) n i and pj. Problem 4.24.

and xj, L i (angular momentum)

and Lj, L i and xj,

In quantum mechanics,

d i ^ dt = ~ <[H,~]> for any time-independent operator ~.

dynamical

variable

Show that for any classical =

Show that

a represented

dynamical

by an

variable

a(p,q),

(4.57)

(a,s)

in agreement with the correspondence

Problem 4.25.

(4.56)

(4.54).

(4.57) contains

Hamilton's

equations

as

special cases.

Problem 4.26. (4.53)

Show that the canonical

coordinates

and momenta

in

satisfy

(qm,Pn)

(pm,Pn) = (qm,qn) = O, Problem 4.27.

If a dynamical

=

(4..58)

6mn

a(p,q) is re-expressed in terms

variable

of P and Q we call it A, A(P(p,q),

Express

Solution

Q(p,q))

(4.59)

= a(p,q)

9A/~P and 3A/~Q in terms of the generator of the transformation. Writing

~A BPn and similarly

~a ~Pm ~Pm ~Pn

-

@a 9qm ~qm ~Pn

+

for @A/@Qn, we need Bqm/~P n and 3pm/BPn.

to order c,

Pm = Pm + e

~G

~qm

"

qm = Qm - ~

@G

3Pm

so that, again to order E,

BPm -

6

~Pn

mn

+

e

@2G Bpn~qm"

-

~qm BPn

=

-

e

~2G ~Pm@Pn

-

and BA

~Pn

_

Ba

BPn

+

e

~a

~2G

(~P---m ~Pn~qm

_

~a

_~G

~qm BPn@Pm ~

From

(4.50),

133

or

(4.60a)

t @Pn

~Pn Finish the problem by showing that A

@a_.~_ =

cr @G

Bqn

Problem

4.28.

(4.60b)

a)

~ Bqn"

What transformation,

for an N-particle

system,

is

generated by the time-dependent generator G = Pt - M~ where P i s

the total

momentum,

M is

the t o t a l

mass, and [

locates

t h e c e n t e r o f mass?

Special

Transformations

Up till now we have not specified any generator G(p,q). Let us try some of the dynamical variables we have encountered so far.

i.

G = Px"

We have na

=

E

so that as in quantum mechanics,

Ca, Px)

@a

=

~

~'-~

p generates the linear displacement,

(4.41a). 2.

G = P8 = xpy

YPx ~a ~a__a_ ~a @a Aa = ~(x ~-~y + Px @py - y ~ - Py --)Bpx

corresponding

to a rotation through an angle e.

This

also is

as i n

quantum mechanics. 3.

s = H(p,q)

Aa = ECa, H} = e~

by (4.57).

(4.61)

Thus Aa is the change in a during a short time g, and the

natural motion of a system can be regarded as the continuous unfolding of a canonical transformation generated at each instant by H. corresponds

to Schr~dinger's

This

equation, which in a similar notation is

A~(q,t)

= - i ~ e H ~ (q, t )

(4.62)

in which H is the operator that takes us from one moment to the next.

134

Problem 4.29. generate

Because

the vector A of

an infinitesimal

the Kepler problem

invariant.

find the transformations will

is constant,

that leaves

Choose a single component,

it generates

it must

the hamiltonian say A

x,y,Z,px,Py , and Pz"

in

of

and z You

them of a more general kind than any of the forms dis-

find

cussed earlier, now continue changes

(2.91)

transformation

since the new coordinates

and prove

of variable,

complexities

the invariance

involve

the momenta.

of the hamiltonian

If you

under these

you will have some idea of the mathematical

that lie beneath

our relatively

simple

formulas.

Properties of Poisson Brackets The Poisson brackets

of dynamical

variables

satisfy

the following

relations: (a,b)

(a,b

+ c)

(a, bc)

=

=

in (4.63c) derive

is that if the variables

of

Time-independent

the Poisson bracket

(c,(a,b))

as well

identity. by Poisson

in 1809,

to P,Q by a canonical

(a,b) remains unchanged.

but that it leads to canonical

transformations

are simplest.

equations

Start with

(a,b) of two arbitrary dynamical variables

as functions

of p and q.

~j

Make a canonical

transformation

it only in b:

~Pi + 3P j ~ i ) - ~a__q_ ~b ~P~) . 9Pi (gb ~Qj ~Pi + ~Pj

= (a, Pj) ~~b. + J

(a, Qj) ~~b.

Now let b be the hamiltonian By Hamilton's

easy to

the last takes a little work

from p and q to P and Q, but for the moment make

Ca, b) - 9qi

(the order of factors

and all are trivially

(a,b), established value of

(4.63d)

= 0

theorem we must use the fact that not only is

there a change of variables

expressed

+

p,q are transformed

the numerical

To prove Poisson's motion.

(b,(c,a))

for commutators)

property

(4.63c)

+ b(a,c)

It is called Jacobi's

A remarkable

(4.63b)

(a,c)

that for Poisson brackets

(Problem 4.30).

transformation

+

+

apply to commutators

is correct

except

(a,b)

(a,b)c

(a,(b,c))

All these formulas

(4.63a)

= -(b,a)

H; in the new variables

equations,

(a,H) =(a, Pj)Qj - (a, Qn)P j =

(4.64) it is

K(P,Q).

of

135

But a is arbitrary,

so that if it is now considered as a function of

P and Q we must have ~a

(~,Pj) = ~Qj , Putting these relations

into

in w r i t i n g

theorem.

~a ~b DPj ~Qj

It results

(4.65)

in a convenience

of notation:

(a,b) we need not specify what independent variables

being used, as well,

~p.j

(4.64) gives

~a ~b (a,b) = ~Qj ~pj which is Poisson's

~a

(a, Qj)

and of course

it leads to computational

are

simplifications

as will be seen in Chapter 7, since some coordinates

are

m u c h simpler than others. As an exercise for the reader, Poisson's

Problem 4.31 asks for a proof of

theorem valid for infinitesimal

easily be c o n s t r u c t e d from

(4.60).

Problem 4.30.

Prove Jacobi's

Problem 4.31.

identity.

Show that for any

A(P,Q) and B(P,Q) defined as in (4.59),

the Poisson bracket is invariant under

Problem 4.32.

Show

ical v a r i a b l e s P

n

infinitesimal

transformations.

that if Pn and qn are transformed to new canonQn'

and

(Pm'Pn) = (Qm, Qn) = O, These relations

transformations, w h i c h can

(QmPn) = ~mn

(4.66)

can be taken as the d e f i n i t i o n of a contact transfor-

mation.

Problem 4.33. to

(4.65)

4.5

and

State and prove relations

analogous

(4.66).

G e n e r a t i n ~ Finite T r a n s f o r m a t i o n s If we iterate an i n f i n i t e s i m a l

one.

in quantum mechanics

from Infinitesimal Ones

t r a n s f o r m a t i o n we obtain a finite

How to do this is e s p e c i a l l y obvious

in quantum mechanics,

in

which

f ( x ) = (1 + i~ Suppose we w i s h

to make e cover a finite range X by iteration.

divide the range into n steps, with n eventually which

e = y/n.

Then

f(X)

Lira =

(1 + ix ~)nf(x) n~

infinite,

We

in each of

136

The limit is the exponential,

and even though ~ is an operator we can

still write

f(x)

=

exp

(/_z ~)f(x)

(4.67a)

._~ ~2 + "" .)f(x) 2~ 2

(4.67b)

or

(I + i--X- G

f(X)=

-

Classical contact t r a n s f o r m a t i o n s way,

are iterated

in much the same

though since the identity from elementary calculus

have to do a little more work.

We have, c o r r e s p o n d i n g

isn't there we to an infinites-

imal p a r a m e t e r

Ae(P,Q)

= a(p,q)

- e(G(p,q),

(4.68)

a(p,q))

Let us assume that the finite t r a n s f o r m a t i o n is of the form

Ay

=

a

-

y(G,a)

+ X2Y2(G, (Gja)) + X3Y3(G,(G,(G,a)) ) + ...

where the k's are to be determined. increment of y, we can write

(4.69)

With e as an infinitesimal

(4.52) as

dA~ = -

(G, Xy)

(4.70)

Applying t h i s to (4.69) gives - (G,a) + 2X2~{(G, (G,a))

+ 3X3X2(G,(G, (G,a))) 2(S,(G,(~,a)))

and c o m p a r i s o n of coefficients

= k 2 = ~, so that

.

gives

I

k3

(~I) n

- ~,

...,

kn =

n!

(4.71)

the finite t r a n s f o r m a t i o n can be w r i t t e n as

AX

=

a +

~

E i

(_~)n (~n "a)

(4.72)

n!

(Gn, a ) is the n-times iterated Poisson bracket.

where

Problem

4.34.

Generalize

transformations, analogous

Problem like

+

+ ...

to

4.35.

(4.57).

the infinitesimal

formula

(4.45) to finite

and find an e x p a n s i o n in m u l t i p l e commutators

(4.72). Equation

(4.72) gives the formal s o l u t i o n of equations

It is clumsy but it works.

Show it works by using it

137 to c o n s t r u c t

the s o l u t i o n of a simple harmonic oscillator that starts

at t = 0 w i t h x = a, p = 0.

Problem 4.36. by G = x n ?

What i n f i n i t e s i m a l contact t r a n s f o r m a t i o n is generated

By G = x n"9

Problem 4.32.

The i n f i n i t e s i m a l rotations

(4.42a) can be w r i t t e n in

matrix form as 1 -e

(~) where

= (e

x

i)%)

1 is the unit matrix.

= [i + ¢(I

0 -I

x

0)]% )

Iterate this to find the t r a n s f o r m a t i o n

that gives a finite rotation.

The Parameter

of the Transformation (4.72) with a = Pn or qn

If we apply the finite t r a n s f o r m a t i o n we generate

t r a n s f o r m e d variables

Pn (Y,P,q),

Qn (X,P,q)

w h i c h we shall use to define Pn and Qn as functions of y for fixed initial values Pn and qn c o r r e s p o n d i n g

to y = 0.

From either of

these we can solve for y to get y :

The r e l a t i o n parameter

to P + d P

~(P)

or

~ :

y(Q)

(4.73)

(4.52) gives the change in any function A(P,Q)

is varied.

and Q to Q + dQ.

dA

(4.74)

(A,G)

Let A be either of the functions y defined in (4.73). (y,G)

a parameter

that

P

With ¢ = dY we then have

dy -

Here y is

as the

Let y increase to y + dy and correspondingly,

enters

Then

= 1

(4.75)

our description

see that G is a c a n o n i c a l l y conjugate parameter. sarily c o n j u g a t e c o o r d i n a t e and momentum,

of

the system,

We

They are not neces-

though that is what they

may sometimes be, as in the following example will show.

Example

4.

We have seen above that G = xpy

of the axes in the xy plane.

YPx generates rotations

If the angle of r o t a t i o n is Y, we find

138 PX = Px c°sY - pysiny

X = xcosx - ysiny

(4.76) Py = pxsiny + pyCOSX

Y = xsinx + ycosy

These can be solved for y by writing

X + iZ = eiY(x + iy),

them as

PX + iPy = eiY(p x + ipy)

so that y = -iln(X + iY)

+ const.

Y = -iln[P X + iPy) + const.

or

In terms of the transformed variables

G = XPy

G retains

its form,

YPx

(4.78)

and we can now verify at once, using either of the forms not both!)

that

(4.75)

(4.77)

(4.77)

(but

is satisfied.

Problem

4.38.

Derive

Problem

4.39.

Carry out the differentiations

eq.

(4.78). that verify

(4.75)

in

the above example. Now in (4.74),

let A = H.

leaves H invariant,

If G generates

a transformation

that

we have dH d-~ = (R,a) = o

where

the derivative

on the left means

dH dx T~us H is independent and Q.

We have previously

in terms of P

cannot call it a

it is not in general one of the coordinates

argued that corresponding

nate there is a conserved m o m e n t u m

canonically

turn the argument

there is a conserved

~X

N is a cyclic parameter--we

because

last few paragraphs

8Qn

of y, however y may be expressed

In other words,

cyclic coordinate Q.

~H ~Pn 9H 8P n ~Y + ~Qn

to any cyclic coordi-

conjugate

to it.

The

the other way and show that if

dynamical quantity one can construct

a canonically

conjugate parameter w h i c h is cyclic. These results

clarify the relation between ~ and t.

already seen that the natural the hamiltonian,

We have

evolution of a system is generated by

with time as parameter.

Thus t and H are canonically

139

conjugate. sense of

But they are canonically conjugate as parameters

(4.75) and not as coordinate and momentum.

point of Hamilton's

equations

is to find p and q as functions of t, it

makes no sense to take t as a coordinate. ed carefully,

in the

Since the ultimate

This point should be absorb-

as it has caused a certain amount of confusion in the

literature. 4.6

D e d u c t i o n of New Integrals It is trivial in quantum m e c h a n i c s

that if H commutes with

dynamical variables a and b, it commutes with their commutator, the consequences are profound.

but

In classical mechanics Jacobi's

identity yields

d__ (a,b)

dt

so t h a t

if

important fore out

a and b a r e result,

of lowering

it

order

b))

then

gives

=

(a, Cs, b))

(a,b)

is

also.

a way o f f i n d i n g

of the

equations

- (b,C~,a)) This

is

integrals,

of motion,

a very and t h e r e -

without

carrying

any i n t e g r a t i o n s . One c a n ,

brackets, because

but

initial

of course, after and f o r

instant t o .

Isotropic

k e e p on f i n d i n g

a certain

a system with

integration,

The

constant,

since the

=-(~,Ca,

point

f degrees

integrals

nothing

o f f r e e d o m has

an e n e r g y - c o n s e r v i n g

by e v a l u a t i n g

new w i l l

be f o u n d .

at most

Poisson This

2f constants

s y s t e m one o f t h e m i s

is of

the

An example will show how this comes about.

Oscillator

A soluble example of the consequences

of Jacobi's

identity is a

simple harmonic oscillator

in two dimensions with x and y forces equal,

Fig.

is

4.3.

The H a m i l t o n i a n

1 (px 2 + py 2 ) + ½ k(x 2 + y2) H = ~-~

(4.79)

X

Figure 4.3

Isotropic oscillator with orbit arbitrarily oriented.

140

and from the circular

symmetry we know that the angular m o m e n t u m

L = xpy is constant.

To find another

the hamiltonian

integral,

of two uncoupled

Since each conserves

(Px 2

It is now a simple matter

-

(4.801

we note that H is the same as

oscillators

its energy,

B = 2-~

YPx

of the same frequency.

the difference

py2)

k(x 2

+ ½

to find a fourth

-

in energy

is constant:

y2)

(4.81)

integral by Jacobi's

2 C = (L,B) = ~ (pxPy + mkxy) Continuing,

theorem,

(4.82)

we find

(C,L) = 4B

so that no further new integrals

4kL

(C,B)

and

(4.85)

/17

can be found in this way.

fact found more than the 2f - 1 = 5 independent

integrals

We have expected,

in and

one can verify that H 2 =

B 2 +

%

Thus only three of the four integrals The integral

(4.82)

represents

C2 +

(4.84)

0~2L 2

are independent.

physical

property of the oscillator

that does not depend only on the energies of its component motions. To see what it is, write

the motions

x = asin~(t where

B is a constant

- tO),

Unlike H and B it depends

case the center of force

on the difference

(4.82)

is

in phase.

integral

(or perhelion).

is at the center

is ambigous,

tion will be better.

Then

- to) + 8]

2abm~2cos6

p r o b l e m has a vectorial

center of force to the aphelion of the vector

y = bsin[~(t

phase difference. C =

The Kepler

in z and y as

that points

from the

Since in the present

of the orbit,

the direction

and this warns us that some other descrip-

A glance at the integrals H, B, and C shows

~hat they define a constant

second-rank

tensor

1 Aij = ~-~ pip j + ½ k x . x .J

(4.8s)

141

in terms of w h i c h

(4.84) becomes

AxxAyy

- Axy

2

~2 = T

L2

~2

=

k

(4.86a)

while A

+ A

xx

yy

= H

To relate the tensor to the orbit,

(4.86b)

choose the x axis to coincide

w i t h the major axis of the ellipse and let t o = 0.

Then B = ~/2 and

the oscillator's m o t i o n is given by x = acos~t,

(a>b)

y = bsin~t

and we readily find that A

xx

= ½ ka 2,

A

yy

= ~ kb 2,

The axes chosen reduce A.. to diagonal pal axes of the tensor.

A

xy

= 0

form and are called the princi-

E v a l u a t i o n of H and L gives

= ½ k ( a 2 + b2),

L = kma2b 2

whence a2 = ~I [H + (H 2

-

~2L2)½]

b ~ =Z

When L = 0, b = 0 and the oscillations are linear. m o t i o n is in a circle,

Problem

4.40.

When eL = H the

and no larger value for L is possible.

Find the e c c e n t r i c i t y of the orbit in terms of H and L

and in terms of the components simple form w h e n p r i n c i p a l Problem

4.41.

ian coordinates Problem

4.42.

of A... Show that it reduces to a ~j axes are used.

Calculate the infinitesimal

transformations

of cartes-

and momenta generated by H, B, and C. Calculate the infinitesimal

transformations

of coordin-

ates and m o m e n t a generated by A... ~J Problem

4.45.

components Problem

4.44.

mechanics Problem

Find the P o i s s o n brackets

connecting the various

of A... ~J Solve the isotropic harmonic oscillator

in quantum

and give the d e g e n e r a c y of each level.

4.45.

degeneracies.

Do the same in polar coordinates and again note the

142

Problem 4.46.

Except for scale factors,

the Poisson bracket relations

(4.82) and

(4.83) are the same as those of the components of angular

momentum.

This suggests a way to find the energy levels of the

oscillator

in quantum mechanics.

quantum-mechanical

terms,

Transcribe

the entire d i s c u s s i o n into

find the commutators, which will again

resemble those of angular momentum,

and, noting

(4.84), use the appara-

tus of a n g u l a r - m o m e n t u m theory to find the energy levels and their degeneracies.

Be sure your results are the same as those of the last

two problems.

Problem 4.47. the trace of same.

Show that if the coordinate

A

axes are rotated by

(4.76),

(tr A = Axx + Ayy) and the determinant of A remain the

The trace occurs

in ( 4 . 8 6 ) .

What is the determinant?

Problem 4.48. For the Kepler p r o b l e m in the xy plane, the components A x and Ay of Laplace's vector integral are constant. Does (Ax, Ay) give a new

4.7

integral?

Commutators and Poisson Brackets shared by commutators

and

Poisson brackets that the two have a p r o f o u n d formal parallelism,

It is clear from the list of identities

and

yet it is not easy to see why dynamical v a r i a b l e s

they are so much alike.

In fact,

a and b in the Poisson bracket are functions

n o n c o m m u t i n g p's and q's,

it is not even obvious how derivatives

if the of should

be taken. With commuting variables,

~l'

"''' ~K the ordinary partial deriva-

tive is defined by aa Lim 1 a~. = e÷0 ~ [a(~l . . . . With

noncommuting

variables

~i + e . . . .

we d e f i n e

a more

~K) - a(a)] general

derivative

(4.87) s

involving an arbitrary function o(~), aa {c} = Lira 1 [a(al, aa. e+ e Bloore calls

"""

ai + ec . . . .

this a Fr&chet derivative.

~K ) - a(a)]

If c commutes with all the

~'s, then

aa.

s

F.J.Bloore, J. Phys. A. Math.,

(4.88)

aa.

Nucl.

Gen.

6 L7

(1973).

143 Evidently,

the Frechet

derivative

BCa+b) {c} Ba {c} + 3b De. - Be. ~

satisfies ~

{c},

We shall now prove a remarkable

theorem

~a.Ba{ [ a i , b ] } The proof

is by induction.

We write

the usual rules

that

~a

{c}

involving

commutators:

(summed)

= [a,b] the general

sum of pieces

each of which is of the general

and we assume

it to have been proved

another

{c} = y

@e.

(4.89a)

function a(~)

as the

form y a 3 ~ 2 ~ 2 ~ l ~ 3 ~ l a 4

for one such piece,

a'.

....

Now add

factor of e. on the left. J

(eda ') Be.

{[ai,b]} = Lira I

~+0 i (~j + e[aj,b] - ~j)

= [aj,b]a' + aj[a',b] Thus if (4.89a)

holds

the theorem holds is complete

trivially

and the theorem

To establish replacing

for a', it holds

a' + aj @a'

~

{[e~,b]}

= [aja',b]

for

aja'

Now set a' = ~k;

as in the steps just taken.

The induction

is proved.

the relation with Poisson brackets we rewrite

(4.89a)

i by j, b by ai, and a by b:

~Bb a.

{

[=j"ai]}

=

[b,ai]

=

[~i "b]

J or

aa.~b { [ a i , ~ j ] }

(4.89b)

J Now substitute

this into the left side of (4.89a):

@a.

~

{[ai,aj]}}

=

[a,b]

(4.90)

J This identity will give us a relation between brackets. and ql'

Divide

the dynamical

variables

commutators

and Poisson

a i into two sets, Pl'

"'" Pf

... qf, with [qm,Pn ] = i~mn

(4 91)

144

As ~i and aj go through all the p's and q's we get

3.aBqn{8BP~ {i~}}

BPnBa'-q--{ @k

+

[a,b]

{_i~}} =

or by (4.88),

[a,b] where the derivatives

i~ ~a

3b

~a {~b } @Pn @qn

(4.92)

of b are the usual ones defined

in (4.87).

The

quantity on the right is a version of the Poisson bracket which is appropriate version

to noncommuting

if the variables

variables

commute.

and which reduces

similarity between Poisson brackets

and commutators.

If we were to overlook all questions side of (4.92), derivative,

the Frgchet derivative

of commutation

would become

which would amount to putting

there are additional

relations.

[a,b]

on the right

the ordinary

an = sign into

terms left over proportional

the omitted commutation

to the e-number

This is the origin of the formal

(4.54).

to ~, ~2,

But

... from

We have therefore

= i~(a,b)

(4.93)

+ O C~ ~)

From a formal point of view, nothing more can be done to establish the ally,

correspondence

between classical

the correspondence

and quantum theories.

(4.54) can be obtained only by keeping

commutators

(4.91)

cummutators

in going from

procedure.

Since there is no universal

order the numbers

in going from

to (4.93).

physics

have taken pains to symmetrize

Problem

recipe

that

tells

should be written

the quantity A in (2.107)

we recommended

cummutes with the hamiltonian. scription

This is not a consistent in what if they are

It is for this reason that although we in Problem 2.70

verify that it is in fact the correct requirement

all all

the omitted terms of the order of ~ must be

supplied by other arguments. make it hermitian,

(4.90) to (4.92) and ignoring

(4.92)

of classical

to become operators,

Specific-

of hermiticity

into operators

Except

that

and therefore

the reader

form by seeing whether in the simplest

it

cases the

is not enough to make sure that the trans-

is correct.

C a l c u l a t e [ p 2 , x 2 ] by t a k i n g F r ~ c h e t d e r i v a t i v e s and a l s o by e v a l u a t i n g t h e commutator d i r e c t l y . Compare the r e s u l t s w i t h 4.48.

i~(p2,x2).

145 4.8

Gauge Invariance It is perhaps

surprising

that the Hamiltonian

in an electromagnetic

particle

than the fields. particles,

The fields

whereas

field involve

are defined

the potentials

tional definition

them or the forces they exert. particles, well,

potentials

defined by the sources When one studies

pattern,

is affected by the existence

understand,

that produce

the laws of motion in

for example,

of a potential

rather than fields

though in classical

The potentials

opera-

as we

fields govern the orbits of

through which the beams pass is entirely rence of potentials

7.8), and indeed,

govern not only orbits but phase relations

so that an interference

phases,

do not have any such obvious

one finds that whereas

quantum mechanics

for a rather

in terms of forces on charged

(but see Park 1974, Sec.

shall see, are not even uniquely

equations

the potentials

Thus the occur-

in quantum mechanics it remains

on

even if the region

field-free.

mechanics

A and ¢ determine

as

which depends

is easy to

somewhat

the fields according

opaque.

to the

relations: ~A

B = VxA

Now introduce

new potentials

A'

where ~(~,t)

and E determined

according

to

@' = @ - ~

(differentiable) are unchanged;

The latitude

but it introduces mation

of definition

potentials

into something

The classical

as we shall show,

(4.95) with arbitrary

of a simple static electric

field at all,

equation

by the forces

is often convenient

some complications,

of A and @ via

Such a change

The values

they

for computation, for transfor-

I can convert even the

and/or magnetic

field,

or no

time-dependent and elaborate.

of motion, m~ = e(E + v x B )

is gauge-invariant Schr~dinger's

because

of 8

this is what is meant by

saying that A and @ are not uniquely determined exert.

(4.95)

function.

is called a gauge transformation. by (4.94)

(4.94)

~X

= A + VX,

is an arbitrary

of the potentials

E = -V@ --~-~.

it depends

only on the fields,

(4.96)

but in

equation

iH ~

1 (p - eA)2 + e@]~ = [~m

(4.97)

146

the potentials occur explicitly.

The equation can, however, be made

gauge-invariant like (4.96) if we introduce a change in the (unobservable) phase of the wave function connected with the gauge transformation (4.95): 9'

:

e~P~,

e

p

= ~ X(x,t)

- ~)e~P~

(4.98)

Then, in (4.97), i~

Similarly

~~ t

-

e~'~'

= i~ ~t e ~

-

e(~

=

e ip

-

(~

=

eiP[i~ ~

[i~

~

~p

TT+

~h

e¢ - ~ T T ) ~ ]

e~]

-

(Problem 4.49) (p

-

eA')~'

=

e~P(~

-

(4.99)

eA)~

from which follows by simple steps the gauge-invarian~e of (4.97) (Problem 4.50).

Pauli has called the transformations

(4.98) and

(4.95) gauge transformations of the first and second kinds respectively.

It is clear that the physical results of the theory should be

independent of the choice of potentials, but how this is to be achieved raises some interesting questions•

Problem 4.49.

Prove (4.99).

Problem 4.50.

Prove that the complete Schr~dinger equation (4.97) is

gauge invariant.

Problem 4.51. Prove that the eigenvalues of the equation H~ n = En~ n depend on the gauge chosen but that those of (H

-

e¢)~n

:

en~ n

are gauge-invariant.

Perturbation

Theory

Let us start with a system bound together by its own internal forces and described by a hamiltonian ^

~o : #-#-~m+

eV

(4.lOO)

147

written

in one-particle

are not restricted immersed

form for simplicity

in an external

electromagnetic

and that we wish to study the effects to be considered

wave equation

in cartesian

=

act on A,@ but not on W.

-

+

are considered

to split H into an unperturbed

~, this is not a gauge-invariant

The

The

+

(4.101)

equation. as a perturbation,

it is

part H 0 plus a perturbing

but since it is ~ - eA that

potential,

A,@,

coordinates,

it is a gauge-invariant

If the external potentials natural

this system is

field B,E with potentials

=

and, as we have seen,

our considerations

of this field on the system.

gauge transformations is now,

though

Suppose now that

to one particle.

is gauge-invariant

separation.

and not

The fact does not mean

that we will get wrong results, since nothing has been falsified or omitted,

but it affects

the approximations

of interpretation.

difficulty called @n"

Perturbation

Suppose

theory calls

we make and it leads to a

the eigenfunctions for an expansion

of H 0 are

of the form

(4.102)

= X On(t)@ n with the o's determined by an approximation o's have a physical

procedure.

Further,

IOnl 2 is the probability

interpretation:

the system will be found in the nth quantum state of the

measured

unperturbed

system.

Now if a gauge transformation

is carried out and ~ becomes

the o's will be entirely different, their physical @n in (4.102)

interpretation

~n (See Problem

cannot be kept.

4.51.)

equation.

of gauge.

Such an equation

=en¢n"

only if @n satisis

(4.103)

~ = ~ - e¢

that the phase of @n will vary in the

This means

On the other hand,

into the "unperturbed"

accomplished

the perturbing

equation,

potential

by A is

and we do not seem to have

much.

For a complete solve the auxiliary

and general

discussion

problem of calculating

sufficient

approximation

Often this

is not necessary.

we can choose

that

We can keep it only if

same way as that of ~ and the o's in (4.102) will be unaffected now built

e~,

and it would at first appear

also changes by e c~, and this happens

fies a gauge-invariant

changes

the

that if

it would now be necessary the solutions

of

(4.103)

and then using them for the expansion If the external magnetic

to

(4.102).

field is zero

a gauge in which A = 0; in fact we normally

to

do this

148 without

thinking

the effects

about it, putting the entire interaction

of the magnetic

field are small,

can achieve

the same simplification

by choosing

numerically

small and then omitting

it.

system is immersed interaction, -eE.r,

in electromagnetic

to good approximation,

the potential

into e~.

Thus

a gauge in which A is

(Problem 4.61)

radiation

if the

one can put the entire

into e@, which comes out to be

energy of a particle

in an electrostatic

That this special choice of gauge is the only one consistent the interpretation

If

even though not zero, we

of ICn[ 2 as a probability

field. with

was pointed out long ago

by Willis Lamb. ~ Problem

4.52.

mechanics equation

Show that when a dynamical variable

involves potentials of motion

which depend explicitly

i

dt

4.53.

mechanics

on time,

~

: <~[~'~]

+ ii

Show that the corresponding

(4.104)

>

relation

in classical

is dn

~

d'-{ = CQ,H) + @--~

Problem

4.54.

complete

Show that in classical

hamiltonian

which depends

and quantum mechanics,

is simple,

gauge-invariant,

and physically

reasonable

in in both

and quantum mechanics.

4.56.

Show that the operator

~' : eiV~e - i v has the same matrix elements transformed

state

(4.98)

(and expectation

Show that p' = p - eVl.

Problem

4.57.

Just as a canonical

leaves the Poisson brackets transformation

(4.106) values)

that the corresponding

state.

s

the

in (4.101) has a time rate of change

Show that the time rate of change of h defined

4.55.

(4.103)

Problem

H defined

(4.105)

on the gauge.

Problem

classical

its

is d<~>

Problem

~ in quantum

of the form

transformation

unchanged (4.106)

(Poisson's

to new p's and q's theorem),

leaves invariant

W.E.Lamb, Jr., Phys. Rev. 85, 259 (1952). of Phys. 101, 62 (1976).

in the gauge-

~ had in the original

show that a

the commutation

See also K,H. Tang, Ann.

149

relations

of the transformed

if ~ is a function

Problem

4.58.

formation

operators.

of operators

Consider

(Note that this is still valid

as well as coordinates.)

in hamiltonian

mechanics

the canonical

trans-

generated by

F3 (P,Q, t ) = PnQn -el (Q, t ) Find the new m o m e n t u m tion between

transformations

Problem

4.59.

and the new h a m i l t o n i a n

this transformation (4.95)

involving

Show that

A = asin(k.r the magnetic

on the rela-

and the gauge

the field variables.

if the external

- ~t) ,

field is a plane wave with

@ = bsin(k-r

field B is automatically

ality of E requires

and comment

of particle variables

- ~t)

transverse,

(4.107)

while

the transvers-

that k.a

b ---~T~ Show that B is now p e r p e n d i c u l a r

Problem

4.60.

Find the X that transforms A' = a'sin(k.r

where

the new amplitude

Problem

4.81.

to E.

- ~t),

i.e.,

in the preceding

(Note that A" is longitudinal depends

- ~t),

@"= -E(t).r

potential

amounts

to setting

Problem

4.62.

original

Note also it isn't,

For evaluating matrix

in which

The magnitude

of light a thousand

elements,

the wave function differs of A" is therefore

than that of A' by a factor of kr, and the "optical with the w a v e l e n g t h

k is small.

and @"is gauge-invariant.

on time.)

r gives the size of the region from zero.

problem,

generated by X = -A',r and show

that though @"may look like an electrostatic

significantly

that the spatial deriva-

are

A" = - (a'.r)kcos(k-r

since E in general

(4.108)

to k.

field implies

Carry out the gauge transformation

that the new potentials

¢' = 0

a' is p e r p e n d i c u l a r

A weak magnetic

tives of A are small,

this to

smaller

approximation,"

times the radius

of an atom,

this equal to zero.

Show that A" gives

the same magnetic

A. How does it happen that an A" which

field as the

in the situation

150

mentioned above is hundreds

of times smaller than A describes

the same

field? Problem

4.63.

Show that in addition to energy, linear momentum,

angular momentum,

and

the equations for an n-particle system have a

further integral C =

n ~--I miri

n - t i~= =1

and comment on the physical meaning of the constancy of C. Problem

4.64.

Show that

if the forces between particles

in an

n-particle system were inverse-cube~

there would be two more general

integrals of the equations of motion

(Wintner 1947, who says that

Jacobi knew them) D = 2Ht -

n ~I i=

ri'pi

a nd F = Ht 2 -

n ~ i=1

(tri'P i - ½ miri 2)

CHAPTER 5 The principal thing

THE HAMILTON-JACOBI THEORY

object of classical

is at time t; that is, to find a set of

object of quantum mechanics physics,

but you can calculate

Hamiltonian

dynamics

differential

find

equations.

since ~ has a value

everything

mathematical

descriptions

are so wide

partial

familiar

equation

equation

of Lagrange

matical

is known.

necessary

the subtler question Further, to problems

In Chapter

is known,

answers

5.1

The Hamilton-Jacobi

sketched

as in Figure

W is evaluated

difference

and a study of the

above as the solution

in the sense that if a wave function values,

etc.,

the desired answers Classical mechanics

is then easy. theory;

is more specific;

the

We shall find that exactly soluble problems and quantum theory,

in Chapter

but

is much

7.

E~uation

5.1.

qt space of Lagrange, and paths can be We have already

seen in (4.27)

that if the

for a natural path and then compared with

for a slightly different path running between end points

when the

should be easy to find.

have to be made quantum mechanics

We are once more in the function

if the eikonal

will do much to illuminate

These matters will be discussed

the value

assumptions,

about equally hard in classical

that when approximations easier.

differential

(1.31), which was

the same thing in classical

a catch.

1.3),

came out of the

relation.

of expectation

are more detailed.

are usually

equation

function was characterized

is solved,

is, however,

equations

to

(Sec.

will help to explain the mathe-

for the arguments

We have a right to expect equation

theorems

comes a partial

the two theories,

the calculation

the two

6 we shall see how to recon-

under suitable

in quantum mechanics,

it solves

between

It is now our task to show that out

and Hamilton

of their physical

the wave

and

~(q,t) that are the same as the

These arguments

relation between

assumptions

eikonal

for

that is the same as the eikonal

struct quantum mechanics,

The equation

that they seem to belong

differential

dynamics.

from wave optics.

equation

Lagrangian

The differences

but in Ehrenfest's

ordinary

of Newtonian

of the dynamics derived

of ideas,

differential

equations

is in the sense of classical

for every q and every t. equation.

for example,

qn(t). The principal ~(q,t). From

all there is to know.

differential

universes

every-

q(t) and ~(t) or p(t) by means of ordinary In ~(q,t), q is in no sense a function of t,

is a partial different

is to find where

is to find a wave function

this you cannot calculate where

There

dynamics

in a slightly different

time,

slightly

the change

in Y

152 is given by t

6W

=

[pn6qn

-

(4.27)

H6t] t o

If the variations

6q and 6t are zero at the initial point A, then W is

8

&t 0 Figure 5.1

t

Adjacent paths in qt space leading from a common initial point.

defined by this relation point.

Varying

as a function of q and t at the arrival

the q's and t one at a time gives @W

3qn

and substituting

~W

Pn"

~t

the first of these ~W S(~,

This

is the Hamilton-Jacobi

Cartesian occurs

coordinates

of a de Broglie wave;

3W + // = 0

equation. ~

form.

different here

called it the principal

(5.1)

into the second gives

(5.2)

We have seen it before,

for a single particle,

in a more general

meaning was entirely

q,t)

- H(p,q,t)

The equation in Chapter

i.

in (1.31).

Here

in

it

is the same but its There W was the phase

it is the action integral.

(Hamilton

function.)

i This equation was first given by Hamilton, Phil. Trans. Roy. Soc. (1834), II, p. 247, a year before the paper containing what are now called Hamilton's equations. Hamilton's discussion, however, was somewhat more involved than that given here, and it was clarified and generalized by Jacobi in his lectures in the winter of 1842-43 (see Jacobi 1869). For somewhat condensed discussions of the theory's development see Dugas 1955 and Lanczos 1970.

153

Now we must given later,

start integrating.

the energy

If, as in the examples

is constant,

to be

we can do one integration

in (5.1)

immediately:

W(q,t)

S(q)

=

where E is the constant numerical called the c h a r a c t e r i s t i c

Hamilton

-

(5.2)

dependent

and time-independent

and

(5.4)

have solved for S(q). (4.27)

and

to)E

-

(5.3)

value of the energy,

=

and S, which

satisfies

function,

~S H(~-I, q) o~ Equations

(t

(5.4)

E

are the classical SchrDdinger

analogues equations.

How do we find useful

results

of the timeSuppose we from it?

From

(5.3),

6S = 6W + 6[(t - to)E ] = pn6qn

E6t + E6t + (t - to)6E

or

(s.s)

~S = pn6qn + (t - to)6E so that S may conveniently (The t r a n s f o r m a t i o n familiar

in thermodynamics,

already encountered Sec.

be regarded

from W(q,t)

4.1.)

From

as a function of q and E.

to S(q,E)

is of a type especially

called a Legendre

transformation.

in going from L(q,~)

an example

to H(p,q)

We have in

(5.5), we have t - t O = 9S ~--E "

Pn = 9S ~qn

(5.6a,b)

The first of these shows the rather curious way in which on~ deduces the temporal behavior

of a system from the timeless

given by solutions

(5.4).

(1.32).

Example

of

description

The second we have already seen in

How the procedure works can be seen from a simple

I.

Simple Harmonic

Oscillator

2m

so

p

=

~~s -E =

[~m(E - ½ k x 2 ) ] ~

example.

154

Thus

S = (mk)½ I [-~

- x2]~dx

(5.7) = ½ (ink) ½

This has been written sketched

in Fig.

looking at S.

{x(

- x2) ½ + -~- s i n -

[(

)½x]} + c o n s t .

down to show how the solution

6.2b.

Actually

Differentiating

looks;

one is not normally

under the integral

it is

interested

in

sign gives

dx

~E~-~s = t -

t o =

(~) ~ (s

-

~

kx2) ½ X

= (~)½ s i n -1 (2E/k)

giving

t(x,E).

The inverse

X = (~½ As promised, integral

=

k/m

point of the solution was finding

(5.6b)

is familiar.

form in (I.Ii),

with a quantum

~2

Finding x(t) from a knowledge

that gives S.

part of the phase

is

sin~o(t - t o )

the critical

The relation Cartesian

%

We encountered

the

of S was trivial.

it first in

in which s = ~-IS is taken to be the spatial

of a de Broglie wave,

and the momentum

associated

is p = ~k = VS

The meaning

of (5.6a)

also becomes

clear if we think of ~ - I W as the

W is a function W(E,q,t).

entire phase of the wave.

a localized wave packet we superpose waves belonging values

of E as in (1.20)

and Fig.

In order to make to a range of

1.2:

I

ei~-iW(E,q,t)A(E)dE

where A(E) has its maximum at E. condition

for constructive ~W

a~ -

As in the earlier discussion,

interference o

(~

is =

~)

the

155

and with

(5.3)

realized

that ~-iw

trivially. mechanics assumption

this is the same as

What allows

is a phase

(5.6a).

Thus as soon as it is

the relations

is remarkable

(5.6) come out almost

is that the structure

these relations

of Newtonian

to be derived without making the

of a wave.

Problem 5.1.

Figure

around a cylinder.

5.2 shows a pendulum made by wrapping

a string

Find the period.

I

Figure 5.2

5.2

Step-by-Step

Integration

The main computational constants

of the motion

To illustrate Problem 5.1.

of the Hamilton-Jacobi

strategy

in dynamics

When E is constant,

s

=

w

is the use of

in order to simplify calculations.

see here how to use constant momenta coordinates.

Equation

+

E(t

-

and their conjugate

the integral

to)

=

ftI

5

+

expression

We shall

cyclic for S is

~)dt

t

= it (pnqn - H + E)dt to or s

=

IiPndqn ~0

along a natural path on which p and q both depend on t and H has

(s.8)

156

the c o n s t a n t accordingly

v a l u e E.

If n o w ql'

constant,

'''' qk

we can c a r r y

are c y c l i c

and PI'

out the c o r r e s p o n d i n g

"''' Pk

integrations

at once,

S(q)

Call the i n t e g r a l

and w i t h

=

E n=1

(qn

- qno)Pn

f

J n=k+l Pndqn

+

It is

Sk(q).

qo

Sk = S -

k E n=1

(t - t o ) 6 E

-

(qn

(5.5) we have

k ~S k =

~ n=1

pn6qn

+

n=k+l

pn6qn

+

(t - t )6E o

S k is a f u n c t i o n

together with

k

~ n=1

f

Clearly,

(5.9)

qno)Pn

-

pn~qn

k Z n=1

of the e n e r g y

the v a r i a b l e s

qk+l'

...

-

E n=l

(qn

qno)~Pn

Cq n - q n o ) 6 P n

and p

qf.

, "'"

Pk'

all c o n s t a n t s ,

It s a t i s f i e s

3S k (qn - qno )

n = 1,

..

(5.10a)

k

~Pn ~S k ~qn - Pn

~S k ~--~-- =

Example 2.

t

n = k+1 . . . .

-

f

to

(5.i0c)

The K e p l e r P r o b l e m

W i t h ql = 8, q2 = r, 2 Pr

H =

2m

(5.1Oh)

L 2

+ 2-~-~ - ~r

P8 = L = const.

~SI =

sI :

I

T21½dr

[~m(E + ~) - V ~ -

157 Everything

flows

from this

integral.

To find the orbit,

we have

dr

@ - @

. . . .

o

~S t

-

t

[compare w i t h the tables.

and

first

r2]L2

dr =

(5.11b)

m

[2m(E

~E

(2.72) The

r2[2m(E + ~)

1

= o

(5.11a)

L

8L

(2.70)].

does n o t

+

Both

~r) - L2]½r 2J integrals

involve

can be f o u n d

t and is the e q u a t i o n

in all for the

orbit, e - e

w i t h e as in result.

= sin_ I r - a(1 - e 2)

= sin_ I r - L 2 / m y O

er

(2.74b),

The s e c o n d

~(t

er

and this, w h e n

equation

- t

solved

) = sin -I r

- a

[e 2 _ ( r

a~

orbital

is u s e f u l

to r e a d the S o l a r

of course, have

be s o l v e d

rederived

Example

3.

Here

to p r e d i c t

Kepler

Problem

the r e l a t i o n

-

where E T

includes

formulas

in w h i c h E did n o t

the rest

velocity

the p o s i t i o n s

results

System

as in

(2.81).

This

like a c l o c k but

form.

less

It cannot,

At any rate, we

in a few lines.

energy

Relativity and m o m e n t u m

V(r)] 2 = c 2 p 2 + energy mc 2 .

is t a k e n from

(mc2) 2

(4.19)

(5.12)

For c o m p a r i s o n w i t h e a r l i e r

i n c l u d e mc 2, we shall w r i t e E T

o r b i t s E is a g a i n n e g a t i v e . )

p2 = 2m[E(l

/

of the p l a n e t s .

in c l o s e d

in S p e c i a l

between

[E T

(For p l a n e t a r y

angular

to give r(t)

our e a r l i e r

- a} 2 ]½ a

~

w h e r e ~ is the a v e r a g e if one w a n t s

is our e a r l i e r

gives

0

so if one w a n t s

for r,

= E

+ m c 2.

This gives

E E + 2--~-~T) - (1 + m-~2)V( r)]

1 + ~2

V(r) 2

(S.13a)

158 By comparison,

the n o n r e l a t i v i s t i c version is

p2 = 2m[E - V ( r ) ] so that in special r e l a t i v i t y

(5.13b)

it is as if the energy had been increased

to = E(1 + E/2mc 2)

Es.r. and V(r)

(5.14)

had been changed to

(1 + mczE--~r)V ( r )

Vs.r.(r)=

The rest of the w o r k proceeds

2mc21 V ( r ) 2

as in Example

(5.15)

W i t h Y(r)

2.

= -V/r, we

have

p r 2 = 2re[E(1

E r + 2--~Ec2) + Z~] - L2

-

r2X 2 / c 2

y'

E = (1 + m--~-f) Y

(5.16)

The orbit is

dr O

-

=L

@

r2[2m(Es.r.

0

The integral

+ y ' r - 1 ) _ (L 2 - y 2 / c 2 ) r - 2 ] ½

is no more difficult than that in C5.11a), L2

--

and gives

.~2d--2

y(m + E c - 2 ) r =

(5.Z7a) 1 -

es.r.

Sin[(1

-

-L-2Y o - ~2 ) ½ ( O

-

@0 ) ]

where E e

2 = I + s.r.

These are of the same form as

(L 2 - y2c-2) s.r. (m + Ea-2)2¥ 2

(5.17b)

(2.74), w i t h only slight differences

the dependence of orbital and dynamical p a r a m e t e r s

except for the

occurence of

sin[(/

y2 )%(8

L2c 2

- @ )] o

-~ s i n [ ( /

-

y2 2 - - ~ - ~ ) (8 - @o)

W i t h this, r comes b a c k to a previous value after one cycle when 2

(1 - ~ 5 2 - ~ c 2 ) ( e has increased by 2~.

- eo)

That is, the increase

in @ is

in

159

2

AO : 27(I + ~ )

and the orbit precesses

forward through an angle

~y2

27

[email protected]. = L 2 c 2 in each revolution.

In planetary

6es.r.

If the relativistic out of special

Starting

5.2.

equation,

-E

e2

dynamics,

with E = - G M m / 2 a ,

and Newton's

from

the nuclear

correction.

(5.19)

interest because

Problem

5.3.

is 6 times as great.

(5.12), write down a relativistic and exhibit

Show that there are no stable (These results

wave the

is states when

are at most of methodo-

they ignore the effects of spin.)

A ball of unit mass rolls under the action of gravity

(take g = i) inside a cup whose axis is vertical surface

in this way

law, this would be the preces-

The true precession

charge z > 137/2.

logical

this is

= (I -TGM2)ea c z

derive the energy levels of hydrogen,

relativistic

(5.18)

me2

theory of gravity were put together

relativity

sion of planetary perihelia.

Problem

~ 1 -

is of the form z = f [ r ) .

and whose inner

Show that the hamiltonian

of the

system is

H =

Problem

5.4.

Suppose

Hamilton-Jacobi

5.3

Interlude

½ ( pr2 + 1 + fr 2

the surface

on Planetary Motion

Einstein calculated

fr

is a paraboloid, the motion

=

~¢~r

f = ½ Kr 2

Use the

for small values of r.

in General Relativity

corTection

from the general

of planetary perihelia.

roughly analogous

) + f

r2

method to analyze

The first observable precession

po a

to Newtonian

dynamics

that

theory of relativity was the The calculation proceeds

to our earlier treatment

in a way

of light in Sec. 1.6.

There

we set the speed of light equal to c by setting d82 = 0 and then determined

the path by Fermat's principle.

In (4.11) we saw that the

160

variational

principle

for the motion of a free particle was written

in terms of the invariant gravitational considered invariant

ds.

In general

force introduced

to be moving

as such; a particle

to (4.11)

with ds as already given in Chapter

from

expression.

=

(I - 2 l r ) - I d r

The equivalent

because

of the negative

geometry

geodesics

let the radial coordinate

r

(1.54)

condition

in two dimensions

(5.20)

are

is the great

are harder to visualize the d82 between two

negative,

or zero.

(1.54) leads to an intractable

ducing a new radial coordinate

transforms

are usually more convenient

sign in the metric:

points may be positive,

Solution using

are those

of space and time

surface that is the shortest path between two

In space-time

Instead,

expressions

the coordinates

A familiar example

circle on the earth's

(1.54a)

2 - r2de 2

(1.54b)

Curves that satisfy the extremal

points.

neighboring

(S.20)

GM/c 2

(1.54) by assigning

called geodesics.

is

: 0

in some other way, and some assignments than others.

The only

i,

- 2k/r)dt 2 -

k

derivable

in its orbit is

in flat space-time

6 I d8

or any equivalent

there is no

freely in a curved space-time.

law that reduces

d8 z = c 2 ( 1

relativity

into what

in (1.54) be called r'.

r according ,

integral

= r(1

(Prob. 5.5). Intro-

to (5.21)

+

is called the isotropic

form, which will

be easier to handle: d82 h(r)

= (

= h(r)c2dt

I - h/2r ] 2 I + k/2r" "

6 I mc{c

the unnecessary -

[he 2

We also abbreviate

=

(I

+

)

(5.22b)

theory will become as clear constants

of (4.10) and write

k(r 2 + r2@2)]½}dt

in which the integrand now functions I.

(5.22a)

~ k(r)

So that the relation with nonrelativistic as possible we introduce

r2d@ 2)

2 - k(r)(dr2+

as a Lagrangian

the square root by R:

= 0

(5.23)

and will be called

161

I = mc(c

R2

- R),

=

~°2

_

~(~2

+

r2~2)

(5.24)

The m o m e n t a formed from I are ko Pr

•

kc

= -R- m r ,

= L (const.)

mr2~

PO = T

W i t h these we define a H a m i l t o n i a n in the usual way H = ~

R

L2 (pr 2 + ~-f) + mcR - m o 2 = E (const.)

E x p r e s s i n g R in terms of the m o m e n t a gives R2

R2 = ~ o 2

L2

~(Pr2

+~)

from w h i c h we can solve for R and w r i t e H as 2

H

=

[hc2(m2c

L2]]½

Pr 2 + ~

+

kr2~ J

mc 2 =

(5.25)

E

or 2

(~ + mc2)2

=

Pr + -V-

hc2(m~o2

L2

~-~

+

From this, E pr 2 = 2m~ ¼ (i + 2-~) w h i c h is to be compared w i t h

+ m~c~k(¼ - :) - L~ a

(5.16).

(s26)

In the first term of (5.26) we

expand k h -I t o the first power of k and in the second, where the c o e f f i c i e n t is m u c h larger, we keep two powers: -1< h = l + r i.x.~ +

..

1 - 1)

k (~

""

=

2k61

r -

+

3k

~r

+

""

")

and find E

pr 2 = 2m[E(1

This

can be written

in terms

e x p r e s s e d in the style of

Vg.r" The o n l y the

significant

correction

predicted

is

4E

L2

of a general

relativity

+ $--~-E) + (1 + m-~y) ~] -

difference

perihelion

2/°2

(5.27)

potential

(5.15),

= ( / + ~4E -~)V(r)

6 times

r 26Y

from (5.16)

as great

precession

3~ V ( r ) 2 - me---

is

as that therefore

is

in the

of special

(5.27a) last

term,

relativity.

where The

162

6~GM

[email protected].=

(1

-

e2)ac

(S.28)

z

We have already given an estimate of this precession

for a nearly

circular orbit in (2.88). The experimental situation

is best for Mercury,

for which a is

small and e = 0.2, a relatively

large value.

is 43.03 seconds of arc per century.

Here the predicted value

The observed value must be

picked out from among a number of much larger effects. 2 In fact, the total precession observed is about 5600", contributed mostly by the precession planets

(Sec.

residual 41", 3

of the equinoxes 7.6).

discrepancy

were concerned

1.01±0.02

times the theoretical Problem

metric

value computed value.

that in principle

to be further improved.

The present

a small planet

smaller than Mercury's.

from astronomical

data ~

is

Radar observations~, 5 yield allow the Newtonian

"observed"

calculations

value is 1.005±0.02

value.

Set up the same calculation

5.5.

there was a

theory of about

enough about it that they had

with an orbital radius

times the theoretical

more exact distances

and Newtonian

the law of gravity or inventing

(1979) "observed"

of other

paper was published,

between observation

(to be called Vulcan) The best

8.3) and the influence

When Einstein's

and astronomers

considered modifying

(Sec.

using the Schwarzschild

(1.54), and show that it leads to a more difficult

Show that the substitution

(5.21)

integral.

leads once more to the results

of

this section. Problem

Attempting

5.6.

to make a field theory of gravity by rough

analogy with the electrostatic

field, show that in this theory the

energy density of the gravitational

field is negative.

that E < 0 in (5.27) and that all energy produces we can understand Interpreting

qualitatively

the correction

the corrections

Problem

5.7.

Evaluate

field,

to E and y in (5.27).

in y as a correction

of the sun, M@, how large is the correction?

Remembering

a gravitational

to the effective mass

(MO = 1.99 × 1033 gm.)

the planetary precession

by a perturbation

calculation. 2 G.M.Clemence,

Revs. Mod. Phys. 19, 361 (1947).

3 The generally accepted value was that of S. Newcomb, Wash. Astron. Papers 6, 108 (1898), who gave 41.24" ±2.09". The effect had first been established as 36" by U.J.J. Leverrier in 1859. I.I. Shapiro

in Hegyi 1973.

s I.I. Shapiro, G.H. Pettengill, M.E. Ash, R.P. Ingalls, and R.B. Dyce, Phys. Rev. Lett. 28, 1594 (1972).

D.B. Campbell,

163

The precession

Solution:

the expression

comes only from the last term in (5.27),

for the characteristic

S =

[2m(E

+ ~)

- ~

=

I [2m(E

+ ~)

-

function

+ r~]½dr

~]½dr

~ -

+ ~

2

6X2

r212m(E

EI

~2 ~)Y" - ~L2]½ +

This is to be integrated between the two turning points, the orbit.

Although

and the integrand integral

the square root vanishes

of the second integral

nonetheless

converges.

=

-~[

The integral

my

+

z, -

can be done by complex

Integration

-

~S

~

~-E-E] +

Problem

5.8.

precession

"".

2~ (I +

=

E ~-g-T)

is 6e

from which follows

over a complete

angle is @ =

Thus the precession

all around

at the turning points

(_2ms)½

and the corresponding

=

~c

(s.29)

~-£

the usual result.

Show that if the perturbing

energy is C/r 3, the

is 6@ = 6 ~ C m 2 y L~

(We shall use this result later, Fermat's

...

is infinite there, the

methods (Born 1927) or taken from tables. cycle of r gives s

so

is effectively

in Sec.

(s.3o) 8.5).

Principle

In Sec. 1.6 Fermat's deflection

principle

of least time was used to find the

of light by the sun's gravity.

this principle

governs

We can now easily show that

the orbits of particles with vanishing

rest

mass. Taking the lagrangian

of the particle L = mc(c

- R)

to be the integrand

in (5.23), (5.31)

164

with R as in (5.24), we find by the usual procedure

a conserved

E = mc2(hcR -I - I) Solve this for R and use it to rewrite mo

L along the natural

(5.32)

(5.31):

2

E + mc 2[E + (I - h)mc ~]

path.

Now let m approach

zero keeping E constant:

L = mo z ÷ 0 which

is constant

(Figure

energy

(5,33)

along the natural path.

Compare

a natural path

2.15) with another path which runs between the same two points

but requires

a time which differs by St from that of the natural path.

By (4.27), p.

123 , with

~qn = O, ~W = -E6t

But with

mc ~ << E.

(5.34)

(5.33), we know that ~W is of the order of mc2~t, Thus

6t must be zero:

the varied path,

6t, takes the same time as the natural stationary with respect

to deviations

one.

with

to first order

in

That is, the time is

from the natural path,

and this

is Fermat's principle. 5.4

Action as the Generator If a system's

principle Sec.

for S.

of a Contact Transformation

energy is conserved, Starting with

there is a variational

(5.8), we vary S as we varied W in

S.l: q

~S

= ~ (~Pndqn

+ Pn6dqn )

J

qo

= lq(~Pndq n - ~qndPn ) + [pn~qn ~ q qo qo

q

=

l

q ~H

(~n

~H

Cs.3s)

~Pn + --~qn ~qn) dt + [pn~qn]

qo

qo

6~

165

If we consider only variations unchanged,

and if 6q vanishes

then ~S = 0.

in which the numerical

value of H is

as before at the limits of integration,

Because the time at the endpoints

special case of the Maupertuis

principle

is not varied,

(2.102)

this

is of little practical

use, but we can see from it that S is part of the theory of contact transformations. S can be varied

(for constant

energy)

by varying

or the final q's; it is a function of q and qo" from (5.35),

Comparison with an El(q, Q).

~S ~qon = - P o n "

(4.32)

transformation

from the initial

set Po' qo to the final set p,q,

we can understand

2f constants

The equation

f first-order

f constants. answer

generates

the We

the infinitesimal S

form of this transformation. an important point.

of integration

for their complete

for S, H (~

contains

of

of motion for a system with f degrees of freedom are of

2f, and require

solution.

S generates

of a system as the time goes from t to t + dr.

the integrated

The equations

the definition

from an old set of

Correspondingly,

seen that the hamiltonian

With this interpretation order

derivatives,

(5.36a,b,c)

satisfies

the transformation

p, q to a new set P, Q.

have previously

~S ~ = 0 ~t

shows that S(q,qo)

F 1 generates

transformation

generates

Its partial

are

~S ~qn = Pn"

coordinates

either the initial

,q) = E

(5.4)

derivatives and a complete

solution contains

How are we to find the other f constants?

is suggested by the case we have considered:

only

The general

suppose that the

f constants of the complete solution are q o l . . . q o f. Then C4.32) states that the path of the system is defined by [5.36b,0], and this brings in the additional a solution. Problem

5.9.

calculated Problem

Integrate

the last few paragraphs 5.11.

gravitational

are needed to specify

between S as

I, p. 153, and the F 1 in Problem 4.22.

a free particle moving

Problem

Pon that

Analyze the source of the resemblance

in Example

5.10.

f constants,

the Hamilton-Jacobi

in 2 dimensions,

equation for S describing

and show how the program of

is carried out in this case.

Do the same for the motion of a projectile field.

in a uniform

166

Problem

5.12.

Give the formal modification

to the theory developed

above that makes use of S k rather than S when there are k constants of the motion. Problem

5.13.

Apply

the results

motion of an isotropic potential

Jacobi's

problem to the

oscillator with

= ½ k(Xl2 + x22 )

leave the subject where Hamilton

But in solving a partial

other ways

(5.37)

Generalization

The last few paragraphs in 1834.

harmonic

energy V(Xl,X2)

5.5

of the previous

two-dimensional

to introduce

of the coordinates. us to use constants

constants

differential of integration

We need a more general of integration

by Jacobi in his lectures

equation

left it

there are

than as initial values

approach

as they occur.

that will

enable

This was provided

in the winter of 1842-1843

in K~nigsberg

(now Kaliningrad). The point is to generate possible. 6

as many constants

Suppose we can find a contact

forms p, q into new coordinates transforms

that trans-

and momenta and at the same time

H into a number E independent

all the new momenta will be constants depend on time in a specially

of the motion as

transformation

of the new coordinates.

and the new coordinates

simple way.

The trick,

Then

will

of course,

is

to find the transformation w h i c h does this. Following

the pattern of F 2 in (4.34), we wish to find a transforma-

tion function which we shall call p's into new constant properties

to be determined.

to H but depending transformation

Pn =

that will

H is to be transformed

only on the constant

equations

and the equations

-S(q,a)

transform

the old

~'s and the old q's into new coordinates

~ with

to a new E, equal

~'s and not on the ~'s.

The

are

~s(q,a) ~qn

"

~n =

~

~a

of motion for the new canonical

an" = - 9E(a)~¢n = O,

Sn : 9E__E_~_ =~n

~n(e)

(5.38a,b) n variables

are

(const.)

(5.39)

6 We restrict ourselves to situations in w h i c h ~H/~t = O, since they are of principal interest to physicists. For an excellent discussion of the general case as well as the one presented here, see Goldstein 1950, Ch. 9.

167 Both equations

of (5.39)

can be integrated

over again that the a's are constant ~n

=

~n t

at once:

the first states

and the second gives +

(5.40)

~n

The constants

~ and B are known as the first and second integrals

the equations

of motion respectively.

A Special

Choice

of

a's

A simple way in which the above conditions choose one of the constants

can be fulfilled

(5.39)

is to

~, say ~i' to be the energy, E(oO = c~1

Then

of

(5.41)

gives C~l =

1

,

~°2 = ~3 = "'" = 0

and with B ° = -to, ¢i = t - to,

¢n = 6n"

so that all the coordinates are constants. mined?

n = 2, S . . . .

except the first one,

Now how is the transformation

We start from H ( p , q )

and use

f

(5.42)

like all the momenta,

function S to be deter-

(5.38) and

(5.41) to get

aS H(~-~I" q) = ~i This

is again the time-independent

in a more general solution

context,

are not merely

constants

ered two ways quantities

in which constants

of the coordinates

they occur.

in the but any

So far, we have encount-

can occur in S: In Sec,

equation for S, but

of integration

5.9

as conserved we shall encounter

a

as the constants w h i c h arise in the separation of variables

of a partial

differential

are f + i in number: equation.

however

and as initial values.

third way:

Hamilton-Jacobi

since the constants

the initial values

of integration

(5.43)

~i

equation.

However

plus f others

they arise,

the constants

that come from integrating

But since S occurs only differentiated

in the equation,

the one

of the constants

is a trivial additive one that carries no information

about dynamics.

If we agree to ignore this one, a complete

depends

on f constants

~i'

Once S has been found, we use (5.38) aS(q,~)

a~ 1

as (q, ~)

= t - t

o"

solution

"'' ~f"

a~ n

=

6n

and (5.42) n = 2,

to see that 3 ....

f

(5.44a, b)

168

The

first

is already

familiar

... f do not involve they are solved

from

(5.6).

time and describe

The equations

for n = 2,

the shape of the orbits when

to give

q : qCe,B) Time is introduced relation

between

for q(e,8,t-to)

equations possible belong

Example

only By

q's, e's,

(5.44a),

(s.4s)

which

and t - t o .

is in general

Solving

may be difficult,

if the e's are the f independent

to a general

4:

Charged

If the field (relativistic)

of the f equations

Particle

in a Uniform

is in the x direction,

set of

but it is in principle

constants

solution

hamiltonian

a single

the whole

of integration

that

(5.44).

Electric

Field is -eEx and the

the potential

is

= (c2p 2 + m % 4 ) ½ -eEx = e I Since py and Pz are cyclic

they are constants

e3' so that

e 2 and

px 2 = (e I + eEx) 2c -2 _ e22 - u32 - m2c 2 and the general

S(q,e)

formula

for S satisfying

(5.38a)

is

: f [(el + eEx) Zc-2 - e22 - e3Z - ra2c2]½dx + e2Y + e3z

To integrate

this let

CL1 + eEx = CV Then

SCq, c~)

Differentiating c

t - t o =7~;

1

= -~c J (V2 "_ (~2 2 with respect

-

_

ra2c2)½dv + e2Y + e3z

by putting

m~c2)½

-

(v°Z

in initial

e 1 = c C P z o 2 + c~22 + e 3 2

-

~2

2

~32

values:

+ r/t2c2) ½ _ eEz 0

or

V02 = c-2(Ul

(5.46)

to e I gives

[Cv2 - e22 - e32

This can be simplified

e3 2

+ eExo)2

= pz02

+ ~22 + ~32 + m2c z

_ m2c2)%]

169 and using

this relation

twice gives

t - t o = c e1E {[ (~i + eEx) 2 - (~i + e E X o ) 2

1

{[2~leE( x

= tee

Untangled,

- Xo)

+ e2E2 (x 2

+ c 2 P¢o 2]% _ C P x o }

- Xo2) +

c2P¢02] ½

-CPxo}

this is + e E ( x 2 - x o 2)

2~l (X - XO)

from which x(t)

=

can be further

c2[2pxo(

t

- to)

disengaged.

+ eE(t

-

to)2 ]

(5.47)

To see what the expression

means, let eE = 0 and write ~i = mrC2' Pxo = m r V x o with m r the relativistic mass. Then (5.47) is just x - x o = Vxo(t

- to)

Other special

cases

which is not surprising. be similarly

and approximations

derived.

To continue

with the program, ~S

~"a2

62"

From these we readily

find

so that the projection

return

~S

~3

to (5.44):

63

Y - 62

~2

z-

~3

63

of the trajectory

(constants)

on the yz plane

line through the point (82,83) with slope ~2/e3. (Problem 5.15) gives y and z as functions of x. Problem

Discuss

5.14.

(5.47) when

Pxo = 0.

relativistic

problem

nonrelativistic (It will b e g o o d

In the plane z = 0, find y(x)

Problem

5.16.

If the constants

7

P.M.

invariant

limits

of

to solve the non-

a n generate

[see Eq.

[4,55)),

in the above example. transformations

Am. J. of Phys.

57, 1161

which leave

what transformations

6 n generate? 7

Campbell,

further work

from the beginning.)

5.15.

the hamiltonian

is a straight

A little

and r e l a t i v i s t i c practice

Problem

constants

can

(1968),

do the

170

Solution:

Write

pn[q,a )

(5.38a,b)

and (5.40) as

DS(q,a)Dqn ,

=

where the time dependence

Sn(q,a )

that

(symmetries

DS(q~a)Dan

~n(a)t

-

of q is such as to make 6n constant.

(4.57) and (4.55) the constant E invariant

=

a's generate

transformations

of H), but ~ contains

By

which leave

the time explicitly,

so

(4.57) becomes

d8 n =

(Sn, H)

D8 ~--~

+

dt

and constancy of 8 does not imply that ~ is a symmetry of H, as generating

an infinitesimal

transformation

Take B

to new coordinates

n

and

momenta with

6qm

e =

The second relation

6pm

DS n (q,a) ~Pm

0

6pm = -c

DSn (q,a) ~qm

is

D

-e =

DE Da

Dqm

D - -~ Da n

DS

= -e

n Dqm

9Pm(q'a) Da n

Whenever we change a n infinitesimally, ~Pm = (DPm/Dan)~an" so that here, ~a = -e. The 8's change the ~'s by varying the momenta while keeping n

the coordinates

fixed,

first integrals

generate

generate

changes

and so they will in general symmetries

change H also.

Thus,

of H, while second integrals

in the numerical values of the first integrals.

Integral Surfaces Let us look at the integration procedure. that f = 3.

There will be three constants,

additive ones that arise from the integration.

as ( q , a ) Da 2

each define an algebraic whose coordinates

_- ~ 2 '

--

Dc~3

The two equations

(5.48)

B3

are ql' q2' q3 they define two surfaces.

intersect

Finally,

the last equation,

point.

for simplicity

relation between ql' q2' and q3; in the space

surfaces moves

Suppose

a I plus two other non-

in a line which is the system's (5.44a),

as time passes and intersects This gives the configuration

defines

These

orbit Fig.

5.3.

a third surface which

the orbital

line in a moving

of the system at time t.

171

Figure 5.3 Problem 5.17.

The orbit is the intersection of two integral surfaces. Construct the three surfaces mentioned above for a

particle moving freely Problem 5.18.

in space.

Construct the three surfaces for the path of a projectile

in a uniform gravitational

5.6

field.

Orbits and Integrals If one wants to know what a system will do after having been set

in motion in a certain way, there is nothing to do except to solve the equations.

But there are other kinds of questions one can ask that do

not require everything to be solved:

is the orbit closed or does it

fill a certain region, and in the latter case what region does it fill? What is the character of orbits in phase space?

Are there any regions

of phase space or configuration space into which a system is forbidden to move?

Questions of this kind that require generalizations

about

classes of solutions are often of more interest than the solutions themselves,

and they are sometimes relatively easy to ask and answer

in terms of the integral surfaces. In the following paragraphs we shall see the kind of arguments that can be based on the construction of integral surfaces without making any attempt to solve Hamilton-Jacobi considerations

to follow are geometrical

equations.

Because the

in nature and we are going to

illustrate them with pictures, we are obliged to treat systems with only a few degrees of freedom.

The methods,

however,

are general.

Motion Under a Central Force Suppose we wish to study the general properties an attractive central potential V(r).

of motion under

The particle's position and

motion are given by a point in the phase space whose coordinates are, for example, r, 8, Pr' and p@.

Since this is too many for convenience,

172

we agree to ignore the angle e

by considering

that three-dimensional

slice of the four-dimensional

space which corresponds

addition,

P8 is a constant.

for central

forces,

to 8 = 0.

In

To see what this

allows us to say about the orbit, write

(s.49)

E = % (pr 2 + p92/r 2) + V(r) and PO = r [ 2 E In the space whose coordinates surface; defines

are r, Pr' and p@ this defines

a typical one is shown in Fig. another

surfaces

such surface,

intersect,

Fig.

(s.so)

- V(r) - prZ] ~;

a plane.

5.4b, defines

5.4a.

a

The c o n d i t i o n p @ = const.

The line along which the the values of r and Pr

Pr

r Figure 5.4

(a) Integral surface corresponding to (5.50). (b) Intersection of the integral surface with the plane P8 = const. (Only the half of the figure with Pe > 0 is shown.)

compatible with the given values of E and Pg" If we now represent

the system in the space r, Pr with P8 fixed

and 8 = 0, we arrive at the kind of orbital Figure

5.5, in which each successive

Figure 5.5

representation

revolution

shown in

of the particle brings

In this orbit in rOp space the locus of points at which the path pierces the plane 0 =r 0 is a closed curve.

173

it through the plane the contour a position

8 = 0 at a certain point,

determined

by the construction

to distinguish

between orbits

and these points

of Fig.

5.4.

lie on

We are now in

that are closed and those

that are not. Two-Dimensional

Isotropic

The h a m i l t o n i a n (neglecting

Harmonic

Oscillator

of this system is w r i t t e n

unimportant

constants)

H = %

[ p ~ + po2/r

w i t h P8 equal to a constant, system is shown in Fig.

5.6a.

L.

in polar coordinates

as 2]

E

(S.Sl)

contour

in r, Pr for this

+ ½ r2 :

A typical

But there are other integrals

of this

r

Figure 5.6

system

(a) (b)

Contour in r, Pr determined by (5.51) for fixed values of E and PS" Intersection of the previous contour with that defined by (5.53).

(Sec. 4.6).

One of them is B = ½ Cpx 2 - p y 2

which

in polar coordinates

+ m2 _ y ~ )

is 2

B : ½ (pr 2 + r 2 - Pr82)cos 28 - PrP8 2-~

sin28

(s.sz)

174

Let us assume that B ~ 0 and look at the plane defined by @ = 0. B

0, take @ = ~/2.)

(5.53)

pr 2 + r 2 - L 2 / r 2 = 2B

at the same time as (5.51). The allowed values points

correspond

Fig.

directions

these intersect;

the two

around the orbit.

There is

and ~e now see graphically how

Iprl ,

of the second integral

forces

the orbit to be closed.

What role does the third integral

5.17.

curves.

for every value of @; thus for each @ there is

only one possible r and one

Problem

5.6b shows a pair of typical

of r and Pr occur where to opposite

one of these diagrams the existence

(If

Then the path in (r,Pr) must satisfy

(4.82) play in fixing

the orbit just discussed? Poincar@

Tubes

If an orbit is not closed but angular momentum we can still draw conclusions path pierces

from the r, Pr plot,

the r, Pr plane with

lying on the closed contour which, the given constant values fixed.

What will

circumstances

@ = 0 it pierces as in Fig.

of E and L.

the new contour

can any two contours

is still conserved, for each time the it at a point

5.4, is determined by

Suppose we change E, leaving L

look like?

Only u n d e r very special

intersect,

since if they did there

would be two orbits which at a certain moment had the same values of r, r, L, and @.

With r and L the same,

two orbits would have to coincide two contours some moment

can cross

can give rise to two different

point.

corresponding

If we continue

enables Fig.

the system's

The contour of Fig. the space r, Pr' which spirals

cannot intersect.

Fig.

5.7a

and no smaller E is possible.

construction

given by Poincar~ which to be visualized:

the orbit by including

the angle

return to

@ (Fig.

5.7b),

5.7a is now seen as a cross section of a tube in

@, and the particle's

orbit in this space is a path

around the tube but never leaves

for the exceptional

This that do

to decrease E, the contour will narrow to a

dynamical behavior

5.5 and complete

Contours

at

to three values of E for a central

The orbit is now a circle,

There is a geometrical

subsequent motions.

balanced on its point.

not contain such points of instability shows contours

The only way in which

is if exactly the same initial conditions

is the situation of a pencil

potential.

@ would be the same and the

throughout.

points

never touch each other~

at which two orbits

in this diagram,

it.

Further,

intersect,

except

the tubes

in which p~ is fixed,

the tubes

175

c o r r e s p o n d i n g to smaller E lie entirely inside those c o r r e s p o n d i n g to larger E.

Figure 5.7

(a) Contours in r, Pr corresponding to different values of E for an attractive central potential. (b) Poincar~ tubes whose cross sections are the contours shown in (a).

An Angle-Dependent Potential The next case to be d i s c u s s e d is one in which the orbit is not re-entrant.

There is no integral c o r r e s p o n d i n g to B above and because

@ is not a cyclic v a r i a b l e The h a m i l t o n i a n

the angular m o m e n t u m is no longer conserved.

is I

H

=

-~ (Pr

2

+

P8 2

I r2 1 ) + ~ + 7

r3c°s3e

(5.54)

r~ The form is chosen here because it has r e c e i v e d considerable d i s c u s s i o n since it was first studied n u m e r i c a l l y by H 6 n o n and Heiles 8 a number of years

ago.

because (Sec.

The H a m i l t o n - J a c o b i

e q u a t i o n cannot be solved exactly

it is impossible to carry out a separation of the variables

5.9),

and so we resort to the computer.

The b e h a v i o r of this simple system shows c o n s i d e r a b l e variety, d e p e n d i n g on the value of the energy,

Since the potential

is not

symmetric b e t w e e n @ : 0 and e = ~, we set x : rsin@, y = rcos@ plot y and

py

and

instead of r and Pr' getting a contour c o r r e s p o n d i n g to

O = z (negative y) at the same as that c o r r e s p o n d i n g to 8 = 0 [positive y].

Figure

5.8a shows ii0 successive passages through the plane.

again, the points lie on contours.

Here

Clearly there is an integral of the

m o t i o n w h i c h is r e s p o n s i b l e for the contour in the same way as L was in the situations

in w h i c h it is conserved.

In this case the exact

analytic form of the c o n s e r v e d q u a n t i t y is u n k n o w n and one m u s t M . H ~ n o n and C.Heiles, Astron. J. 69, 73 (1964); see also M.H~non, Quart. J. Appl. Math. 27, 291 (1969); E . M . M c M i l l a n in Brittin and 0dabasi 1971; and J.Ford, A d v a n c e s in Chem. Phys. 24, 187 (1973).

178 laboriously construct it by approximation. ~ For comparison, Fig. 8b shows the corresponding motion when the angular dependence in [5.64)

+ + + + ÷

+ +

÷÷ ÷

+ +

+

+ + +

÷

~xxXX

+

+

<

t

+

+

X

I

I

XXXX

X

X XXXX I

X XXXX

X )¢XXX

X X X X ~x

t

t

X XxxxX

~

I

I

X X

+

4'

+ +

t

÷,

+ ÷ ÷ ÷

+ +

+ +

Figure 5.8a

+÷**

Computed points in an r, pm plot using the potential (5.54).

+++÷+÷÷+%

/

+

XXXx x

%

X

÷

X

~,,:

;~.

÷

+*. +÷~*+

xxxxxxx~x

g

~ +,

Figure 5.8b

9

The same omitting the factor of cos38 in the potential, from the plane; +: entering plane.

F.G.Gustavson,

Astron. J. 71, 670 ~966].

X

x:

emerging

177

1

is omitted and the potential

1

is ~ r 2 + ~ r s, and the points lie on a

contour determined by the angular momentum But the system has an unexpected

integral.

feature.

Fig.

5.9 represents

the same system started on the same point in the y py plane with a

+

X + +

+

+÷

+ X +

+

4.

X +

Pu

X

+

t" X

+

X

++X

4.

K

+

X

K

4.

X

+

4. 4+ +

X

X

)k X

xx

)K

X

x

X

I

I

I

X

I

4"

+

xXx

~ X

4.

XXX

X

X

+

X

4. +

4.

4. 4"

4. 4.

X

X

X

X X

4.

X÷ X K

X K

+

+

X 4'

4"

X X

Figure 5.9

energy.

What has happened

surfaces

are complex

This produces

R

+

The same plot as in Fig. 5.8= but at a slightly higher energy.

slightly greater here.

4. +

4. + + 4 .

,~

There is no sign of the effect of an integral is apparently

a strong instability

in the observed motion, probably

amplified by the effect of round-off 5.7

Coordinate

errors

in the computer.

Systems

The power of the methods evident

that parts of the integral

in form, with many folds and self-intersections.

in simple examples,

of solution we have developed

where almost every constant

fairly obvious way from a cyclic coordinate. been the most familiar ones,

straight

is not

arises

These coordinates

lines and angles.

But a

in a have

178

number of calculations where the meaning

must be carried out in less ordinary

of cyclicity

is not intuitively

section we shall see why certain calculations special

coordinate

systems

types of coordinates

clear.

require

and then go on to discuss

in three-dimensional

coordinates,

In this

the use of the different

space in which solutions

are feasible.

The Anisotropic Oscillator The two-dimensional Cartesian

coordinates

anisotropic

oscillator

by the hamiltonian

i___

s = 2m ~ x 2 + py2) + ~1 (klX2 + and the Hamilton-Jacobi

equation

~S 2 (~-~)

~[

+

3S 2] (~-j)

This can be solved by separation processes factors

each depending

a sum, as here. Assuming

k2y2)

(5.55)

is +

1 (klZ2 + k2Y2 ) = a~

of variables.

that occur by this name:

equation or any other

is defined in

separation

on a single variable

(5.56)

There are two into a product

of

as with Schr~dinger's

that starts with a laplacian, and separation into

(We shall see later how the two processes

are related.)

that

s(=,y) + st(x) + s2@) we find

[

1 (dS1) 2 + -~ klX 2] + [ ~m (d s 2)2 dz dy

and the only way this can be satisfied a constant.

This gives

IDS121 --2m ( ) dx

+ -2 klX2 = c~2"

Since

IDS221 ) dy

--2m (

1 + "~ k2Y 2] = o~I

is for each bracketed

term to be

2 + -~ k2y

= aI - a2

(5.57)

(dSl/dX) 2 and (dS2/dY)2 cannot become negative, the values of x

and y are bounded:

-Ax<X
-Ay
(5. SScz)

where

A x = (2(~2/ki)½,

A~[2(~ 1 - a2)/k2 ]½

(5.58b)

179

H o w one knows motion

that

oscillates

these

limits

between

are a c t u a l l y

them is d i s c u s s e d

reached, in Sec.

and that the

2.2 u n d e r A Note

on A r c - S i n e s . The

solutions

SCx, y) = where

of

[2m(a 2

the i n t e g r a l s

(5.57) _ -~ 1

can be w r i t t e n

klX 2) ]½dx +

I [2m((~ 1 - a 2 - ~

m a y be c o n s i d e r e d

a g r e e d not to d i s t i n g u i s h

additive

down from

as i n d e f i n i t e

constants.

(5.7):

k2y2)]½dy

b e c a u s e we have

To find the orbits we

have

½klX2)½-

(0. 2 -

8c~ 2

(C~l - a 2

_

2)

=

S2

½ k2Y

or

/ _ sin_1 x ~i Ax What

curves

introduce

I sin_1 _ y _ = B2 ~2 Ay

this s t r a n g e

formula

the time v a r i a b l e

~2 =

represents

as a p a r a m e t e r

~SCx,y) ~al

becomes by

= 2_~ sin_ I ~K_ =

~2

Ay

t

k/m

(5.59)

clear

if we

(5.44a), -

t

o

so that sin-1AY

= ~2 (t - to)

y = Ay sin~2(t

or

- to)

(5.60a ,b)

Y Putting

the first of these

into

(5.59)

x = AxSin[ml(t Equations Fig.5.10

(5.60a,c)

are the r e c i p e

is an example.

The

gives (s.60o)

- t o ) + 82]

for d r a w i n g

curves w i l l

Lissajous

ordinarily

figures;

fill up

Ch) Figure 5.10

Lissajous figures defined by (5.69) for different frequency ratios. (a) If ~i and ~2 are incommensurable the curve finally fills the allowed region. (b) Here ~I = ~2 and the allowed region is not filled.

180 the entire allowed area defined by (5.58). is clear why cartesian variables, expressed

coordinates

If these are the orbits,

were right for separating

since in no other system are the boundaries in terms of one variable (Fig.

the

of this region

at a time.

But suppose the two frequencies now reentrant

it

happen to be equal.

The orbit is

5.10 ) and it no longer fills the available

In this case the problem can be separated

in polar coordinates

space. also.

(Problem 4.43 does it for quantum mechanics.) In Sec.

Problem 5.32.

generator

5.6 we showed that S can be regarded as the

of the contact transformation

initial state to its present state. a 2 of the foregoing

discussion

so that their Lagrangian

L Separate

=

=

are coupled together

+

~2)

_

~

~Cx 2

-

y~)

_

~2xu

new coordinates

u),

figures

+

y =

~-%Cv

in u,v that express

+

u)

the solution of this

Sketch them in x,y and note how the boundaries

figures are expressed 5,8

harmonic oscillators

by introducing

~-%(v

Sketch the Lissajous equation.

that define the

form of the S that generates

is

(~2

~

the variables x

Curvilinear

of the

in each system.

Coordinates

The simple examples curvilinear

~I and

and verify that it does so.

Two identical

Problem 5.33.

the constants

in terms of the numbers

initial state, write down the explicit this transformation

that takes a system from its

Expressing

coordinates

of the last section suggest how the use of should be regarded:

if all the Lissajous

figures generated by a certain orbit can be bounded by coordinate lines

(or surfaces)

be separated. following

in a certain set of coordinates,

If not, the calculation

example in plane parabolic

introduction

the variables

may be very difficult.

coordinates

will serve as an

to this approach and will show how one can identify

classes of potential

functions

for which curvilinear

coordinates

useful. Example

5.

Introduce variables

can

The

a new way of covering

~ and n defined by

the xy plane by means of the

are

181

x = ( ~ n ] ½, If we eliminate

y = @ (~ -

~,

~ > 0

(5,61)

first ~ and then n, we find X2

Y which,

n)

-

~2

X2

2n

__ ,.~2

2~

Y :

(5.62)

for c o n s t a n t ~ and ~, are two sets of confocal parabolas all of

shose intersections

are at right angles,

%

Fig.

5.11.

• X

o Figure 5.11 Parabolic coordinates. We can also easily show that

~=r

+y,

(5.63)

~=r-y

A routine c a l c u l a t i o n gives the l a g r a n g i a n as

L :

I

m(~ + n)

~62

(=~- +

"~)

-

v(~,n)

The m o m e n t a are

p~ :

Tm(~

+ n)

,

Pn : Y m ( ~

+ n)

(5.64)

and 2 ~p, 2 + npq2 H : ~ ~ + n + v(~,n)

(s.6s)

182

The Hamilton-Jacobi

equation

2

1

in these variables

~S

~S 2

m ~ + ~ [ ~ C ~ ]~ + n ( ~ ] Suppose

now that

V(~,n)

is

]+ v(~,n) = %

is of the form

vC~,n)

fl (~] + f2 (q)

(S.66]

=

+ n Then

[~

+ n ( ~ ) 2] + fi({)

3~

and S separates

additively

+ f2(n)

into SI($)

- ~i(~ + n) :

+ S2(n)

0

where

@S

2

~(~-T-)2 + fl (~) - % ~ 2 n(~--~-] aS 2 + f2Cn] Note that the constant

~2 has entered

= ~2

- ~i n = -~2

not via a cyclic

conservation

of energy but via the procedure

in a partial

differential

equation.

(5.67)

coordinate or the

for separating

Such constants

variables

are called constants

of separation. Since

(~SI/~)2

and

al$ + a 2 - f i ( $ )

C~$2/~)2 ,> O,

are not negative,

°~lq - ~2 - f2 (q)

depending

on the f's and the values

establish

limits

vanishes

for ~ and n.

is a turning

oscillates

between

of integration exactly

determine

regions

of the ~n plane.

depending

If it vanishes

the two turning

9 0

expressions

twice,

points.

have

C5.68)

even though they may not

they at least restrict

The equations

on the left

the particle

The role of the constants

in these expressions:

an orbit,

must

of ~i and ~2' these may or may not

Where one of the

point.

is clear

we

(5.67)

it to certain

are easy or difficult

on the forms of fl and f2' but let us see what has already

been accomplished.

In solving

separation

~2 which

constant

the equations

we have

is a new constant

introduced

of the motion,

a

given by

either of two forms 2

~2 = ~ CP~

2

+ f l (~)

- ~i ~ (5.69)

= - ~ nPq z -

f2(n)

+ ~1 n

183

A special case is Kepler motion,

in which ~+

n

This is of the form (5.66] with fl : f2 = - Y Let us symmetrize the expressions

(5.70)

(5.69) by writing ~2 as half the

sum 1

2

(5.65]

this

~2 : ~ [~p~ With

~i

equal

to

H in

~2 = ~ + n

np~ 2) - % ~ z ( ~ reduces

-

- n)

to

Pn

-

my(~ -

n)]

(5.71)

To see what this has to do with anything else we know, let us calculate the component of the vector integral A in (2.91] that lies along the axis of the parabolas, A Y = ~1 (mpxpy _ ypx2)

+ 2Lit

[5.72)

On substituting the expressions that transform this into parabolic coordinates we find

[5.73)

Ay = -~2/m

(There is no need to ask about Ax, since from (2.94) A has only one independent component.] It should be noted that the constant which was derived in Chapter 2 by an ingenious de~ice appears here in the course of a routine application of the separation of variables in parabolic coordinates. Of course, the right set of coordinates had to be chosen, but there is not much ingenuity in this, since as we shall see there are only eleven kinds of coordinates in which the separation is possible, and most of these correspond to potentials so esoteric in form that they are unlikely to find physical application.

Further, we have succeeded

in generalizing our earlier result, since the functions fl and f2' instead of being given by (5.70), are now arbitrary. Finally, we may if we wish perform an actual calculation.

The characteristic function

is [

- @2

fl($)

f

~2

f2"(N)

184

through which the constants

el and u2 will make their appearance

in

the solution. Find fl and f2 corresponding

Problem 5.34.

electric

field,

and evaluate

the integral

to a hydrogen atom in an

~2 in terms of Cartesian

coordinates. Problem 5.35.

Carry out the change of variables

Problem 5.36.

Show that the sets of coordinate

all intersect

each other at right angles.

for the separation Problem 5.3?.

particle

Find the physical

lines given by (5.62)

Why is this fact important

of variables?

Set up the equations

attracted

leading to (5.65).

of motion in 3 dimensions

for a

to a fixed center by an aribtrary potential significance

show that when the coordinates

of the two separation

V(r).

constants,

and

are suitably oriented with respect

to

the initial motion our earlier results are reproduced. Problem 5.38.

parabolic

Solve the plane Kepler problem in two dimensions

in

coordinates.

Problem 5.39.

With the major axis of a keplerian

axis, show that the formula for the ellipse 1 + e

÷

n

1 - e

=

ellipse along the y

in parabolic

coordinates

is

(5.74)

2a

Figure 5.12 A Keplerian ellipse in parabolic coordinates. The point representing the particle oscillates back and forth along the llne. Problem 5.40.

Show from

(5.68) that ~ + ~ ~ 4a in the Kepler problem,

and show that this is compatible Problem 5.41.

Discuss

with

(5.74).

the motion of a particle under an inverse-

square force in terms of intersecting

surfaces

done in Sec.

5.6, but here use the ~, p~ plane.

what happens

if a uniform electric

in phase space as was You may wish to show

field is also present.

185

The conditions under which it is possible to separate variables in the Hamilton-Jacobi equation have been much studied, notably by St~ckel in the 1890's.

For a perfectly general physical system, there are

infinitely many kinds of coordinates in which separation is possible. For a particle in three-dimensional Euclidean space it was finally shown in 1934 by Eisenhart *° that there are exactly ii real coordinate systems

(i.e., systemsin which the coordinates are real numbers) that

satisfy St~ckel's criteria.

They are discussed in Morse

and Feshbach

1953, Ch. 5, with diagrams in which certain readers will see the coordinates in three dimensions. The potentials for which each system allows variables to be separated are the same in classical and quantum mechanics and are given in most economical form in Eisenhart's paper of 1948. *Q The variety of problems for which variables can be separated is extremely small, though fortunately for students and teachers it contains some important cases.

The two-body problem is equivalent to

the one-body problem, but when we leave that behind almost nothing is exactly soluble any more except for very special choices of initial conditions.

We have to resort to approximate procedures,

except for certain qualitative considerations, theory is not specially advantageous. 11 approximately,

and here,

the Hamilton-Jacobi

If equations have to be solved

in letters or by machine, ordinary differential equations

are easier to deal with, and most practical calculations start from Hamilton's 5.9

equations.

We shall discuss a few simple methods in Chap. 7.

Interlude on Classical Optics Although it is not possible to create situations in which the

index of refraction varies as freely as potentials do in dynamics, the theory developed in this chapter has its close counterpart in optics. Only the derivations are different, since we start from a wave theory. Let w(r,t) be the phase at a certain point in a monochromatic light ray.

If one goes to a neighboring point r + ~r the phase changes

according to (i.i0) and (i. II) by K.6r.

If one evaluates it also at

a slightly different time the phase changes by m~t. ~w ~

analogously to (4.27). ,0 87

L.P.Eisenhart,

(1948).

K-6r

-

~6t

Thus (5.75)

As before, we introduce a time-independent

Phys. Rev. 45, 427 ~1954].

See also Phys. Rev. 74,

,i An introduction to Hamilton-Jacobi perturbation theory is given by T.L.Perrell, Am. J. Phys. 39, 622 (1971).

186 p h a s e by a L a g r a n g e t r a n s f o r m a t i o n

which

= w +

=

K.~r

toCt

-

t o)

(5.763

-

to)6~

(5.773

satisfies

6s so

e

+ (t

that 8__f8 t - t o = 8to

K -- Vs, From the definition

of K we have by (l.S)

[~co n(to, r ) ] 2

(783 2 The equation integrate

(5.78)

is the same as

=

0

(5.79)

(1.8) but now we know more about how to

it.

Let us consider medium of uniform propagation,

first the propagation

n.

Taking

of a signal

the x axis parallel

through a

to the direction of

we have

('~[r~')ds2 = [~.con(to) ] 2

(5.80)

or

d8 -d-~ =

where k = ton/c as u s u a l .

k,

8

"

kx

(5.78)

From t

=

t

~8 dk ~to - ~

o

-

-

to~)

x

or =

= 2sF~

(t

=

v g. ( t

"

to)

(s.813

where v

is the group velocity, This is in analogy with the particle g velocities given by the analogous procedures in dynamics. We shall see in Sec.

6.5 why it comes out this way.

A more interesting see Fig. (5,79)

5.13.

With

case is one treated before in Example 1.3,

n(to,z)

we can separate variables

and integrate

to give

(s.823 The orbit is determined by

187 ~8

[

~i

=

x

-

~i

dz

(0

J

'

[k~(~,z)

~s ~2

=

~22]½

~i 2 -

~

'

= -f n(~,z)

81

dz

= y - ~2 J [ k 2 ( ~ , z )

~12 - ~22] ½ = 8 2

-

whence x - ~i

~1 and the p r o p a g a t i o n

y - ~2

=

[

a2

dz

= J [k2C~'z)

(s. 83)

- a12 - ~2 21%

of a signal along the beam proceeds

at a rate

given by

dk k "~'~ dz t -- t

0

(s. 84)

=

(k ~ - ~I ~

~2) ~

X Figure 5.13

Bending of a ray of light as it enters the atmosphere above a plane earth.

Problem 5.42.

Integrate

(5.79)

Problem 5.43.

According

to Example

waves

to get

(5.82).

I.i, the propagation

in shallow water of depth h < g/m2

of water

(i.e., kh < i) satisfies ~2 h

where h is some function of x and beach,

discuss

y.

Assuming

a uniformly

shelving

the m o t i o n of a large isolated wave as it approaches

straight beach.

Problem

5.44.

Show that

(5.83]

is equivalent

to Snell's

law for a

a

188

horizontally Problem

4.45.

layered medium. Show that where

Figure 5.14

and n = n(r), horizontally

there is circular

Problem

5.46.

= cos~,

(Fig.

5.4)

Variables in the Smith-Helmholtz relation (5.86).

the invariant

corresponding

layered medium

to Snell's

law for a

is nrsin X

The constant

symmetry

=

const.

(5.86)

is known as the S m i t h - H e l m h o l t z

invariant.

Show that in terms of the direction cosines

the Smith-Helmholtz

invariant

n(ay

- 8x)

(Note that if y >> x this reduces

a = sin~,

(5.86) is

= const.

to Snell's

law for a horizontally

layered medium.) Problem

5.47.

according

Assuming

that the atmospheric

n(r)

find

the

index of refraction varies

to

difference

whose apparent

between

zenith

= I

the

distance

~o e'~(r-R)

+

real

R

and apparent

is

eo,

Fig.

1

(8~S

2

S.15a.

Solution

The eikonal

equation is ~S

(T~)

2

and with S = S r + S 8 this is

+--r2

:

n2

(r)

earth

directions

radius of a star

189

as e so

as =

"

~

C~2]#

-

"~

(n2

=

r--2"

so that

i

r

S =

a 2 ] ½dr

(n 2 - -#~j

+ ~O

(5.87)

R

Figure 5.15

The p a t h

For calculating the bending of a ray of light as it enters the atmosphere above a spherical earth.

of the

ray

is g i v e n

i

by

r

-a

= B, or

as/aa

dr r

(s.88)

=

2(n2

~2 ~ + e

-

r2J

R

To i n t r o d u c e

@

we n o t e

that

from

Fig.

5.15

(b),

0 p

d° I

tan@ o -- R ~

(s.89)

r=R

By (s. 88)

dO dr

n

=

R2(no2 r=R

_ R2 ~-i~

0

=

n(R)

=

1

+

v

0

190

and this,

in

(5.89),

gives = noRsin@ o

To i n t e g r a t e

(5.88), we w r i t e

the i n t e g r a l

dr 2

_

~9o ~ 2 ~

-

r 2j

the

by R in

is

denominator

only of

a few kilometers

the

second

this

dr

thick

integral

we c a n r e p l a c e

and

r

find

[I - e - p ( r - R ) ]

- /__ sin_ I a__ ~o r ~R 2 (1 - ~ - ~2) 3/2

In (5.88),

in 9o as

R

atmosphere

the

to first order

~2 312 ~-~)

_

R Since

(5.90)

is ~)

sin_1~_ + _ r

o

~ R ~ (I

Now we can d e t e r m i n e

the c o n s t a n t

sin-1 or

by

[:

5Y, 3/2 ~-~) 2

-

a =

-

8.

e -~6r-R)]

W h e n r = R,

0

=

S

@ = 0:

a = Rsin8

8,

(5.90)

szn~ = n sin@ O

which

+

the r e a d e r w i l l

readily

solve

O

to give (5.91)

8 = 8o + ~ o t a n @ ° + "'" W h e n r : ~,

the ray has

the a s y m p t o t i c OVV 0 pR 2

In the first t e r m

(I

-

a 2 3/2 + @

O

(5.91)

@ :

=8

~--~-)

it is a c c u r a t e

a = Rsin0 o, and w i t h

direction

enough

to r e p l a c e

65.90)

by

we f i n d

8o = ~ o t a n O o

(1

-

1 0

or,

finally,

0

- 0 ° = ~o(1

-

~

9o tan30o ) tan0 ° - p-~

(s.92)

191

if @

is not too close to ~/2. The first term comes from Snell's o the second is the effect of the curvature of the earth's surface. angle,

though small,

accurate

is of great importance for astronomers,

formulas have b e e n developed.

law; The

and very

The m e t h o d used here fails

w h e n @o is very near ~/2, and a more delicate analysis is required. A value for Vo under typical conditions of Prob.

is given by the formula

i.ii as 2.77 × 10 -4, and a c o r r e s p o n d i n g value for U is

0.14 km -I

W i t h these @~ - @o = 57.1" tan@ ° - 0.064" tan3@ °

At @

= 30 ° the d e f l e c t i o n is 32.9"; o or 9.28'.

at 85 ° it has increased to 557",

Problem

5.48.

Find the term in v 2 that corrects o

Problem

5.49.

Calculate the apparent change in the shape of the sun's

disc as it sinks towards the horizon.

(That it often looks different

from this can be a t t r i b u t e d to inhomogenieties a clear evening,

(5.92).

in the atmosphere.)

the apparent height is about 3/4 the width.

In

CHAPTER 6

It is a relatively mechanics

ACTION AND PHASE

easy matter to derive formulas

from those of quantum mechanics.

about probabilities

into statements

of classical

One translates

about measurable

one finds ways to eliminate ~, either by considering

statements

quantities,

which phase changes much more rapidly than other parameters or by taking averages

in a suitable way

To invent quantum mechanics

(Sec.

phase.

was much more difficult,

This is the WKB approximation

Hamilton-Jacobi

to introduce

from this approximation

equation of Newtonian physics, It is necessary

hypotheses

1.3)

for ways

law.

of quantum mechanics

little new physics:

furnished by the theory are estimates penetrabilities.

(Sec.

It was

the ~ that allows ~-IW to be considered

and turns out finally to produce for the phase resulting

in

2.1).

had to be found in which to introduce ~ into dynamical not enough to introduce

and

situations

as a

(Sec.

Equation

i.i)

[1.6)

is nothing but the and the only new results

of energy levels and barrier

at some point to change something,

that do not belong

to Newtonian physics,

in

order to invent a new dynamics. Bohr's

theory simply grafted a quantum principle

onto a Newtonian original laws.

theory of motion.

and widely underrated,

Heisenberg

in 1925 was the first to do that.

of Bohr's

he rewrote

it in terms of matrices,

Jacobi dynamics, Heisenberg's

(Sec.

SchrBdinger

making 6.5).

theory.

Starting

from an

(Sec.

of Heisenberg

waves with Hamilton-

as he did so, to make a

9.7) which later turned out to be equivalent And much later,

6.4)

changes as he did so, and Independently

united de Broglie's

but again making changes (Sec.

though very

theory in terms of Fourier amplitudes

arrived at quantum mechanics

wave mechanics

involving

ideas,

did not point toward new dynamical

expression

and a year later,

De Broglie's

to

in 1948 Feynman showed that if

one takes ~-lW for the phase of a wave and makes careful use of Hamilton's

principle

and the principle

arrive at quantum mechanics arbitrary

hypotheses

(Sec.

by a path which

is particularly

the reader's

but it may deepen his understanding

the old and new theories

and, in addition,

in which new discoveries

are made.

6.1

one can free of

6.7).

This chapter will not advance dynamics,

of superposition,

knowledge

of classical

of the relation between

show something

of the ways

The Old Quantum Theor Z Quantum phenomena were not first noticed at any one instant,

a good place to begin is Wien's observation

(1895)

that

but

the spectral

193

distribution of black-body radiation has a maximum at a wavelength m

inversely proportional

to theJ absolute temperature of the radiation, g = W (const.) m

and it became clear t h a t the value of the constant of proportionality is about 0.294 cm K, independent of the size, shape, and material of the enclosure: Boltzmann's Nowadays

it is a constant of nature.

Introducing a factor of

k allows the constant to be expressed in mechanical units.

one writes Wien's law in terms of the frequency: kW

kW

kT = T m- =

7

~m

The value of k W / e t h a t could be found from information then available was about i0 -2~ erg sec.

It was

(or, in hindsight,

should have been)

clear that a successful theory of thermal radiation must contain a universal

constant of this size

and units.

(give or take a dimensionless

factor)

The constant was introduced into mechanics by Planck in

his famous hypothesis

that the energy of an oscillator of frequency

is quantized in s t e p s

separated by an interval hw.

Although the hypothesis worked,

it was hard to justify)

as 1906 Planck was thinking about expressing

as early

it in another way, I

He

had noticed that the orbit in phase space of the point representing an oscillator

is an ellipse: p2

q2

2mE + 2E/k = I

and t h a t the area of the ellipse corresponding

to a given energy is

A = 2~(m/k) ½ E = E / ~

As one goes from one energy level to the next, E increases by hv and A increases by ~A=h

This is a recipe for quantizing

the oscillator which puts into

evidence the quantity h independently of any physical property of the oscillator,

and Planck accordingly felt that it might be of fundamental

significance.

He and other workers

imposing the same

thereupon tried the effect of

condition on rotators

and other systems with one

! See for example

Planck

1932,

Pt. 4, Ch.

III.

194

degree of freedom. can be written

The area enclosed by a closed orbit in phase space

as f f d p d x

convenient notation

integrated

over the orbit,

but a more

is ~pdx

=

nh

the orbit

n =

(6.1)

2 ....

integrated

around

Figure 6.1.

The integral (6.1) around a closed orbit in phase space gives the area of the orbit, since the doubly shaded area is covered twice in opposite directions.

The alternative when Bohr's circular

(Fig.

1,

6.1).

forms of quantization

theory appeared.

were discussed until

Here the basic quantum hypothesis

orbits was that an electron's

constant

1913, for

angular momentum

satisfied Po

= nh/2~

n

=

1,

This does not follow from the quantization in fact,

of energy in equal steps;

it gives rise to energies

En

But

(6.2)

2 ....

=

2~2me ~ naha

n

=

1,

(6.3)

2 ....

(6.2) does follow from an action principle

JPodO = 2~po = nh The two laws appeared general principle. integral

to be examples

In several

around a complete J

= ~Pmdqm

degrees

(6.4)

in one dimension

of freedom,

of a

with the phase

cycle denoted by J, it is =

nh

(summed over m)

(6.5a)

195

which was appealing under

a contact

quantization By (4.32), momenta

because

it can easily be shown that J is invariant

transformation

has nothing

omitting

and that therefore

the recipe

to do with the particular

time variation,

for

coordinates

g in two systems

used.

of coordinates

and

satisfies

J

~Pmqmdt

=

~PmQm dt

=

dt

-

dt

But since values,

in a complete

cycle both q and Q come back to their

the last term vanishes

J = ~Pmdqm is

proved.

B u t i's n o t

quantizing

J,

since

o f f r e e d o m s u c h as it

does not

recipe 2 is

lead to

and Pvdqv

~PmdQm

(summed)

to

Newtonian mechanics

correct

a hydrogen

=

the

=

suspended.

of

(6.5b)

w i t h more t h a n

an e l l i p t i c a l

levels

at

(6.5a)

nvh,

is not summed over v.

to identify products

systems

energy

terms

~Pvdqv

quantize to

atom w i t h

to quantized

Jv

future

=

when a p p l i e d

separate

all.

and w r i t e

nv

=

I,

orbit

How the procedure works

J = ZJv,

2 ....

(6.6)

The ball moves

in each segment continuous

is

based on classical physics.

= ± (2mE) ½

the function

Integrating

Phil. Mag.

(x

-

walls

at x = 0

Xo)

segments

in Fig.

6.2a.

oscillator

across

so as to make

S

(The characteristic is shown for comparison

in

the box and back gives = 2(2mE)

to the quantum condition,

W. Wilson,

it encounters

Joining

for the harmonic

J

2

to

1 will be

of (dS/dxJ 2 = 2mE are of the form

of the path.

gives

(5.7)

6.2b.)

According

is

can be seen from a calculation

freely except where

The solutions S

Fig.

v in the

the summation convention

A Ball Between Two Walls

and x = £.

function

6.8)

where

to see that in the limit of high quantum numbers,(6.6)

closely connected with arguments

Example I.

(Prob.

We shall use the subscript

in which

by

one d e g r e e

The c o r r e c t

be carried out in the next section, but following Example instructive

initial

and the invariance

29, 795

½

the ball's

(1915).

energy

in its nth state

196

will be

E

-n

n2h 2 8m~2

n = O,

I,

2....

5 5

.... X 0

Figure 6.2. Characteristic function S(x) for (a) a particle bouncing between two walls; (b) a harmonic oscillator.

Problem

6.1.

What is the q u a n t u m - m e c h a n i c a l version of this result?

How do they differ?

The

Correspondence

The

Limit

following argument is an e l e m e n t a r y part of Bohr's theory.

Consider circular orbits with quantum number n for convenience; it is easily shown

(Prob.

6.4)

then

the orbital frequency of an

that

electron in the nth orbit is

~n

me

=

(6.7)

n3~ 3

The energy of the state n is (6.8)

me

E =

2n2~ 2

and the frequency of light emitted in a transition from state n to state n - ~ is ~n,n-a

= ~-I(E n _ En_a )

me ~

= ~

1

((n

-

1

~2

"~)

197 ( n_~ * ~ -2c~ Y ÷ ....

me

~17 )

or

mn,n-~

= ~n

+ "'"

Thus in the limit of large quantum numbers, starting

transitions

of the orbital

~ = I,

2,

the frequencies

from state n are just the various

frequency,

and the results

(6.9)

...

emitted in

Fourier harmonics

of quantum theory are in

harmony with what one would expect by classical

reasoning.

the formula above could have been obtained by writing

Note that

Taylor's

series

as

(n_

but since n varies

~

: V~ -

~ TffT~

in integer

That the nonsensical

+ : - - +n2

n-T

+

"'"

steps the derivative makes no sense.

procedure

leads to the same result as the careful

one used above will be important

in simplifying

the developments

to

follow. Derivations

o f the Q u a n t u m

It is instructive the quantum condition energy.

Supposean

Conditions

to turn the foregoing (6.6)

argument around and derive

from the simple notion of a quantum of

oscillating

system with one degree of freedom is

in its nth quantum state, where n is a large number and we are in the domain of the correspondence (-An) quanta at its frequency

principle.

Let the system emit a few

of oscillation,

v, so that the energy

E(n) decreases by

Denoting

differentiation

in the schematic way just explained,

we can

write this as dn

1

where T is the period of oscillation From

T

of the oscillator

in state n.

(5.6) we can write f in terms of J, the value of S on

integration

around a complete

cycle: T = dd 2-E

(6 i 0 )

198

Thus dJ dE

which

integrates

essentially

as we can verify a complete

dn d--E

+

const.

nh

result

from the value

(6.11)

(6.1)

for a harmonic

of S given in (5.7).

oscillator,

Integration

over

cycle gives

the quantum

2~(m/k)

condition E

The constant, and not

(6.5),

½

= E/~

is =

as we now know,

The same argument (6.6),

=

Planck's

J =

so t h a t

h

to J

This gives

_

nh~

const.

+

is ½hr.

explains

why for a multiply

is the correct

periodic

rule for quantization.

Such a

system can emit quanta with

frequencies

each of its periodicities.

We then have for the vth degree of freedom AE v =

If as in all the examples then J reduces before general

case,

we have given the variables and the argument

For a nonseparable

EinStein 3

proposed

system,

equal

cycles

to n h .

convenient

of each of the various

The anisotropic

though

tion has already of y, the phase ra 2 J

= r8

been done. integral

example

condition:

discussed because

If we integrate

as

is of course

the

Integrate

number

of

and set this

on page

178 is a

most of the calcula-

over r cycles

of x and s

is

-

nh

r,

s,

n

=

O,

1,

2,

...

(6.12)

~2

(Here a2 and a I - ~2 are the energies x and y.)

goes through

8(a I - a2) +

~i

to

are separable,

an integral

periodicities,

oscillator

too elementary

which

a new quantum

over any closed path in q space which makes complete

corresponding

&nvhVv(nv)

to a sum as in (6.5)

for each Jr"

and energies

system

The only way in which

associated

this relation

with the motions

can be satisfied

in

for

all integral values of r and 8 is if a2/Vl and (al a2)/~ 2 are each integral multiples of h. Thus each of the oscillator's degrees of

3

A.Einstein,

Verh.

Deutsche

physikalische

Gesellschaft

19, 82 (1917).

199

freedom must be quantized separately. is that it is separable.

The trouble with this example

There is no soluble nonseparable Hamilton-

Jacobi equation known to the author. Problem

6.2.

Planck's formula

for the spectral distribution in black-

body radiation is

dI

=

8~ahl-S

l

exp(ha/~kT)

- 1

Locate the maximum of this curve, make a rough calculation of the constant W in (6,1) and, using a modern value of k, see how good a value of h is implicit in the Problem V(x)

6.3.

I

= ~

nineteenth-century measurement.

Find how the period of an oscillator obeying the law

Kx ~ depends

on the energy and amplitude of oscillation.

The

action integral J can be evaluated with the help of the integral formula 1

r2

(6.131

(1 - x~)~dx 0

which may be derived with profit and enjoyment from the integral for the beta function. tm-l(l

-

t)n-ldt

=

rF(m (m) +r (

= B (m, n)

0

and some of the identities satisfied by the gamma function F(n). ProbLem 6.4. Find the energy levels of the oscillator in the last problem using the quantum condition in phase space, and show that the

calculation is almost exactly equivalent to a solution by the WKB approximation. Problem

6.5.

Derive (6.8) for a circular orbit.

Problem

6.6.

The potential Y(r) binding two quarks together is usually

supposed to increase with distance. V(r)

= g

Supposing that In

r

o

show that the quantum conditions gives energy levels En = 2-~ In ~ for s states

nh

(zero angular momentum) where p is the reduced mass of

the two quarks.

The integral is not as difficult as it looks at first.

200 What is the difference

in energy between the nth state and the ground

state? 6.2

H y d r o g e n Atom i n t h e O l d Quantum T h e o r y We c a n u s e t h e r e c i p e

and t h e i r lies

degeneracies.

i n t h e xy p l a n e ,

to

(6.6) If

1 the total

For an a r b i t r a r y

the

2

angular

orientation

(Pr

is

Pa 2 *

energy levels

a r e c h o s e n so t h a t

then the hamiltonian H = ~

w h e r e Pa i s

find

coordinates

easily

ez

(6.14)

momentum, w h i c h i s of the axes,

the orbit

f o u n d to be

)

r2

of hydrogen

around the z axis.

one f i n d s

in spherical

coordinates 1

p82

H = -~

where

p 2

~2

(pr 2 +

+ ~

e2

)

- -~-=

p is the reduced mass of electron and proton.

cyclic,

pc is constant

(6.15)

E

Since

~ is

and we can write s = st(v)

+

So(O) + p ~

46.16)

Then ~)S0 2 p 2 (TO--) + sln2@=¢ - -- ~@

(const.)

46,17)

and ~S r

(~) If we write

2

c~0 e2 + - ~ = 2m(E + T - )

(6.17] as PO 2 + ~

and compare total

(6.18~

(6.15)

with

(6.14),

: ~O

we r e c o g n i z e

s 0 as t h e s q u a r e o f

the

a n g u l a r momentum,

J¢ : . ~ p ¢ d ¢

: rich

(6.19a)

~D

C6.19b)

2

=

J~--

-

[~(~

sln20J e2 + T)

~

- -~2]

½

h

dr = n r

(6.19o)

201

These are (Prob.

6.7)

(6.20)

Jr

=

-(J@ + Jq5) + ~e2(-2-~EE)½

Thus

p~ = n ~ h / 2 ~

~0½ = p~ + n o h / 2 ~

It was customary in Bohr's theory to write ~@

½

= (n~ + n o ) h / 2 ~

as £h12n and n# as m,

so that £ = m +n o Since m can be positive or negative while no, n r > 0 we have -£ < m < £ as is given also by quantum mechanics,

(6.21)

although in the newer theory

the square of the orbital angular momentum is written as Z(£ + 1)~ 2. From (6.20) the energy is given by

E = -

2w2Pe~ 2w2Pe~ 2wZpe~ ~J~ + Jo + Jr )2 = - h2(n~ + n o + nr) 2 = - h2(£ + nr)

(6 22)

Evidently there are a number of sets of integers n. corresponding any value of E except the lowest; degenerate.

to

these levels are said to be

Problem 6.10 shows that if n~ + n@ + n r = n, the

degeneracy of the nth level is n 2. After the elliptic orbits of hydrogen had been quantized in this way, Sommerfeld

(1923) used the same methods to quantize the orbits

of the relativisitc theory.

His results agreed with experiment, yet

we now know that this was a coincidence, (but then unknown)

for he omitted the important

effect of electron spin.

The same formula was

correctly re-derived from quantum mechanics by Dirac in 1927.

Problem

6.7.

Carry

out the integrations of (6.19b,c). ~

In both,

it is

The necessary indefinite integrals are in Dwight's Tables, but the best way to carry out closed integrals of this kind is by the use of complex variables. It is not only faster when you know how to do it; it also enables more difficult integrals to be done. For the relevant techniques see Sommerfeld 1923, Note 5; Born 1927, App.2; Goldstein 195@, Sec. 9.7.

202 necessary

to think carefully what the limits of integration

start on J@ take cos@ = V as the variable integrand will then involve

separately.

Show that if the quantum rule J = nh is adopted, with J

6,8.

(6.Sa), 6.9.

Problem

To

1 + __r__9)

I

and the two terms can be integrated

given by

are. The

(5 - ~z)-1, which can be written as

I

Problem

of integration.

a continuous

Evaluate

applied electric the integrand

spectrum results.

the energy shift in a hydrogen

field F.

The action integral

in powers of F.

see Sommerfeld

atom due to an

is difficult;

This is a long and difficult

1923, Note Ii; Born 1927, App.

expand calculation;

2; and Goldstein

1950 for

support. Problem

6.10.

Derive

(6.1S) from the corresponding

lagrangian.

Problem

6.51.

Carry out the separation of variables

Problem

6.12.

Show that if n~ + n@ + n r = n, the degeneracy

that yields (6.16). of the

th level is n 2 6.3

The Adiabatic

Theorem

There is a remarkable sought to establish

argument by which Bohr and Ehrenfest s

the universality

of the quantization

procedure

(6.6) by showing that if it works for one class of potential fewer)

dimensions

it works for all.

originally

due to Boltzmann,

mechanical

transformability

Suppose

The argument

that in a cyclic system

that describe

that the change in the action integral

change the parameters Haar 1961).

The discussion

We imagine parameters) s

a(t)

we make a

The theorem

J is then very slow,

in

as much as we want, without

amount,

provided

that we

slowly enough.

A general proof is rather difficult make it a proof,

theorem.

the system that is slow

in any way.

the sense that we can change the parameters changing J by more than any preassigned

of

called the adiabatic

(orbiting or oscillating)

and does not cause the system to resonate

in 3 (or

on a theorem,

which Bohr called the principle and Ehrenfest

change in some of the parameters states

depends

(Saletan and Cromer 1971, ter

to follow omits the epsilons

that would

but is intended to show why the theorem is true. that the hamiltonian

H

contains

a parameter

(or

which has been varying slowly since an initial

N.Bohr, Kgl. Danske Vid. Selsk. Skr., nat.-math. 1 (1918); reprinted in van der Waerden 1967.

Afd.,

time

8. Raekke

IV.

203 to .

We assume

that it is possible

such that although a(t) time,

changes

to define a time interval

only by a small amount

the system goes through many cycles.

hamiltonian

changes

a since t

changes, the

at a rate

equations,

(6.23)

OH p + ~OH q + ~~H a• = ~-~ ~H a• = ~-~

H(p, q , a ( t ) ) by Hamilton's

As a(t)

t o to t

Sa during this

so that the change

in H due to the change

in

is

OH = it OH ~dt

o

J If a has changed

slowly during

the interval,

this expression by its time average

it

6H = |

Oa

t Now we calculate integration

adt

adt

= t

=

Oa

(6.24)

0

in J, the value of S

is over a single

in

over a cycle,

0

the change

OH/Oa

we can replace

=

SPn~ndt

when the

cycle

6.I = ~ (pn6qn + qn~Pn)dt

= [pn~qn] The integrated The

integral,

+ ~ (-Pn6qn + qnOPn )dt

part vanishes by Hamilton's

very nearly on integration equations

~j = ~(O~n

(compare

the derivation

of

in a.

(2.65)).

The total change

is

~H Bpn} d t Oqn + ~OP n

the changes w h i c h have accumulated change

over a cycle.

In this relation,

(6.25)

6q and 0p are

since t o as a consequence

of the

in H is

6H = ~H ~pnOPn ~H Oq----nOqn + ~ + ~-~ Oa so t h a t r OH Oa) d t OJ = ~ (OH - 7a

- f coa

)oadt

(6.26)

204

by (6.24).

Now integrate

again as in deriving

~-H ~6adt

(6.24)

0

(6.27)

so that 6J is not of the order of 6a, as one might have expected, smaller.

If one wants

a, the analysis

to know how J actually

changes

but

as a function of

is much more complicated. 6

Not every slow change of potential hump in the potential

of Fig.

leaves J constant.

6.3 is slowly raised,

I f the

a particle

becomes

E

Figure 6.3

Potential which violates the adiabatic theorem if the hump is raised.

trapped on one side of the well or the other and J changes discontinuously.

The theorem does not apply here because

at the moment the

trapping occurs a small change in a makes a very large change in p and q.

Thus

(6.27] cannot be used and the argument

of Bohr and Ehrenfest was that if one has a system

The argument such as a harmonic

oscillator (6.6)

in i, 2, or 3 dimensions

quantization

rule

transformed,

by slowly changing

entirely different

quantization

in which the

is known to work, one can imagine

system,

But the action integral points analogous

fails.

the shape of the potential,

say an atom or even something

once equal to nh remains

to that of Fig.

it being into an

like H2 +

so, if no singular

6.3 are encountered,

and so the

rule is universal.

There is a further argument

that makes the adiabatic

plausible basis for a theory of quantization. system is slowly distorted

Suppose

in the way we have described.

will slowly change as the external

theorem a

a physical

forces do their work.

Its energy This means

that there will not be a sudden quantum jump from one value of n to another,

s

for this would involve a discontinuous

change

in energy or in

P.O.Vandervoort, Annals of Phys. 12, 436 (1961); A.A.Slutskin, Soy. Phys. JETP 18, 676 (1964). Calculations of this kind are important in the theory of a plasma confined by a slowly varying magnetic field. See Chandrasekhar 1960, p. 48.

205 some other parameter which ought to change slowly and continuously. Thus the quantum numbers with

should be adiabatic variables,

in accordance

(6.5a).

Example

2.

A ball is set to bouncing

which slowly changes

onthe

its acceleration.

hard floor of an elevator

How does the duration of one

bounce vary? If the ball starts upward at a speed Vo, its trajectory

is given

by y : rot - ½ gt 2

where g is the acceleration

of gravity plus that of the elevator.

bounce lasts for a time T = 2Vo/g.

[

The phase integral

One

is

Tm

j =

2dt = 2 3 mVo

-0

Thus,

= ~I

mg2T 3 :

const.

g

T ~ g "2/3.

Example

$.

A particle

is gradually

circles

strengthened.

in a uniform magnetic

How do the radius

field B which

and kinetic energy of the

orbit change with B? With B constant,

the orbit is determined by the balance of forces,

m r m 2 = er~B,

so that the frequency value.

By [4.16),

m = eB/m

(6.28)

is determined hy B but the radius can have any

the phase integral

is

J : ~p.d~ = ~(mv + e A ) . d £ where A i s velocity

the vector

v is

Cnearly)

potential constant

second t e r m i s s i m p l i f i e d

of the field.

In the first

i n m a g n i t u d e and p a r a l l e l

by S t o k e s ' s J = ~mvd£

theorem:

+ e I VxA.dS

= 2~mvr + ~r2eB

With v = mr = e B r / m by [6.28), this is J = 3~r2eB = 3eft = const.

term, to d~.

the The

206

where # is the total flux through the orbit. varies

as B -#, and multiplying

If J is constant,

= m2 shows that the kinetic energy varies as B. methods

for heating

a plasma is to immerse

is then slowly increased. since a magnetic particle's

Although

6.13.

oscillating varies,

energy,

remember field.

that a changing magnetic

1 is suspended a mass m

frequency,

field is slowly established

How does the electron's

Problem

6.15.

moved.

How do the frequency and kinetic £?

Problem

It has been hypothesized

1973, p. 45; Reines year.

Discuss

energy change? i,

p. 195, are slowly

energy of the ball vary with

by Dirac and others

the effect of changes

in G on planetary

i how the phase integral S arises

the solution of Schr~dinger's

of the form A(x]

exp[is(x)].

is pursued,

one encounters

an almost exact integration (6.1)

is possible

level.

since p involves

fails.

(Merzbacher

Here 1970, Ch.

in the allowed and forbidden

is replaced by

~pdx = (n + #)h which,

equation by an

the question what to do if

7), and on using this to connect solutions one finds that

in the

This is the WKB approximation.

there are the turning points where the approximation

regions

orbits and on

with Quantum Mechanics

of approximating

If the analysis however

(Mehra

1972, p. 56) that certain of the fundamental

We have seen in Chap. expression

to

to the moon, which can now be measured very accurately.

Connections

process

perpendicular

of nature are really changing by about i part in i0 I° per

the distance

6.4

If

a circular orbit in a Bohr

The walls of the box of Example

the separation

constants

As the acceleration

and energy vary?

in the nth quantum state, how does n change?

A magnetic

6.16.

k.

amplitude

the orbital plane of an electron executing hydrogen atom.

field

It is this that does the work.

at the end of a spring of stiffness

how do the spring's

6.14.

field which

it might at first be argued that

In the elevator of Example

it was initially Problem

One of the standard

it in a magnetic

field does no work it cannot posibly change the

kinetic

gives rise to an electric Problem

r

the two sides of the equation by (eB/m) 2

E, is an implicit

(6.29) equation for the nth energy

The wave function between the turning points a and b is

approximated

hy

207

~(=) =

Nk-@cos[

z
(6.30)

a ~ x _< b

and that in the forbidden regions by analogous This is the point of closest contact between

exponential

expressions.

the old quantum theory

and quantum mechanics. But the WKB theory does more than enable us to derive and correct the equations

of the old theory;

it helps us to understand how the new

one is related to what went before. expectation

Quantum mechanics

value of a dynamical variable

the corresponding

operator

a(p,x)

states that the

is given in terms of

~ by

= I~*(x)~(p~x)~Cx)dx

(6.31)

Let us see how this formula works in the especially which a is a function of x only.

We consider n to be large, but

will later return to the question of small n. the forbidden

regions

simple case in

contributes

negligibly

The wave function to the integral,

in

which

we write as

I

k-1(=)a(x)cos~[

a

so

kC=')dx' - I

(6.32a)

=

a

Ibk-1 (=)cos~ [

~]dx

[~k C x ' ) d = '

1~]~x

a

using

(6.30), where ~kC=)

If n is large,

= pCx)

the (cosines)ain

:

{2m[~-

vC=)]} ~

(6.32a) oscillate many times and can be

replaced by their average value of 1/2:

Ib [~l¢(x)]-la(x)dx Ja -- "'b v~ Let us interpret ~ik as the classical momentum:

(a) = I

J

m-l ~dx dt

208 and finally,

change the variable

of integration

from x to t:

Itb a[x(t)]dt ta
where ~ is mechanics averages the

the

Thus e x p e c t a t i o n

correspond,

in the theory.

first-order

to a rule

that

a small

in energy

by the

values the

system.

to time

which says

that

state

see

corresponds

system produces

of the perturbing

We s h a l l

from the adiabatic

rule

by a perturbing

unperturbed

of a classical

time average

in quantum

quantum numbers,

produced

in the

perturbation

in the unperturbed

this rule follows

of large

In particular,

e v a l u a t e d

change given

evaluated

limit

perturbation

A

H1 i s

(6.33a)

= ~

time average.

in classical

hamiltonian energy

=

an

energy

in Chap.

7 that

theorem.

Problem 6.17. Suppose that a is a dynamical variable containing p and x. Is (6.33a) still true? (Consider first ~ itself, then polynomials containing

terms like x2~m~ 3 ...)

Problem 6.78. out above,

Using

(6.12) and a calculation

similar to that carried

show that for large m, the dipole matrix elements

which define allowed optical

transitions



are given in classical

terms

by

= T -I

cos(~amt)x(t)dt

a = m - n

(6.33B)

~0

where the time T covers a whole number of cycles, frequency

in the mth state,

It follows

and a << m.

from the result of the last problem that the matrix

elements of x correspond

to the Fourier components

variable,

and we see how to interpret

vanishes,

the quantum transition

corresponds

either.

proportional

of the classical

the fact that if

is not allowed.

to the same frequency,

at this frequency, physics

~m is the classical

The Fourier component

and if the system is not vibrating

one would not expect any radiation

Furthermore,

in classical

since the intensity of radiation

is

on the one hand to lI 2 and on the other to the

square of the amplitude Fourier amplitude,

of the electromagnetic

we see that intensities

are related by our formula.

wave coupled to the

as well as selection rules

209

The

Correspondence

Principle

At high quantum numbers, theories

are supposed

the results of classical

to correspond.

and quantum

This is an obvious

requirement

of any version of a quantum theory and of course it emerges equations

of the two theories.

approximation that there

is reasonably

is a one-to-one

semi-classical

methods

What is not trivial

accurate

useful theory.

between states deduced by

and those of the exact theory.

though heuristic

given above,

theory

(Sec.

although until

argument.

rule relates

to quantum mechanics

remember

the connection

between

S = ~¢.

If we traverse

the configuration

AS = J = nh,

principle,

of quantum

6.5) explained why it is true Bohr preferred

to call it the correspondence How Einstein's

One is not led

and it furnished a

guide in the early development

It is known as the correspondence

Heisenherg's

is that the WKB

at low values of n also, and

correspondence

to expect this by the arguments

from the

is clear if we

action and phase found in Chap.

space in any closed loop,

whence A¢ = ~ n

We see that the quantum-mechanical space in all its dimensions, condition

of periodicity

natural generalization freedom.

(6.34)

"wave" is a wave in configuration

however many they are, that

the wave must satisfy,

and that

of the usual quantum condition

from a moving boat the apparent

is the

(6.34) is the

to f degrees of

else.

The wavelength

If one studies ocean waves

frequency will change with the boat's

speed and direction but the wavelength

is a property of the water and

of a "matter wave," on the other hand,

is given by the momentum

of the matter,

motion of the observer.

The wave function

carrier of phase and amplitude,

and that depends partly on the in quantum mechanics

are described.

In the next

section we shall see that though phase and amplitude quantum mechanics, Heisenberg's

is a

which are the two crucial parameters

in terms of which natural processes

6.5

(6.34)

There really isn't any "matter wave" in the same sense that

there is a sound wave or an ocean wave.

nothing

I:

are essential

waves are not. Quantum Mechanics

After Hamilton had shown that there is an affinity between the equations

of Newtonian mechanics

and those of wave motion,

century elapsed before evidence was discovered relationship

might have a counterpart

almost a

that this formal

in nature,

It is not

to

210

derogating

from SchrSdinger's

discovery

to say that if he had not

followed his own path to his wave equation

(Sec.

would soon have derived it in another way. general

formulation

of quantum mechanics

9.7) someone

The first correct

the foundering

The successes

and

did not stem from the idea of

waves at all, but rather from a series of brilliant to correct

else

quantum mechanics

guesses about how

of Bohr and Sommerfeld.

of this theory were always more noted than its failures,

but by 1925 it was clear that the theory was giving wrong answers-the excited states of helium, calculate

by perturbation

for example,

theory because

should have been easy to

their energies

differ only

slightly from those of hydrogen but Born and Heisenberg ~ were unable to get agreement with experiment. possible,

using the separation

Similarly,

of variables

of Sec.

the electronic motion in the ion H2 + exactly effects

of nuclear motion)

but here again,

and so determine

experiment

Copenhagen,

was Bohr's

though Heisenberg

the right path,

2.12, to quantize

(neglecting

the small

the ion's binding

energy, 8

disagreed.

The locus of the discussions quantum mechanics"

it should have been

that finally gave birth to the "new

Institute

for Theoretical

Physics at

was quite alone when he finally found

in June 1925, on the North Sea island of Helgoland.

It is unnecessary

to try to follow the full history here--much

of it

is given in van der Waerden 1967 and it is full of false starts and good guesses,

but it may be instructive

the old quantum theory was modified

to see the formal way in which

into the new.

Heisenberg 9 started with the claim that an atomic theory should involve observable

quantities

and that it is therefore pointless,

example,

to talk about the orbit of an electron

modified

also the most characteristic

theory,

around a nucleus,

~mn

He

and singular result of Bohr's

that except in the limit of large quantum numbers,

frequency

for

the

of light emitted from an atom in a transition

from

state m to state n is not the same as the frequency of any of the electronic motions

mmn

inside the atom.

The trouble

is, of course,

that

depends on the final state as well as the initial one:

~mn and Heisenberg's

Ann.

~-~ (Em - En)

C6.35)

first step was to assume that all dynamical

7 M.Born and W. Heisenberg, 8 W.Pauli,

=

Z,Physik

quantities

16, 229 (1923).

d. Physik 68, 177 (1922).

9 W.Heisenberg, Z. Physik 33, van der Waerden 1967.

879 (1925).

Translated

and annotated

in

211

have the same kind of dual dependence:

a coordinate,

for example, was

to occur in the theory as a quantity

Xmn(t) = Xmnei~mnt though

its precise relation

The corresponding

momentum

to experiment

remained

to be specified.

is •

Pmn where v is the particle's

(6.36a)

=

°

~Xmn

--

(6.36b)

~mnXmn

mass.

What these two-index quantities mean was not clear, but fluctuating

quantities

for radiation manifest another

like the electric dipole moments themselves

during transitions

(m ~ n), while constant quantities

single state

(m = n).

this kind is suggested, can be understood us examine

such as energy refer to a

How to calculate with two-index but only suggested,

limit of large quantum numbers,

[see

quantities

of

by the fact that in the

the different

as Fourier harmonics

responsible

from one state to

spectral

frequencies

(6,9) and (6.33b)].

Let

this relation more closely.

Fourier Amplitudes Suppose which,

a one-dimensional

according

to Bohr's

Then its coordinate

system is in its mth quantum state,

theory,

can be represented

x re(t) = where the

the

state

Xm(t)

is

X~ a r e m

m.

a set

They

it oscillates

are

of

2

constant

not

all

with frequency

in

a m-

by the Fourier series

xae ia~mt

(6.37)

m

Fourier

independent

amplitudes because

appropriate the

to

coordinate

real:

x m*(t)

= Xm(t)

or

Za*e -ia~mt m

= ~ X a ei~mt m

= ~ X -ae -ia~mt m

so t h a t x~* = Xm-~

(6.38)

212 The correspondence (6.36).

principle

suggests

as calculated by classical given by

(6.35).

frequency

~

n

considerations

Classically,

and its Fourier

a system

according

a neighboring

to quantum

should be the same as that

radiates

theory,

(Note that here and subsequently,

aE an n

than infinitesimal

quantities,

to an

to a ratio of finite rather

as already remarked

In the limit of large n, the two frequencies like

n to

(6.39)

the "derivative" with respect

in integer steps refers

~ in expressions

from state

is

index which varies

from this that

at the natural

in a transition

~_2 (E n - E n . ~ ) : ~ - i

=

to

frequency

~ : I, ~, 3, ...

state n - e, the frequency

mqu

(6.37)

the radiated

harmonics:

mcl : ~ n whereas

how to relate

In the limit of large quantum numbers,

(6.37)

following

are equal. corresponds

(6,9).)

We learn to m - n in

(6.34) . Quantum

Amplitudes

Calculations

are performed w i t h functions

momenta.

To see how functions m a y be formed,

represent

x m 2 in a series

analogous

Zm2(t ) = Let 8 : Y - ~.

~

and

to (6.37).

We write

X~X~ei(~+~)~m t

Then x 2(t)

=

m

SO t h a t

of coordinates

let us see how to

the Fourier

~

amplitude for

(6.40)

x~xY-~eiY~mt mm

~,Y

Xm2 i s

S X~X7-~

(6.41)

mm

We have suggested above that the Fourier amplitudes the quantum amplitudes

in (6.36],

and that

X e corresponds m Now what corresponds

to

(6.41)?

to X

Combining

together w i t h their time dependence

correspond

in some sense, m3m-~

(6.42)

the quantum amplitudes

according

to C6.40] gives

to

213

i~-1(Em-Em_e)t X

Z Xm,m_~e a corresponding

to (6.41).

m,m_y+

e

i~-*(Em-Em_y+~)t

This does not have the required time

dependence (6.36a), but if we change it to

Z X c~

ei~ - * (Ern-Em_ ~) t x

ei~ -I (Em_~-Em_ Y) t

or, more succinctly, = ~ x

a

(m2)m'm-Y then

the

terms

agreement (6.40).

Then

with

Em_ ~ c a n c e l (6.36a)

The n o t a t i o n

(6.43)

as w i t h

k runs

over

Heisenberg's merely

first

condition

(6.39) the

invention. the

recognize

it.

The Quantum

let

quantity

m - ~ = k and m - y = n.

for

to to

of the

Note that

introducing

this

this into

agree with

for

This

point

is

he h a d s t o p p e d

a new n o t a t i o n ; the

new p h y s i c s .

multiplication

he h a d n e v e r

recipe

system.

at

quantum theory

matrix

(6.44)

E XmkXkn k

so as t o make i t

Apparently

according

a nd p r o c e e d e d

old

he was

rule

=

quantum states

an e q u a t i o n

recognize that

corresponding

c a n be s i m p l i f i e d :

all

transcribing

changing

the

is

(x 2 ]ran where

(6.43)

(x~)m,m. Y h a s a t i m e d e p e n d e n c e i n

and

as w e l l

m,m-~ x m-a,m-y

The r e a d e r

but Heisenberg

heard

by

frequency

of matrices.

will did not

He n o t e d

(XY)mn ~ (YX)m n

forming products,

draw m o m e n t o u s c o n c l u s i o n s .

Condition

In the old quantum theory,

Planck's

constant made its appearance

via the action integral,

Pvdqv = mvh (See.

6.1),

w h e r e t h e mv a r e

find how ~ occurs Again,

v = I, integers.

in a calculation

the calculation

2. . . .

Heisenberg's

f

C6.45) next

task

was t o

5ased on the two-index quantities.

by Fourier amplitudes

pro(t) = Z P~e i ~

mt

furnished a guide.

Let

214

Then in the mth state of our o n e - d i m e n s i o n a l

system,

2~m-1

J

Jp

m =

The integral

1

• mXmd t

t .... ~ iB~ t._ ~mXm e mav

~a £ ~ m ~m e

= a~S] °

is zero except for the terms in which B = -e:

Jm = ~ - - Z m

or J

The b a s i c increases

in

assumption steps

o f h, J

m

of Bohr's

(6.46)

~ aPeX -a

a

/nm

method of quantization

~ aPeX-a m r~

J

m

(6.41) was trans-

(6.43), -2~i

in which the exponential with r e s p e c t

that

= mh + const.

Transcribe it in terms of quantum amplitudes just as scribed into

is

so t h a t

= -2~i

m

= -2~i

to

2 aPm,m_aXm_a,m

(6.47)

= mh

Now d i f f e r e n t i a t e

time factors now cancel.

m! -2~i

with " d i f f e r e n t i a t i o n "

Z a ~m e

as in

(Pm,m-~Xm-a,m)

(6.39).

= h

H e i s e n b e r g now constructs the

integer relation of w h i c h this is the quantum limit. O~ ~'~ f ( r n )

= f(m

so that in the limit of small ~,

e with ~ = h/2~.

(Pm+a,mXm,m+e

+ a)

(6.48) becomes - Pm,m_eXm_e,m)

This is Heisenberg's

(XmkPk m

or in matrix notation,

He writes

- f(m)

= £~

second invention.

in the first term and m - e = k in the second.

k

(6.48)

- PmkXkm)

= i~

Then

(6.49) Let m + e = k

215 (xp

-

[6.50)

PX]mm = i ~

This is the first time that either the imaginary i or n o n - c o m m u t i n g dynamical quantities, what Dirac later called q-numbers, had ever occurred in physics

in any essential way.

A Simple Application The a p p l i c a t i o n of these ideas to a harmonic oscillator

is so

simple that it is not an adequate test of the theory, and even in his first paper H e i s e n b e r g w e n t on to consider the more difficult p r o b l e m of the energy levels of an anharmonic oscillator, but the simpler problem contains : mass and

some, at least, of the essential

Pmn = ~Xmn" i~

=

or

(6.50)

i~Z CXnk~knXkn k =

because

~kn = -~nk"

ideas.

With

is

-

mnkXnkXkn )

2 ~ ~knXnkXkn

The great s i m p l i f i c a t i o n here is that the

o s c i l l a t o r is harmonic;

its m o t i o n is at the frequency

there are no higher harmonics.

~n,n-1

= ~ and

Thus the sum has only two n o n v a n i s h i n g

terms: =

2~(Xn, n+lXn+l, n

-

Xn, n-lXn_l,n)

(~6. Sl)

Heisenberg assumes, i n analogy w i t h C6.38]tthat X

=

X

mn

so that

nm

(.6,51) is

C6.s2) In this r e l a t i o n let m = 0, c o r r e s p o n d i n g there

is no lower state,

Xm,m_ I

to the ground state,

Since

= 0 and

IXo,112 = We can now use

(6.52) to find all the IXm,m+:[ 2 =

Note t h a t Xmm = 0:

IXm,m+712.

(m +

:) 2~

C6.55)

the o s c i l l a t o r ' s displacement x has, of course, no

zero-frequency Fourier component, and the time-dependence of x is

216

manifest a part.

only during a radiative

Now let us calculate

transition,

the energy.

in which Xmn(m # n) plays

We assume the formula from

classical physics ,~ = ~ ~ ( x 2 + ~ 2 x 2 )

and transcribe

it as

Hmn The nonvanishing

H

mn

=

1J[ (X2) mn + ~)2(X2)mn ]

~

have n = m±2 and n = m.

Hm,m+ 2 = ½ P(Xm, m+iXm+l,m+2

We find

+ ~2Xm, m+lXm+l,m+2)

= ½ ~ [ ( . i ~ ) X m , m+l(_i~)Xm+l,m+ 2 + ~2 Xm,m+lXm+l,m+2 ~

and s i m i l a r l y ,

~Mcm-2. : O.

H mm = ~ ~[~m,m+iXm+1,m

The diagonal matrix

+ xm~milXM-l~m

= 0

element is

+ ~2(xm, m+lXm+ljm + Xm, m_iXm_1,m)]

or

By

this is

(6.53)I ,

or ~mm = (m + ~ ) ~ Thus the energy is represented diagonal matrix.

by the elements

(6.55) of a time-independent

The extra half in the energy was not entirely new.

It had been conjectured

earlier as a necessary

correction

to the

Planck formula but this was the first time it had emerged from a mathematical

scheme.

The unfamiliar Xmn.

Clearly,

oscillations. amplitude

quantity

in all this is the quantum amplitude

it has something Let

the

energy

to do with the amplitude

of state

A m as one w o u l d c a l c u l a t e

E m = ½ (2m + I ) ~

= ½p~

it

m b e (m + ½ ) ~ . classically

Am

is

of the Then t h e

g i v e n by

217

This is something

like

(6.53) but not the same.

thing about the calculation

of (6.5S)

has it been assumed that the oscillator The

idea

of a trajectory

And the remarkable

is that nowhere, is executing

even implicitly,

sinusoidal motion.

does not occur.

Equation of Motion Suppose that some dynamical variable f is represented by a matrix

fmn = Fmnei~mnt Then its time derivative

is

fmn = immnFmnei~mnt i = ~ (Hmm - Hnn)fmn i = ~ (Hmmfmn - fmnHnn ) If H is a diagonal matrix,

this is i

(6.56)

finn = ~ (Hf - fH)mn Heisenberg's dynamical

coordinates standing 1973.)

theory was put together out of a belief that the

variables

of atomic physics

and momenta

represent

in the classical

of the correspondence

sense,

relations.

something

and out of an under-

(See Heisenberg

He was also able to assume that, transcribed

quantum amplitudes,

the hamiltonian

would still be of use. classical triumphs

hamiltonians

functions

It is the micraculous

from classical physics

clothed in new mathematics

particles

may be much greater,

classical

physics will tell us what to write down.

The difficulties

And the theory was ill-adapted

variable

to computation.

failed to derive the Balmer formula; mechanics

of

original paper it is not at all clear what the

That was clarified gradually

of hard work.

and properties

for there is no reason to think that

quantum amplitudes mean or how a dynamical

months

of

that has led to the

of the future theory that will explain the structure

states at once.

in Mehra

into his new

effectiveness

of atomic theory in the last half-century.

In Heisenberg's

other than

Heisenberg

Pauli accomplished

In the next year Schr~dinger

and shortly afterward

can refer to two

in the next few years. tried and

it in several

invented wave

showed that it is mathematically

218 equivalent with matrix mechanics where the two overlap. for physical

systems

having a continuous for example--but erative motions

that can be described by coordinates range of variables--the

situations

involving

of many particles

They overlap and momenta

r, O, # of atomic orbitals

spin and isospin or the coop-

are usually treated by matrix

methods, which are in principle more general.

Problem 6.1~.

Assuming

that Heisenberg's

quantum amplitude

the matrix element <mlxln> , verify that the equations

Xmn

involving

is

this

quantity derived above are in fact correct. I°

Problem

6.20.

Show that the nondiagonal

are zero for the harmonic

oscillator.

Problem

constructed

6.21.

Heisenberg

as the expression argument,

the commutation

of the old quantum condition

new quantum amplitudes. quantum mechanics

(6.45)

In order to appreciate

start with the commutation that you need,

(px - xP)mn

elements

relation,

(m ~ n)

relation

(6.50)

in terms of his

the subtlety of the plus anything else from

and derive the old quantum condition

from it. Shortly after Heisengerg's to generalize

(6.S0)

to include

paper, Born and Jordan 11

showed how

the off-diagonal

as well,

elements

[xp - px)mn = i ~ m n The theory was then complete could solve or approximate of degrees of freedom. and detailed structure

in that if one worked hard enough one

any dynamical

It is natural

of Poisson brackets.

fundamental

discussion,

Jacobi

i0

to ask whether the more complex

This turns out to be the case.

Pauli 12 has shown that if one defines

structure of Poisson brackets

identity and postulates

all of classical

dynamics

Having established

actually

system with a finite number

of classical mechanics can be constructed

a knowledge algebraic

'

xx

M.Born and P.Jordan,

12

W.Pauli,

In a

the

an equation of motion of the form (4.57~

can be derived.

this

from

by means of (4.63) with the

we can verify that X_~ and X_ m ~ are

t h e same i n t h e c o r r e s p o n d e n c e Nuov.

(6.57)

Zeits.

cim. I0, 1176

.

.

limit.

f/l

See '~1~.~'2).

f. Physik 34, 858 (1925) (19S3), Sec.

2.

219

6.6

M a t t e r Waves In 1923 de Broglie :3 p r o p o s e d the existence of m a t t e r waves,

derived the r e l a t i o n b e t w e e n w a v e l e n g t h and m o m e n t u m by a relativistic argument,

and p r o p o s e d experiments by which the hypothesis

checked.

We shall not follow his arguments here, but will instead

could be

show some connections with what we have already done. The p r o p a g a t i o n constant k of a matter wave is given by

k = ~-~p = {~m~-2[E-

and the p h a s e change a l o n g an e l e m e n t of p a t h d~ = ~ - 1 ( p ' d r

so t h a t at

(6.58)

v(r)]} ½

- Edt)

dr a n d a t i m e d t

is

E = ~

t h e p h a s e c h a n g e i n g o i n g from a p o i n t

r ° at

t o to a point

r

t is r, t

A¢

i

= ~-I

(p.k

- E) dt

roJ t o

integrated natural

a l o n g the n a t u r a l

path,

path

we c a n r e p l a c e

connecting

E by H ( p , r )

r ° and r.

Since

it

is a

and

rj t

A¢ = ~-1

= ~-lW(r,t)

L(r,r)dt

(6.59)

Jro to where the n o t a t i o n a function

reflects

only of the

approximation,

the

fact

end p o i n t

a de B r o g l i e

that

of the

W is

(for

a given

integration.

wave o r i g i n a t i n g

at

ro,

r ° and to)

Thus, i n t h i s t o i s g i v e n by a

"wave f u n c t i o n " ~(r,t) where a i s

= a(r,t)exp

some s u i t a b l y

phase-integral but here if

W is In

mechanics provides (6.5a)

under contact used.

general

still:

complexity is

(6.34)

that

described

L. de B r o g l i e ,

This

though there

(6.60)

- Et]

is nothing

f r o m t h e wave e q u a t i o n

mechanics plus

no ~ , that

transformations. In

i [SCr)

de B r o g l i e ' s

but the i n S e c . 1.1~ hypothesis.

must be such a c o n s t a n t

as a p h a s e .

we h a v e n o t e d

to a complete oscillation dinates

derived

from c l a s s i c a l

t o be c o n s i d e r e d

= a(r,t)exp

chosen amplitude.

approximation

derived

Classical

i W(r,t)

the phase

integral

J is

Thus t h e a d v a n c e i n p h a s e

of the

system is

independent

we h a v e t h e s t a t e m e n t

t h e same a p p l i e s

177,

corresponding

of the coor-

of a hypothesis

more

to a system of arbitrary

by a n y n u m b e r o f v a r i a b l e s , Comptes r e n d u s

invariant

107,

148

not just (1923).

the three

220

that occur in (6.60).

In its full generality,(6.35)

in any number of canonical

coordinates.

describes

a wave

The wave is a wave in q

space, which only for a single point particle

coincides with the x, y,

z of ordinary space. Stationary

Phase

Let us suppose

it has been possible

equation and determine

the principal

to solve the Hamilton-Jacobi

function W(q,e,t).

From what

has been said above it might appear that W/~ is the phase of the wave function of the corresponding corresponds constant, consider

quantum system, but in fact the phase

to a new characteristic

which we shall call U.

function,

first the time-independent

(6.61)

in Sec.

5.7.

to the phase of a t i m e - i n d e p e n d e n t

is Seen if we consider distribution

to

- 8n~ n

where the 8Vs and e's are those introduced corresponds

from W by a

case, for which we define

U = S(q,~)

quantity

differing

It will be most convenient

a wave packet characterized

That this wave function

by a narrow

of the ~'s,

~(q) = ; A(~)ei~-lUdf~ where tion

df~ = dalda2...da f

and A ( a )

for

centered at ~n as in Fig. 6.4.

Figure 6.4.

is the condition

for stationary

function ~(q) will differ appreciably of the phase with respect ~U

~(~ n

or

each a n represents

The condition

a distribu-

for constructive

Distribution in A (~n) that forms a wave packet.

interference derivative

(6.62)

o~ n

=

"~ n

=

0

phase, Sec.

1.2.

The wave

from zero only where the to each ~n is zero.

n

=

1,

...

f

This is

221

~S "~ as in (5.57~.

We see that

satisfies Jacobi's

n

Sn

(~ = ~ ' = n n

(6.62) represents

a wave packet whose center

equations.

In classical dynamics, with

(5.57) satisfied,

a variation in U is

given by @S

6u

=

~qn ~qn

~S + ~

~en - S n ~ n

~nSSn

-

or

6U = ~BS n

6qn - an~8 n

Thus U is conveniently regarded as a function of q and 8 with BU The difference

~S

~U

in meaning between U and S is clear when we remember

that the e's correspond to conserved dynamical variables and the 8's to initial positions

in q space.

Thus S, with given values of the e's,

allows one to calculate families of orbits corresponding to different initial positions,

whereas

U, with given initial positions,

to calculate families of orbits corresponding the e's.

allows one

to different values of

It is the interference between different members of these

a-families

that creates the wave packets.

We now see why the speed of a light signal in (5.91) came out to he the group velocity, and Wheeler

and it is for this reason that Misner, Thorne,

(1973) refer to the Hamilton-Jacobi

"condition for constructive

equation as the

But note that what has

interference."

been done here is in no sense a mere extension of the Hamilton-Jacobi theory or an alternative way of expressing the argument, introduced an idea that

is entirely new to mechanics,

of superposing waves to form a wave packet.

for we have

the possibility

Though this is a funda-

mental feature of classical wave theories it makes no sense at all within the framework of classical mechanics. Hamilton-Jacobi mechanics

The assimilation of

into a wave theory depends on two entirely

new ideas, superposition of wave amplitudes

and introduction of a

universal constant having the same units as S. of Hamilton's

From the publication

first paper "On a general method of expressing the paths

of light,

and of the planets, by the coefficients

function"

(1833) to de Broglie's

tentative

because it still lacked a wave equation,

of a characteristic

hypothesis,

took 90 years.

rather useless From the

222

W r i g h t brothers

Problem 6.22.

to the moon landing Show, by adapting

that it is impossible corresponds and 8n"

standard methods

and definitions,

to form a wave function of the form

simultaneously

to arbitrarily

What "indeterminacy

Problem 6.33.

took 66 years.

principle"

How does one change

that

(6.62)

narrow distributions

of

n

results?

(6.62)

so as to produce

a time-

dependent wave function? 6.7

Construction

of a Wave Function

The difficulty with a wave function

like

only to the natural paths of the particles that waves

diffract

(6.64)

is that it refers

described,

whereas we know

and do not follow the natural paths

following

argument,

principle

of superposition

functions

out of action integrals

exactly.

The

due to Feynman, I~ shows how one can use the to construct

true quantum-mechanical

evaluated

along paths

wave

that are not

natural. To find the wave amplitude

at r in Fig.

6.5, Huyghens'

principle

A

[ Figure 6.5

r

The amplitude at r is found by coherent from the slits.

states that one must superpose r via the different

slits,

superposition

of contributions

the rays that have travelled from r ° to

each with its proper phase.

Assuming

that

we know the wave function to the left of the grating, we construct the amplitude the slits,

at r at time t as the sum of amplitudes

contributed

by

the ith one being i ~Wi(r,t)

C6.63)

aiwbi(r)e

*~ R.P.Feynman,

Revs. Modern PhFs.

20, 367

(1948).

223

amplitude

where a i is the slit width,

at slit i from the source at ro, w is the

and

!W.(r,~ wbi(r)e ~ * is the amplitude,

together with its proper phase, produced

time t by a wave of unit amplitude arriving at the slit. b. involves

the inverse-square

do not know it a priori. of course,

Hamilton's

law and some obliquity

at r at The factor

factor,

It must come out of the theory.

principal

function

evaluated

but we

Wi(r,t ) is,

along the natural

path from the slit to r. The role of the barrier was to allow us to discuss tion to the amplitude different grating, of Fig.

points

at r made by Huyghens

along the plane of the grating.

all points of the plane 6.6.

the contribu-

wavelets originating

contribute,

If we take away the

and we have the situation

at r is not just that contributed

The amplitude

at

natural path from r ° to r, which is a straight

by the

line.

.A !

r

X

'A Figure 6.6

Every point of the plane can be regarded as a sllt.

Finally we recognize

that there is nothing

plane A-A or this particular consider

set of broken-line

all imaginable paths from r

special

about the

paths.

We therefore

and r that occupy the same time O

interval.

Fig. 6.7 shows the natural path together with some of the

varied paths.

We have introduced

path is curved.

a force field, so that the natural

We must evaluate W along each path,

calculate e iW/~,"

and find some way of summing over the different paths. W differ for different paths; because ~ is small, widely,

The values of

the W/~ differ

and the terms of the sum tend to cancel each other.

Now however we make use of the stationary property slight variations The situation

of W:

for

away from the natural path, it changes very little,

is the same as in Sec.l,2 and Sec. 6.6, where we found

the motion of a wave packet by the principle

of stationary phase.

224

Only varied paths in the immediate neighborhood of the natural path contribute

appreciably to the sum. Is

X

Figure 6.7

Every path contributes to the amplitude at r.

It is difficult to carry out the sum in order to evaluate wave functions;

the problem is one of weighting and lies in the mathematical

domain of measure theory.

In spite of considerable

effort,

few calcu-

lations have been done that could not have been done otherwise,

but in

his first paper Feynman at least shewed that wave functions so constructed will be those with which we are already familiar. Consider the simplest case of one-dimensional motion, drawn in xt space in Fig. 6.8(a)

i.

The last infinitesimal

x, i~

segment of the path is

.

x, t t

L-E; X

Figure 6.8

(~) Path in one dimension represented in Lagranglan qt space. Magnified view of the end of the path.

I

(b)

shown in Cb), where the trajectories have drawn close together and only a time ~ remains before they arrive at (x,t). 15

If the wave

That wave functions might be constructed in this way was suggested long ago by Dirac, Phys. Z. Sowj~tunion 5, 64 C1933), reprinted in Schwinger 1958.

225

amplitude at p o i n t x, and time t is given by some ~(x', t -s) we can construct the amplitude at (x,t) range dx'

starting in the

at x',

: I ~(x',

~(x,t) where dm'corresponds natural

out of contributions

to w in

one contribute,

The i n t e r v a l s

(6.63).

we t a k e

are

t - E)b(x')ei~-lWdz'

now a l l

Since

b outside

only paths the

infinitesimal.

close

to

the

integral. We w r i t e

k as

(x - z ' ) e -1 s o t h a t

=½

n

(~

x') ~

-

m ~ _

- V(z)

and (x

W = L ¢ = ½ m

E

x')

2 -

(6.64)

mV(x)

It is c o n v e n i e n t to introduce ---- X

-

dx' -- -d~

Xtj

so that

~(x,t)

Since

only

O(x,t)

values

= b

I

~ exp ~i "2-~--rm~ a eV(x)]~(x

of x'

= be - i ~ ' 2 V ( x )

near x matter,

exp(

~

~

- ~,

t - E)d~

we e x p a n d i n p o w e r s

[¢(z, t - e) - ~ ~ ( x ~

~x 2

o f 6,

t

+ ... ] d~

Since

I

~e-aX2dx

=

(ITa- 1

__

(i~a-1)~

3~

46.65)

we have

I

~eiax2dx

_co

(6.66)

226

while

I

I

• =x2e~aX~dx

~ xe i aX z dx = O,

-

oo

i ~-da

"

(i~a_1

)½

(6.67)

Thus

~(x,t) = b . ~ . Expand each side in powers

~(x,t)

= b . ~ .

We get agreement

ie~

[~(x,t-~) +

~2~(x~t-c) ~x 2

of e, keeping only e°and

...] +

e:

×

in the limit

e ~ 0 if

b = (2-~e) ½

(6.68)

The first power of e then gives

which may be familiar. The mathematical Feynman,

method is not familiar.

"One feels," wrote

"as Cavalieri must have felt calculating

pyramid before the invention of calculus."

the volume of a

Wiener had done something

along the same lines in the 1920's in connection with the mathematical theory of Brownian motion, 16 but the subject was, and remains, unknown to physicists? 7 The method's Feynman and Hibbs Insights

Gained

possibilities

are explored

in

1965.

from

Huyghens'

Principle

What has been done here is very important, far the most direct route from the equations the Schr6dinger

largely

equation.

for it furnishes

by

of classical physics

to

There are certain cases in which this

z6 N.Wiener, J.Math. and Phys. 2, 131 Revs. Modern Phys. 33, 79 (1961).

(1923).

See also S.G.Brush,

1~ A clear and detailed review, with extensive literature references, is D.I.Blochintsev and B.M.Barbashov, Soy. Phys. Uspekhi 15, 193 (1972). See also J.B.Keller and D.W.McLaughlin, Am. Math. Monthly 82, 451 (1975).

227

directness

is a great advantage,

prescriptions unambiguous equation

for "quantizing"

results.

An example

An equation of motion, interpretive

apparatus, density,

however,

(1965).

commutation Feynman's

The mathematics

The interpretation

apparatus

of

are derived in Yourgrau

is a momentum,

generalized

and

and Mandelstam

and the

(1968).

to include the dynamics is, so that physics

royal road of hamiltonian mechanics.

theory leads in a straight

the

I~I 2 as a

are given by Feynman and

any more than Schr6dinger's

needs Heisenberg's

One needs an

is done somewhat more generally

theory is not readily

spin and isospin,

is not a theory.

the proof that <-iN3/~x>

relations

of Schrodinger's

and one needs to be able to generalize

other parts of the interpretive Hibbs

theory do not yield

is the establishment

laws to new situations.

probability

in cases in which the usual

,8

in a curved space.

dynamical

notably

a classical

of

still

But Feynman's

line from the Hamilton-Jacobi

theory to

the wave equation and shows where and why ~ comes in, and with it we have succeeded classical

Finally, In Sec.

the argument of Sec. I.i, in which

there is an interesting

2.6 we expressed

Hamilton's initial

in reversing

theory was derived from the quantum theory.

principle,

question of physical

the equations

which states that of all paths connecting

and final states in qt space, that actually

one which minimizes

the action integral.

as a purely mathematical

prescription

a question of the general

followed

is the

This can of course be taken of motion,

sense one inevitably

encounters

form "How does the system know which path

gives the least action if it tries only one of them?" leaves

given

for finding equations

but if one tries to give it a physical

dynamics

content.

of motion in the form of

this question unanswered,

Classical

but in the light of this

discussion we can say that it tries all of them, and that the natural path emerges as a result of the property Problem

Show by considering

6.24.

that the integral of (6.66) be justified?

Problem 6.25.

Derive by Huyghens'

free particle moving

the area under successive

converges.

the derivation

of stationary phase.

What about

principle

(6.67)?

loops, How can

the wave function of a

in a unit circle starting with an arbitrary

(X,to). S o l u t i o n . 18

There is

natural paths leading ,8

a trick

here,

for

t h e sum o v e r a l l

possible

to x includes not only paths in which it moves a

For a recent discussion ( 1 9 7 2 ) ; 24, 980 ( 1 9 7 3 ) .

see K.-S. Cheng, J. Math.

Phys. 13, 1723

228

short distance

from x' to x b u t

also those in which it travels a whole

number of times around the circle in going from x' to x. corresponding

to n revolutions

and ~(z,t)

is

= 2 mX e

Wn

= b

~ n=--eo

The action

(x + 2 ~ n

12~e

i~-IWn(x)

- x') ~

~(xv,t-e)dx

'

0

Now show, assuming

that ~(x',t-e)

is single-valued

on the unit circle,

that

*(x,t)

and complete include the W

= b

I ~

the calculation. n

for n~

O?

im

exp[2--~ (x - x ' ) a ] ~ ( x ' , t - e ) d x

'

What goes wrong if one forgets to

CHAPTER 7

THEORY OF PERTURBATIONS

The number of calculations either

in classical

or in quantum dynamics,

the number of useful results part of physics, imations,

that can be carried out exactly,

so obtained

engineering,

and dynamical

and the worst difficulties

problem are no longer separable. corresponding

problem

but the resulting

is comparatively

is even smaller. astronomy

involves

arise when the variables

approxof a

What one hopes to do is to find a

in which not only are the variables

differential

small and

The greater

equations

separable

can be solved exactly,

and

then move from the solved problem to the unsolved one by a systematic procedure

of approximation,

The procedures in somewhat

usually

involving

analogous

fashions,

very far since what is observable

theories.

An astronomer,

for example,

in the sky and has less interest an

electron's

in series.

can be carried out

but there is no use in pursuing

comparison

physics

expansion

in quantum and in classical mechanics

position

wishes

differs

the

in the two

to calculate positions

in knowing energies,

whereas

in atomic

is not an observable while its energy

is. Because astronomers' cal theory of perturbed

need for precision

the most eminent mathematicians Because alone,

and our discussion

ous situations 7.1

subject we shall mostly leave it

of the classical

theory of perturbations

to examples which throw some light on analog-

in quantum mechanics.

Secular and Periodic

Perturbations

To someone who has encountered mechanics,

the classi-

in history have had a hand in it.

it is a very specialized

will mostly be confined

is very great,

orbits has been carried very far, and many of

perturbation

theory in quantum

it might seem quite obvious how to proceed

in classical

mechanics.

Let us say that we wish to calculate

the perturbation

the Earth's

orbit by the action of Mars.

that the perturbing

force or energy carries

Assume

of

a factor e and write the Earth's position as

r(t) = ro(t ) + erl(t ) + eZr2(t ) + ... put it back into the equations of the same order in e. perturbation

of motion,

and gather together

In this procedure

terms are small,

that

lerll

not so, since even a small perturbation,

terms

it is assumed that the

~< Irol , but this is just if allowed to run long enough,

will finally bring the Earth to a point very far from where it would otherwise have been.

230

To see what happens let us use perturbation of a harmonic changes

oscillator

the stiffness

(if the amplitude

if one disregards

this warning

theory on a trivial problem,

by the addition of another spring that

k to k + e and the frequency

is fixed)

the oscillator's

x(t) = asin(m

asin~t + ...

increase without

ment remains bounded.

It is spurious

limit, whereas

of course

because

the displace-

To get a finite result we must sum an infinite

number of terms of the perturbation can be done in another simple Anharmonic

(7.2)

+ ...

is called a secular perturbation.

Ix - xol

Then

becomes (7.1)

= Xo(t ) + ¢a~itcoset

it has

to ~ + e~ I.

displacement

+ eml)t

= asin~t + E ~ I ~

This result

and proceeds,

the p e r t u r b a t i o n

series

in ¢.

Let us see how this

example.

Oscillator

The example

is a harmonic

oscillator

force so that the equation of motion

perturbed by an anharmonic

is

+ ~02x

= cx 3

(7.3)

If we try to solve this by letting X = X 0 + 6X 1 + £2X 2 + ... we see how the secular perturbation 2

..

2

2

""

(7.4)

arises: 2

3

2

XO + ~oXo + E(Xl + ~OXl ) + ~ (X2 + ~oX2 ) = £(XO + 3gxoXl + " ' ' ) whence Xo + ~ 0 2 X o

= O

xl + ~02xl = x03 x2 + ~oZX2 = 3 X o 2 X l etc.

The first equation has a solution x 0 = asin~ot

Then the second equation

is

(7.s)

231 ~i + ~02Xl = a3sin3~ot

this equation without knowing

If we encountered judge

= % a3(3sinmot

it to be the equation of a harmonic

force having a Fourier component The resonance would transfer tionally

to t (Prob.

oscillator

an ultimately

amount of energy

would ultimately

increase propor-

7.1).

that the frequency

(7.1)]

driven by a

divergent

To get out of the difficulty we suppose example

its context we would

in resonance with the oscillator.

and its amplitude

to the oscillator

- sin3eot)

changes

[as in the primitive

from ~0 to m, where

~02 = ~2 + el I + e212 + ... and choose l I so that the secular perturbation

vanishes.

(7.6) The terms

through e 2 are given by

Xo + el41 + e2x2 + (~2 + et I + e 2 1 2 ) ~ 0 + ex 1 + e2x2 ) = e(Xo + eXl)3 Suppose we require

that 2(0) = o

x(O) = a, The

zeroth-order

(7.7)

equation

of w h i c h the solution

(7.7)

from

that satisfies

(7.8)

is

C7.8)

is

X 0 = aCOS~t The next equation

is

~i + ~2Xl

= -llXo

+ X03 + % a3(3cos~t

= -llacos~t and the resonant

secular

term cancels X1

The remaining

=

if

$ a~

(7.9)

equation Xl + 0°2Xl = % a3cos3oJt

has a solution

+ cos3~t)

(7.10)

232

xI

= ~

G

3

[cosmt

-

cos3mt)

(7.11)

which when combined with x o is consistent with the boundary (7.8).

condition

The frequency we have found is

= (~02 - e~l)#= ~0(I -

S~l 3~a 2) ) = ~0(I 2~02 8~02

(7.12)

and the solution so far is £a 2

xCt)

The secular

= act

~

~a 3

+ 3--~-~T,cosmt - ~

term is gone and only periodic perturbations

see the origin of the word anharmonic: the amplitude

of swing.

series because

of this kind occur in quantum mechanics;

examples are in the theory of many-body interacting

fields.

We

in e, but in fact if we were to expand

of e it would be an infinite

Difficulties

remain.

the frequency now depends on

In one sense we have stopped after the first

term of the series expansion x(t) in powers

e.

(7.13)

cossmt

m contains notable

systems and in the theory of

The method used here is there called "summing

an infinite number of diagrams,"

and is necessary

if finite results

are to be obtained. Problem ? . 1 . frequency m.

mr

Find

the

Problem 7.2.

(7.11)

A series

L-C c i r c u i t

= (LC) -½ i s

i(t)

current

driven when

Find the general

(no by

resistance)

a sinusoidal

m < mr,

m = mr,

with

a natural

voltage and

of

frequency

m > mr -

solution of (7.i0) and verify that

is the right solution to choose.

Problem ?.3.

Look again at (2.27) and verify that the results of

Sec. 2.3 agree with those obtained here. Problem

?.4.

Problem ?.S.

Find the next terms in e in the example Discuss

is very slightly 7.2

the motion

damped with a force proportional

Perturbations

the calculations

we ask are easier:

if it

to ~.

a wave function,

are easier because

though the oscillator

physics may end up far from where perturbation,

oscillator

in Quantum Mechanics

In quantum mechanics questions

of the anharmonic

above.

the

in classical

it would have been with no

in a nondegenerate

little changed by a small perturbation.

state at least,

We expect an expansion

in

is

233

powers of e to go through, perturbation

correctly.

and it does,

if we handle the secular

It is easy to arrange things so that the

danger of secular perturbations

is not in evidence;

this is what is

usually done, but we shall be a little more naYve here. The problem

to be solved is i~ ~

where,

= (H 0 + eV)~

(7.14)

in general H 0 and V are both operators,

moment t h a t

V is independent

been possible

of time.

and we assume for the

We assume also that

to solve the unperturbed

it has

problem to find the stationary

states, ~ n (°) i~ ~ Ot

(o) = HO~ n

(0)

(7.15)

= En~ n

~n (0) = ¢n e - i K - I E n t

We identify

the state sought by saying that it is to be that state

which in the absence of the perturbation the unperturbed

stationary

Let us assume t h a t

would coincide with one of

say ~a (0).

states,

the spatial part of ~ can be represented

by

a sum

~a + where c

that

n

Cn¢ n

(7.16)

is of order e, but that the time dependence,

of ~a'

i s changed by t h e a d d i t i o n =

(7.14)

instead of being

o f an e n e r g y At:

, . .ei~ -I + AE) t (Ca + I Cn@n) (Ea

where the prime indicates this into

E

n~a

that the term n = a is omitted.

(7.17) Putting

gives

(E a + A E ) ( ~ a + E ' C n ¢ n) = E a ¢ a + Z ' C n E n ¢ n + eve a + eE'CnV¢ n

or AECa

Now multiply

+ 2'(E a + At - En)Cn¢ n =cV¢

by Cm* and integrate.

At = ~<~Ivl~>

a + eE'CnV$ n

(7.18)

If m = a,

÷ ~Z'c <~IVln> n

(7.19)

234

where the matrix element < a I V l n >

is defined as

(7.20)

= I ~a*gCndX

TO o r d e r ~, perturbation

(7.19) gives the familiar of energy, AE

To c o n t i n u e , we r e t u r n and i n t e g r a t i n g w i t h m ~ a : (E a +

Cm = E

AE

e

=

to

- Em)C m

(7.18),

=

formula for the first-

+

O(e 2 )

this

£ <mlVIa>

+

time multiplying

by Cm*

eZ'Cn <m[Vln>

e - E (<mlVla> + Z ' C n <m]VIn> ) + AE m

a

order

(7.21)

m ~ a

All these relations are exact, and they form the basis for an iterative evaluation of AE and cm .

For example, using the first term of (7.21)

in (7.19) gives

AE

=

e

+

¢2

~, n

+ AE - E

E

a

+

(7.22)

"'"

n

and further terms may be written by inspection.

The only difficulty

with the application of this formula is that it contains AE implicitly and must be solved for it, but this expansion is simpler to write down than the usual expansion in E that contains AE only on the left-hand side.

It was first given by L~on Brillouin in 1933. As in the discussion of classical perturbation theory,

not really an expansion in e, since the expressions

this is

(7.17) for ~ and

(7.22) for AE contain all powers of e, but it achieves a formal simplicity beyond that of the more conventional Schr~dinger perturbation theory precisely because it goes to the root of the problem of secular perturbations.

Although the problem solved in this way can

be dealt with otherwise in other forms of perturbation theory, most forms of the quantum theory of fields require the correction to the frequency to 5e made explicitly as we have done here.

The process by

which this is done is known as renormalization.

Calculation

of

Perturbed

Wave

Functions

If we use the first term of (7.21) to calculate a "first-order" perturbation to the wave function, we have

235

Cm

=

~

+

AE

-

<mlVla>

E

a

0(e 2)

+

(7.23a)

m

and

<mIvl=> + AE

¢ = ~a + A¢,

A¢ = e E' E m

Sometimes

- E

a

only a few of the matrix elements

~m

(7.23b)

m

are different

<mlVla>

zero and the sum is easy, but sometimes

it has many terms and,

addition,

in the form of an integral

it may involve

a contribution

from a range of energies this reason the solution H^ 0

- Ea

E

in w h i c h

m

it is often convenient of a differential

the spectrum

equation.

Multiplying

- AF)A~, = -~

z' <mlVl=>% : -~(Z ~ l v l a > m

to

by

as

of V~ a in terms of ~m' so with

in (7.22),

(~1 o

The quantity

Cm - % )

m

The sum is just the expansion --

(7.23b)

For

of A¢

AE gives

(#o - z

AE

is continuous.

to reduce the determination

from

in

Ea -

)A¢

on the right

involves

In the ordinary o n e - p a r t i c l e

= -e(V-

)¢

(7.24)

a

only the unperturbed wave function.

Schr6dinger

equation,

where

2 V2 + V o ( r ) ~^o = - 4~-~

it is useful

to write

A{ = E X ( ~ ) ¢ a ( r ) A short calculation

-

then shows

~2 ~-~ [ v 2 x

that X satisfies

VCa'VX + 2 - - ]

- <=lvl=>

(7.25)

x = -v + <=lvl=>

Ca

T h i s may be r e a s o n a b l y Problem

7.6.

Show that

easy t o s o l v e , (7.19)

is, in an obvious notation,

A~ = ~ ( < a I v i a >

Problem

first-

?.7.

Find the first-order

and second-order

oscillator p e r t u r b e d

perturbed

+ )

perturbed wave function energies

by an interaction

~x ~.

and the

of a simple harmonic

236

Problem

Using the method just explained,

7.8.

find the lowest-order

correction to the ground-state energy and wave function of a hydrogen atom in an electric field F. Problem

Show that if AE is smaller than all the energy differ-

?.9.

ences E n

Ea,

the implicit equation

(7.22) can be solved for AE to

give, to third order, an expansion for AE:

-

< IvIn>_ + n

m n

+

a

(Em - E a ) ( E n - E )

m

(Em _ Ea) 2

]

...

(7.26)

This series in e is the original perturbation expansion given by SchrSdinger in his earliest papers.

The second p a r t of the third-

order term is called the wave function renormalization

term.

Such

terms appear in increasing profusion when the series is carried further (though,

7.3

in practice,

nobody does).

Adiabatic Perturbations In this section we shall compare the classical and quantum

theories of a perturbed bound state, tive result.

in physical content and quantita-

The physical content of the quantum perturbation theory

is clear, especially if the unperturbed state is nondegenerate:

a

bound state is defined by a potential energy and the usual boundary conditions

at infinity.

One tries to alter the known solution of a

problem similar to the one in hand in such a way that the eigenvalue equation is satisfied approximately and the boundary conditions exactly.

If the unperturbed state is degenerate,

set of stabilized eigenfunctions

one determines

a

in a way which is explained in texts

on elementary quantum mechanics and it is these that are altered by the perturbing potential. is not so clear, met,

The physical sense of the classical theory

for there is no criterion for a stationary state to be

and any number of states of roughly the same energy could be

taken as the effect of perturbing a given unperturbed state.

We need

a criterion by which "the" perturbed state corresponding to a given unperturbed one may be defined. The criterion if found in the adiabatic principle:

let us

consider the calculation not as a certain expansion in powers of e but as the a t t e m p t miraculous,

to find out what happens if by some means, physical or

the perturbation is established very slowly.

The adiabatic

237

theorem (Sec.

6,3 ) t h e n s t a t e s

that

S = J~pndqn : ~ p n q n d t remains constant in generalized

in value.

coordinates

It follows

Suppose that

initially

addition

2~[E(t)

- V(t)]dt

t h e e n e r g y was Eo, a c o n s t a n t ,

Then g r a d u a l l y

of a perturbing

of energy

that this is

S :

e n e r g y was V0 .

from the definition

the potential

Vl(t ).

Then t h e c o n s t a n c y

Vo :

Eo

~-

~o -

and the potential

energy is

c h a n g e d by t h e

of S implies

that

Vz

or

E: As long as V 1 is changing, that V 1 stops changing

the constant

EO + VZ

E varies during a cycle, but if we imagine

when it reaches

the desired value, ~ becomes

energy of the system, E = Eo + F1

(7.27)

This very much resembles

the first-order

for we have seen in Sec.

6.4 that expectation

mechanics theless,

correspond

to time averages

of energy is obtained

the unperturbed

ing the perturbation? quantum-mechanical

mechanics.

if the average

If the perturbing ly modify our earlier

Never-

V is computed using Is the perturbed

also the result of adiabatically

establish-

This can be answered when we have found the

description

Adiabatic Transitions

in quantum

limit, while the first-order

rather than the perturbed motion.

energy in quantum mechanics

(7.17)

in quantum mechanics,

values

in classical

(7.27) is exact in the adiabatic

perturbation

replace

formula

of adiabatic behavior.

in Quantum Mechanics e n e r g y V d e p e n d s on t , treatment.

we s h a l l

have to slight-

S i n c e 5E now d e p e n d s on t ,

we

by

= (Ca + X ' C n ( t ) ¢ n ) e - i ~ - l j ( E a + b E ) d t Substitution

into the wave equation gives

(E a + AE)(Ca + Z'CnCn) + i~E'enCn = EaCa + Z'CnEnCn + eV¢a + eZ)CnVCn

238

or AE¢ a + E ' (E a + AE

- En)Cn~ n + i~E'Cn~ n =

~V~a

+

g~ I cnV~ ~

From this we get as before

AE(t)

=

e

+ eZ'c

n

(t)


(7.28)

>

while if m ~ a, i~c m +

Em)a m = E <mIV(t) la> + Z'an<mlV(t) ln> (7.293

(E a + h E ( t )

If we calculate Cm only to the first order, i~c m

+

(E a

t =

-~;

V(t)

= eYt~,

(7.30)

~<mlV(t)[a>

Em)C m =

Now let us suppose that V(t)

(7.29) becomes

has been turned on continuously from

where y is eventually

to become very small.

The

solution of (7.30) is

e re(t) -- - ~ i

m

which with y÷O is exactly

AE(t)

That is, nothing

=

(7.23a)

e

-

to first order.

~ 2r.'

(to second order)

The energy shift is

<mlV(t)[a> E

m

-

E

adiabatic and stationary state perturbation

function of time.

in the sense of time average and expectation value,

only to the first

The expectation value

is taken with respect to unperturbed wave functions,

the time average in (7.27) motion of the system.

is with respect to the actual perturbed

The analogy is pursued in Problem 7.13; let us

see how good it is from a numerical point of view.

Example

1.

The

for the perturbed energy correspond,

order in e, but this is not surprising. < a l V ( t ) la>

The

theories give the same

This is the adiabatic theorem in quantum mechanics.

classical and quantum formulas

(7.32)

a

is changed in our earlier result

except that AE has beocme a slowly-varying answer.

i-~

a

Anharmonic

Oscillator

The hamiltonian corresponding

H = p~+ ½ m~o2X~ + V 2m

to (7.3)

is V =

gmx ~

239

Classical mechanics An u n p e r t u r b e d motion has

Ec

Xo = ac°s~0t" The first-order

perturbation

Ec( 1 ) the bar denotes

= ½ mco 2a2

0

of energy, which

over a cycle of the unperturbed motion,

where

(05

% ~mx-T= ~s

=

(i)

3

ema

(7.33)

~

In terms of Ec(°)

a time average.

Ec

is the average of V

is

e

this

is

(0)2

(7.34)

= 8 mO~o~ Ec

Quantum mechanics E

(1)

(7.3s)

= = 3(4--k~o)~C2n2 + 2n + 1)

qn

or

Eqn

(1)

3 e ~2

8 m o~02 [(n + ½) 2 + %]

Since Eqn(O) = (n + ½)~U~O, this

Eqn The classical

(15

3

is

C

- 8 m~04 [Eqn

and quantum results

(052

+ Eqo

correspond

the zero-point

energy E (o) qo

Problem 7.10.

Calculate (7.33) and (7.3S).

Problem 7.11.

Calculate

result

in classical

(0)2]

(7 36)

at high energies where

can be ignored.

and compare the perturbed

and quantum

energies

theory w h e n a harmonic

placed in a uniform field of force.

that

oscillator

(This is a second-order

is

calcula-

tion.)

Problem 7.12.

Solve the preceding p r o b l e m

new coordinate

$ = x + ~ and choosing ~ appropriately.

Problem 7.13.

Let , be the exact solution of =

s~

and ~(o) be an e i g e n f u n c t i o n ^

~o ¢

=

of

exactly by introducing

Ho +

o

(o)

E(0) =

¢

(05

v

a

240

¢ so that 1~ *~(dx) = 7.

normalized

E = E (°)

Show t h a t

(7.37)

+ (¢(°)~V~(dx) 4

exactly.

If ~ is the state that results

tion is established close)

7.4

adiabatically,

from ~(0) when the perturba-

this is the closest

(but not very

quantum analog of (7.27).

Degenerate

States

Everybody knows that in quantum mechanics, applied to a degenerate splits. classical

state the degenerate

(We shall see below what the criterion mechanics

the situation

energy we read frequency. apparatus was developed

for "usually" the same,

is.)

In

if for

(see for example Corben and Stehle 1960)

for

but it lies beyond the cutoff of this

quantum mechanics,

is of narrow interest, A Classical

is essentially

is no longer current.

place of elementary

is

In the old quantum theory an extensive

dealing with this situation, book and moreover

when a perturbation

energy level usually

Since the subject

is a common-

while in classical mechanics

it

our discussion here will be very short.

Oscillator

We start with a nondegenerate

oscillator

in two dimensions,

for

which pl ~ + p2 2 H0 =

(7.38a)

+ ½ m(~ol2Xl 2 + t022x22 ]

2ra To this precessing restoring

system

(Fig.

7.1) we add a symmetrical

but nonlinear

force V = % e ( x 2 + y2) 2

(7.38b)

Y'1

Figure 7.1

Orbit of a harmonic oscillator in 2 dimensions. ) Degenerate case, e I = ~2"

~) el # ~2"

241

Writing

the unperturbed

oscillation

in parametric

x = asin0~l% ,

form (5.70) as

y = bsin(~2t + @)

we note that E (0) = ½m(~012a + 0322b)

independent E ~)

(7.39)

of ¢, but that E (I) involves ~:

= % e[a~sin--T~-~it + b~sin~(~2t

In the first two terms, done carefully.

sin~t

=

+ @) +

2aab2sin2mltsin2(m2t + ~)]

3/8, but the last average must be

We have to average

%{ COS2[(C~ 1 + ~02)t + £~] - 2COS[((O 1 + (~2)t + £~]COS[(~ 1

+ COS2[(~ 1 If ~ zero.

~2)t

~2)t

- ~]}

~ ~2' the first and last terms give ½ and the middle If

- ~]*

term gives

~i = ~2 the last term gives cos2@, while the other two are

unchanged.

Thus

E (z)

= % ~ [ ~3 (a" + b ~) + ~1 a262 (1 + ~1 c o s 2 ~ ) ]

(7.40a)

where

1

6 =

~i ~ ~2

(7.40b)

~i = ~2

These formal expressions different

reveal that the degenerate

from the nondegenerate

nondegenerate,

the perturbed

the unperturbed turbed motion

In the degenerate ellipse,

of the ellipse

filling curve of the nondegenerate orientation.

The existence

ing to the same unperturbed splitting

of degenerate

state is

only on the amplitudes

and hence on the energies

is a stationary

spatial orientation

case is essentially

If the unperturbed

energy depends

oscillations

the x I and x 2 directions.

one.

case,

of

associated with

in which the unper-

E (I) depends on @ but not on the

(Problem

7.14).

For the space-

motion there is no such thing as

of different perturbed energy is the classical

levels by a perturbation

energies

correspond-

analog of the

in quantum mechanics.

242

We may ask how the discontinuity continuous

analysis.

an idealization;

It arises,

in (7.40) arises out of a

of course,

only because we have made

we are willing to wait an infinite

take the time average.

time in order to

In fact, if ~2 - ~i = 2~/(I year),

say, it is

only a matter of convenience whether we say that the system is degenerate.

In this case the ellipse precesses

and whether we say it is stationary emphasize.

Whether we say that two energy levels are degenerate

depends not on the vanishing practical Problem

very slowly in space,

depends on what we wish to

possibility

of the difference between them but on the

of observing

it.

Show that in the above example

7.14.

equal and the semidiameters

of the resulting

if the frequencies

are

ellipse are A and B, the

shift in energy is E(1)

Degeneracy

=

-I~ e(3A ~ + 2A2B 2 + 3B ~)

~n Q u a n t u m M e c h a n i e e

If the unperturbed

system has several

states corresponding

same energy, we must choose the right linear conbination the unperturbed

state from which to start the perturbation

That is, if the erthogonal

time-independent

degenerate

to the

of them as expansion.

unperturbed

states are ~i "'" @d' where d is the degree of degeneracy,

we form

the linear combination d ~(o) corresponding

to the energy E (0)

~o +

~¢:

=

E i=I

(7.41)

ci~ i

Then from

(~(o) + ~(~))(~(o)

+ ~(1))

+ (v - E ( i ) ) z c i ~

i = o

we find, to first order, (H o

(The ¢ previously here.)

Multiply

E(°))~ (i)

used to distinguish

orders of perturbation

this equation by any ~j~ and integrate.

ZoiC<j]V]i>

- E(l} 6ij)

= 0

j :

1 ....

is omitted

This gives d

or, written out,

(

- E(i))o i + < l l v l ~ > c 2

+

o 3

+

....

o

243

~x

+ C<21vlz>

The condition

etc.

- ~x~)~2

+ <mlvls>~3

that there exist a nontrivial

is that the determinant

of the coefficients

I and this, with given

<51vii>

- F(x~aid

states.

Examples

I = o

hydrogen--so oscillator

d different values of

linear combinations

of unperturbed

eigenfunctions.

are found in all books on quantum

is usually the same example,

the linear Stark effect in

we shall not work it out in detail here.

discussed

above,

state are still degenerate levels

(7.42)

are known as stabilized

of this procedure

mechanics--it

solution for the o's

and unknown E (I) , is an algebraic

to d different

These combinations

are split.

Almost Degenerate

In the perturbed

the ground state and the first excited under the perturbation,

but higher energy

(Problem 7.15) Levels

It is interesting the separation

o

vanish,

equation of dth order which in general produces E (I) corresponding

+ ....

to note what happens

of the unperturbed

in quantum mechanics

levels becomes very small.

as

We

shall show by the example of a two-level

system that the transition

from the nondegenerate

case is a continuous

to the degenerate

one.

Suppose we have a system that has a pair of levels close together: H0~I and by "close"

= El0) ~i "

(0) ~2

H0~2 = E2

is meant that the difference

~2~(°)

with the energy shift produced by the perturbation. other states of the system have energies shall show that under the perturbation not degenerate,

become mixed.

unperturbed

far away from these.

V the two states,

We

even though is

~¢

the solution by a linear combination

of the two

functions, = el~ 1 + c2~ 2

Substituting

is comparable

We assume that

The equation to be satisfied

(B o + v ) ~ : and we approximate

" ~i~(°)

into the equation and multiplying

by #2" and integrating

(7.43) first by ~i* and then

gives a pair of equations

244

E + ~i ~(o) )Cl + V12c2 = 0

(Vll

(7.44) V21c 1 + (V22 - E + E 2( 0 ) ) # 2 = 0 where we have abbreviated equation

by V... zj

The resulting

quadratic

for E has the solutions

_(o)) + E = %(E z(o) + ~2 + _ _(o) (o))z + ½{Vii + V22 - [(Vii V22 + ~i - E2 + 41V1212] %} with equally In Fig.

(7.45)

long formulas

for e I and a 2. _(o) and ~2 ~(o) 7.2 we have assigned numerical values to ~i

and have taken V as proportional

to a parameter

'

h which is allowed to

ICJI

0

°

0

0 (b)

Figure 7.2

Energy levels of (7.45) and coefficients of (7.43) as functions of the strength of the perturbation. (b) Plot of the energy levels in (a) on and expanded scale.

vary from 0 to i. coefficients comparable

The energy levels

fell and

Thus in classical

and the plot of the

to the splitting

of the unperturbed

levels

mixing of states. theory from a practical

quantum theory by calculation,

Problem

do not cross,

It21 shows that as the matrix elements become

in magnitude

there is considerable

levels

l-

point of view and in

the situation when there are degenerate

is only a point on a continuum. ?.15.

Study t h e q u a n t u m - m e c h a n i c a l d e g e n e r a c i e s o f t h e u n p e r -

t u r b e d and perturbed states of the oscillator defined by (7.38). Problem

7.16.

What are the conditions

necessary

if the splitting of

245

the perturbed what value 7.5

levels

is

of X does

Canonical

basis,

formal

basis.

part the

occur?

Perturbation

The c l a s s i c a l formal

t o go t h r o u g h

this

theory

but

of perturbations

calculations

tend

We a s s u m e as b e f o r e

that

the

V(p,

q,

part

We a s s u m e I t h a t these

these

8,

as

constant

perturbed

functions

of time,

constant,

for

hamiltonian

as

V(C,

this,

t).

a very

First,

consists

handsome

the

of a soluble

a complete

qn(a,

soluble

q,

for

the

t)

8,

solution

t)

of

(7.46)

constants,

a n an d

i = 1....

dynamical

system,

and t h e

quantities

8n.

Let

the p's

that

V(p,

(7.47)

they must satisfy

and q ' s defined

HO + V) = (C i ,

suppose

2f

HO) = 0

C's, still

are by

no l o n g e r

(7.47),are

the

same

no l o n g e r

V)

q,

(7.48)

t)

has been w r i t t e n

via

(7.45)

Then ~C.

( c i , v) =

so t h a t

long.

We w r i t e

t),

are

Ci = (Ci" To e v a l u a t e

c a n be g i v e n

t o be v e r y

t).

6 i = (C i , In the

At

constants

c i = Ci(P, Considered

7.2?

p r o b l e m as

pn(a,

us c a l l

in Fig.

t h e minimum s p l i t t i n g ?

Theory

Ho an d a s m a l l unperturbed

a minimum as

What i s

(7.48)

~V

~C.

~

~C.

,.,J -

~V

~C.

~

~Pn DCj D4nJ,

~qn ~Cj ~Pn

is

6¢ = (c¢, cj) aV ~c.

(7.49)

3

where i it

is

an d j

exact

independent evaluate

of the

to

2f.

by P o i s s o n ) s

choice

The m e r i t theorem,

of coordinates

of this the

expression

Poisson

an d momenta

brackets p, q u s e d

is

that are

to

them.

Equation is

run from i

an d t h a t

if

Ci

i

See Sec.

(7.48)

has

a precise

a time-independent

5.7.

counterpart

dynamical

variable

in quantum mechanics: that

is

constant

in the

246 unperturbed

system,

then in the perturbed

d

system, A

= ~i < [ ( H ^ o + ^V ) ,

: ~i < [ ~ , c i ] > _

~i]>

(7

50)

dt

The foregoing for calculation, pertaining

equations

are all exact and consequently

useless

since the C's are defined in terms of quantities

to the perturbed

system.

But if we write

C. = C! O) + C! I )

where the C! O) are calculated

+

(7.51)

...

from the unperturbed

system,

(7.49)

becomes ~v (o)

b! l )

=

and higher approximations

(c~° ~ , "

c! °)) ~

(7

+

j

CO! o) J can be obtained similarly. .

.

.

In order to see how the formalism works out in practice, apply it first to a particularly Example

2.

simple and obvious

5z)

.

we

situation.

Perturbed Harmonic Oscillator.

Let

1 H o = ~--~(p 2 +

and suppose that the perturbation

m2~2x2

consists

) of attaching

C7.53) an extra

spring to it: V = ½ kx 2 The solution of the unperturbed

X

=

C7.54)

problem is of the form

U- (1° ) s i n m t

+

C 2( ° ) c o s ~ t

(7.ss) p whence the constants

=

mm(C O)cosmt

corresponding

u~ 2( O ) c o s ~ t )

-

to this zeroth-order

approximation

are

C1( 0 )

=

xsin~t

+

J?-- c o s ~ t mo~

(7.56)

C2(o) = x c o s ~ t

- J2_ mm s i n ~ t

There is only one Poisson bracket,

J

c2

m~

247 and it is identically

constant.

V (°)

With

= ½ kCC~°)sin~t

(°)cos~t)2

+ C2

we find for the first-approximation • (1) C1

~o) =

(C

~v(O)

^(o)) ,

U2

mk~

@O~°)

+ C 2(O)cosmt)cosmt

(C °)sin~t

@v(O) k

i

"

Let us assume

~2

that the perturbation

Then for t > 0, we integrate C(Z) 1 = - ~ k

C~I) = ~ k

the perturbed

cosmt)

~(o)

This shows

the secular

represents method

part of a cycle,

the perturbation

is cumbersome

this problem

Perturbation 1918,

Brouwer

(I

of the oscillator

to

phase by

in k it correctly

(Problem efficient

simplicity

is the basis 1961).

perturbations

of celestial

7.17).

The

approach

makes

to

it valuable

Its principal

difficulty

in the solar system

arising

from resonances.

orbits

the Sun exactly

that when Jupiter times, since

there actually

and the resonance

of energy between

mechanics

is in the

are secular perturba-

produces

It happens, 5 times,

for

Saturn

a much larger

the two than would normally

the force

(Plummer

such as we have just encountered;

tions

so, it is small,

will not continue

situations.

and Clemence

it 2.0134

(7.57)

but to first order

since

exchange

0.

sin~t)

the oscillator's

is the more difficult

orbits

=

C (0) + C (I)

sin~t

and obviously

has changed

2, but its formal

theory

of secular

k 2rao-----T

kt 2m~

this

example,

t

cosset)]

-

by substituting

x(t)

and we have seen a more

in Chapter

in more complicated

avoidance

perturbation

after the perturbation

an appreciable

+ u. ( 2o )

~(O)(cos~t + u2

- uI

be valid

at

in (7.55), we find

= C(°)(sinmtl +

xCt)

established

+ 2C °)cot + 02~(O)sin2~t]

~t - C °)sin2~t

If now we evaluate for the C£°l's

was suddenly

to find

[u~(0) I (] - cos2(0t)

[2~(O)u 1

+ c~(0) 2 cos~t)sinmt

(C °)sin~t

mto

B~ 1

occur.

is weak and the periodicity

Even of the

248

resonance

is 880 years.

To obtain the accuracy

required

or the space program requires very long calculations, are mostly simple in principle, will

in astronomy

but the methods

as the example in the following

section

show.

Problem

2.17.

Carry out the calculations

leading to (7.57) and show

how the result is related to the exact solution. Problem

2.18.

Find a way to eliminate

the secular t e r m s

in evaluating

the C i(i) , and verify the result by an exact calculation. 7.6

Newtonian Precession The general-relativity

precession

precession

of the orbit of Mercury

largest part is accounted

is only a small part of the

as viewed from the Earth.

for by the precession

system used, which is tied to the slowly-changing Earth's

axis and will be evaluated

be discussed here,

is contributed

and the part a t t r i b u t a b l e

in Section 8.5.

essentially

direction

Another part,

to general

relativity

is only the residue

from the observed value.

two coordinates

and two momenta,

but it is convenient

to give a and the two components

A, since by (2.93), A = ye.

The direction

A

e.

For this

of the Laplacian

integral

of A is given by @a'

7.3, and @ao is the value of @a at the time t = 0.

F i g u r e 7.3

to

We first define the orbit by the magnitude

and direction of its major axis a, and its e c c e n t r i c i t y

Fig.

to

the m o t i o n of a planet we need four numbers,

choose them as follows. is suffices

of the

by the action of the other planets,

after the others have been subtracted To characterize

The

of the coordinate

In the

_

~ l g l e s and c o o r d i n a t e s f o r c a l c u l a t i n g Mercury by t h e a t t r a c t i o n of. J u p i t e r .

the perturbation

of t h e o r b i t

of

249

absence

8a would remain

of perturbations

to calculate

its rate of change.

constant

at @ao; we are going

To locate the planet

in the orbit

thus defined we assume that at some time t = t o the planet was at aphelion, initial

and measure

direction.

its subsequent

The planet's

displacement

position

relative

to that

and motion can be calculated

from the four numbers

a, To calculate

A x,

Ay,

the Poisson brackets

to

(7.58)

in (7.52) we need a set of

coordinates

and momenta.

convenience

and does not affect the result,

is only a matter

of

but the calculation

is

Which ones we choose

very short if we remember

the view of the Hamilton-Jacobi

that was taken in Sec. 5.5, in which the characteristic taken to be the generator coordinates mass

of a contact

transformation

8n and momenta en with constant values.

is set equal

to i, they are

(Problem

C~l = E = - -Y-2a

~2

~z

82 =

function

is

to a set of If the planetary

7.21)

L

=

equation

[ya(1

=

- e2)] ½

(7.59)

In

=

to

-

the unperturbed

evaluate

OaO

system the components

of A are constant;

we

them at time to:

A x = -yesinfl2, and the other variables

a

=

-

are found from

We can now calculate

(Ax, Ay

(7.59):

2 e2 = I + ~

2al,Y

the required

)

=

(7.60)

Ay = yecos82

8Ax 8Ay 8fl----28a 2

~i~2

brackets

3A~

~A

z

I

= --X~ (Am2 + Ay

(7.61)

almost at sight:

x _

382 ~ 2

2)

2&l&2

(7.62)

or

(Az, Ay)

= ~

[¥a(I

-

e~)] ~

(7.63a)

and similarly,

(a,

to)--

2a2

Y

(7.63b)

250

(Ax"

to)

=

a ( 1 - e 2) A ye2 x

(7.63a)

(Ay,

t o)

=

a(1~e2- e 2) A y

(7.63d)

(a, Ax)

=

The largest perturbation Jupiter.

Figure

(a, Ay)

=

0

(7.63e)

of the orbit of Mercury

7.4 shows the situation.

is created by

We assume that Jupiter(~+)

Figure 7.4 Angles and coordinates for calculating the perturbation of the orbit of Mercury by the attraction of Jupiter. moves

in a circular orbit of radius a 2 with an angular

while Mercury perturbing

(~) moves

in an ellipse

characterized

frequency

~2'

by a I and e I .

The

energy is

V

=

- ~6

6

In terms of the orbital variables

=

(7.64)

Gin.,,

this contains

1 I

= [r12

_ ~rlalc°se

= ~ az nZ__O

+ a22] ½

Pn(C°Se)

e = 8z

82

(7.65)

251

where t h e Pn'S a r e t h e L e g e n d r e p o l y n o m i a l s , 1 t h e e x p r e s s i o n f o r ~ in powers o f r l / a Z : = 1,

Po(COSO)

and so forth.

Pl(COS@]

= cosO,

P2(COS@)

We shall need only these

Since both @ and r I are periodic only interested simplify

in the cumulative

everything

the sum

by taking

calculated

: ½ (3C0S2@

three

I)

terms.

functions

effect

by e x p a n d i n g

of t, and since we are

after a long time, we can

time averages.

In the first term of

(7.65) we have

rl(t)cos@(t ) = rl(t ) (cos@icos@ 2 + sin@isin@2) in w~ichrlCOS@ 1 and rlsin@ 1 are periodic cos@ 2 and sine 2 have period incommensurable, the entire argument,

T 2. Since T 1 and T 2 are different and term averages to zero, while by the same

P2 (cos@)can he replaced --

:

by 3

P2 = ~ (~ -

To c o m p l e t e

the

second

term

we n e e d

of this kind are quite easily to this chapter

Thus effectively,

(7.66)

time

average

details

r12 .

Averages

are in the appendix

(1 + ~3 e l 2 ) a l

=

energy

(7.67)

2

is

(1 + 3 el2)(

al ) 2 ]

is given by the time derivative

rate of change

of

is

the perturbing

The precession

I

= ~

the

[I + :

the average

:)

calculated;

and the result rl2

in t with period T 1 and

of A.

We find for

of A X

-T-A x = (A x, ~) by

(7.63e). T-

Ax

With =

=

(7.61),

36a12 , 8a 2

this is

3 6a12

- 8 Y2a23

-

3 @a12 4 y2a23

(A x, e~)

(Ax" Ax2 + Ay

(A x, Ay ) Ay

2)

4 Ya23

el 2

y

252

One revolution of Mercury takes a time 2~a 1 Y

and in this time, on the average, A x changes by 7--

3

A x = AxTI

~

= - i 2~ ~

aI 3 (-~2} (I - e l 2 ) # A y

Let us choose axes so that at the moment of interest A lies along the y axis.

Then the forward precession

AAx radians A

In

one

Y century,

(Earth)

parameters

x 360x602

A 27 arc sec. Y makes 415.2 revolutions.

Mercury

The r e m a i n i n g

are m = mo

al a2

-

AA

=

in one revolution is

-

=

Jl 4.5m e 329390m0=

57.91x10ekm 278.3xlO6km

9 . 5 4 8 x I 0 -~

=

@

=

Earth

7 . 4 4 1 x 1 0 -2

e I = 0.2056

and we find for the precession

in one century attributable P

to Jupiter

= 155"

The precession of Mercury's orbit caused by Jupiter and all the other planets

is calculated as 531" per century.

equinoxes

The precession of the

once in about 25780 years adds 5026" to this.

value is 5600".

The observed

The difference 5600"

(531"

+ 5026")

= 43"

agrees with the value calculated in Sec. 5.3. The foregoing calculation bation.

is an example of a first-order pertur-

Higher orders are, as one might expect, more difficult and

are described in works on celestial mechanics. Problem

7.19.

Show that the constants

in (7.59) are those which arise

from solving the Kepler problem in two dimensions. Problem

7.20

Calculate the brackets

in (7.63).

Problem

2.21.

The eccentricity of Jupiter's orbit is e 2 =

0.056.

Refine the calculation done above to see whether this makes any difference.

253

Problem 7.22. expansion

Problem 7.25. momenta,

Find the effect of the next nonvanishing

Calculate (Ax, Ay) using Cartesian coordinates and

and show that (7.63a) results.

Problem 7.24.

The interaction with other planets not only causes a

planet's orbit to precess; in its orbit. average,

term of the

(7.65).

it also alters the position of the planet

By how many seconds of arc in one revolution,

on the

does Jupiter change the orbital position of Mercury?

Problem 7.25.

As seen from the earth,

the moon travels in an

approximately elliptical path in a plane

(Fig.

7.5), slightly inclined

Z

/x Figure 7.5

Coordinates for Problem 7.25.

to the plane of the earth's orbit around the sun (the plane of the ecliptic).

Owing to the action of the sun, the plane of the moon's

orbit wobbles--i.e., revolution

the angular momentum £ precesses

in 18.61 y.

at a rate of one

Assuming that the earth orbits the sun in a

circle of radius R, calculate this rate. Take as variable the vector r running from the earth to the moon and show that, averaged over a year,

the perturbing energy provided by

interaction with the sun is

= 2R GMp [ s ( ~ R r )2

rz -~-¢]

(7.68)

where M is the sun's mass and ~ is the reduced mass of earth and moon. Now, calculate the rate at which £ precesses.

The answer is

254

T __~=! 3 m~

m@ + m M

(R)3 ~ sec~

where T

is the period of the precession, T is one month, and the P other variables are obvious. Numerical values are m

+ m

• R

=

6.057xlO27g

M

=

1.971×10~3g

D =

1.496xlOZScm

a~

a =

5°8t43"

=

3.8155×I01°cm

CHAPTER 7 APPENDIX Time Avera g e of Start w i t h

rn

in K e p l e r Orbits

(2.70) or

(5.11),

E = energy

t =

J

dr

2 (~

+

Zr)

]%

L

This can be r e w r i t t e n more neatly ties e x p r e s s e d by (2.75a,b]

-E = -Y-" ~a "

~

z

=

(1 -

and

e

L = angular momentum y = G/en

in terms of the basic orbital proper-

(2.77),

2) mT -2E2 = (1 -

eZ)yma,

axis of the orbit,

T is the orbital period.

We find

T

I

rdr

[e2a 2-

(a

-

e is the eccentricity,

r)2] ½

a t once from a t a b l e ,

reached

variable2

i n 1609.

but our goal

introduced

i n t e r m s o f ~,

(7.69)

=

a(1

-

ecos~)

C7.70)

becomes

t

esin~)

(7.71)

J

w h i c h is known as Kepler's equation. We w i s h to evaluate

rn

I fr(t)ndt

From ( 7 . 7 1 ) ,

at

= 2-~ ( I

- ecos~)d~

so that

2

is

by K e p l e r

Let r

and,

~ first

and

(7.69)

T h i s c a n o f c o u r s e be i n t e g r a t e d by t h e u s e o f an a n g u l a r

= 2n(~)½a 3/~ Y

where a is the semi-major

t = 2Ta

T

Kepler's name for this v a r i a b l e was the eccentric anomaly, E. have changed the letter to avoid confusion with the energy.

We

256

n

r n

where the integral

=

~--~/(:

- ecos¢)n+ld~

a

is from 0 to 2~.

Positive values

of n are easy;

negative values are calculated by contour integration or by expanding the integrand in powers of e.

A few values are (r/a) n

3

Se2 + ~3 e ~

1+

3e2

1

e2

I

-I

1

-2

(:

-.5

-

e2)-%

CHAPTER 8

THE MOTION OF A RIGID BODY

In the narrow world of the exact sciences there are several kinds of rigid body.

There are nuclei, generally not spherical and

precessing in the atomic field or some applied field.

There are

molecules, whose shapes may be very complex, and there are stars and planets interacting through gravitation. field of engineering,

In the closely adjacent

and especially space engineering,

there is an

immense variety of oscillating and rotating devices, some of which, such as the gyroscopic stabilizers used on space craft, are extremely sophisticated. In every case the rigidity is an idealization.

Nuclear and

molecular spectra show series of lines associated with rigid-body motions among many other series produced by motions in which the system changes its shape.

Stars and planets are far from rigid, and

the designers of real machinery are always conscious of the elastic properties of the materials they use.

Nevertheless there are

phenomena characteristic of rigid-body motion in general, and in this chapter we shall study some of them. The discussion will be limited by a somewhat arbitrary restriction. involved in inertial guidance

Except for a few

(Sec. 8.4), man-made devices generally

involve supports of some kind, fixed axes or restrictive gimbals by which forces are exerted from outside to constrain the system, molecules,

Nuclei,

and astronomical bodies float in the fields that influence

their motion.

We shall consider only this latter class, skipping

with regret (except for Problem 8.20) the theory of the spinning top, an object with one fixed point. mathematically

For 200 years the top was analyzed

in order to confirm the insights of childhood; more

recently students have been introduced to tops in order to confirm the insights of the blackboard.

Instead, riding the crest of

astrology, we shall consider the precession of the equinoxes. 8.1

An~ular Velocit Z and Momentum The velocity of a point revolving around a fixed axis can be

very simply described.

Choose a point 0 on the axis to be the origin

of coordinates and locate P by the vector r o.

Define the angular-

velocity vector m directed along the axis according to the right-hand rule, with the length equal to the numerical angular velocity m.

Then

the velocity of P is given, in magnitude and direction, by v

:

~oxr °

(8.1)

258

regardless

of

the

location

of

0.

Note

that

the

components

of

m are

V

P

Figure 8.1

Relation between linear velocity and angular velocity.

not introduced

as time derivatives

this important

point in Section 8.5.

If the axis

of anything.

itself is moving,

with velocity V,

so that the point

In all

the

the

cases

the

of mass

V is

zero

With particle

we s h a l l

center

center

mass,

this P.

consider,

of mass, is

and

at

the

If

remains

let

(8.2)

o axis

of

a n d we may c h o o s e

rest.

(8.1)

choice, It

0 is in motion

(8.1) becomes v = V +~xr

through

We shall return to

us

now 0 i s valid

evaluate

chosen

even the

rotation

passes

coordinates

if

as

the

~ changes

angular

so

that

center its

of

direction.

momentum of

the

is

i = mroXV = mroX(~Xr o) or

(8.5)

1 = m[ro2C0 - ( a ~ . r o ) r o ]

Note that convenient

1 is not in general to introduce

~i

=

parallel

vector

m(ro2~i

indices

to ~.

It

will

explicitly

- roiroj~ j)

in

the

sequel

and write

(summed)

or £i = m(ro2~ij The fundamental

hypothesis

- roiroj)~j

about a rigid body

C8.4) (never really

be

259

encountered

in nature)

relative positions. Thus

is that all parts

This requires

the angular m o m e n t u m

of it maintain

of a rigid body is given by

Li = Ioij~j"

Ioij = 2m(ro2~ij - roiroj)

summed over all the masses, with the components mass.

The formula

looks nice but

can be remedied by introducing The coordinates

it is useless,

a new coordinate

we have used so far,

(8.1)

thus far hold equally well of vectors

of vectors

fixed in a rotating from fixed axes.

All

system. and directions

of the

about their rates of change.

in a rotating

Of course,

coordinate

thinking

to be careful,

system appears

We shall see presently

system,

for the

them are unchanged

if we start

we shall have coordinate

by

the relations we have derived

and the angles between

adopt such a system. of change

This

v is the rate of change of ro, but it was introduced

and not as a time derivative.

lengths

of time.

fixed in space and centered

to, v, and ~; we have said nothing

To be sure,

to each

for as the body moves

on O, have only served to specify the magnitudes vectors

~8.5)

~k appropriate

and both Iij and mj are functions

all the r's change,

the same

that they all share the same ~.

if we

about the rates

since a vector

to move when viewed

how to take this into

account. We choose axes center of mass unchanged:

fixed in the rigid body, with the origin at the

as before.

v represents

axes, but the components axes.

The position

of the vectors

velocity with respect

of v are evaluated with respect

of a particle with respect

given by the fixed vector

L i = Iijw j where the components

The interpretation a particle's

r, and

is to fixed

to the moving

to the moving

axes

is

(8.5) becomes

Iij = Zm(r26ij - rirj)

I.. ~J are now constant.

This will greatly

(8.6) simplify

the later analysis. The same quantities energy,

T.

occur in an evaluation

of the body's

We have T = ½ Zm(~oxr) 2 = ~ /:m[a~2r 2 -

= ½ Zm(r2~ij - r i r j ) ~

j

(~o.r)2]

kinetic

260

That is, __- ½

_r..~.o~.

(8.7)

zj z j

or

T = ½ L.~

This recalls a particle,

(8.8)

the fact that one can write T = ½ p.v for the motion of but here there

is the difference

that in general

L and

are not parallel. 8.2

The Inertia Tensor An object like lij , bearing more than one index,

tensor ment

if it has the right transformation

is that it should transform

like a product

it is in our case formed from the product is satisfied

automatically.

a linear operator

of vectors

Considered

The require-

of vectors,

A tensor can be regarded

and as a thing.

is called a

properties.

this criterion in two ways:

the vector ~ into the vector L by rotating

its length.

Considered

ties

it represents

of a solid object just as other physical

ted by various vectors components

and scalars.

Written

as

as a linear operator,

I transforms

as a thing,

and since

~ and changing

the inertial proper-

properties

are represen-

out in detail,

the

are

I Zm(y + z 2) - Zmxy - Zmxz 1 Iij = -Zmxy Zm(x2 + z 2) - Zmyz

(8.9)

-Emxz - Zmyz Em(x2 + y2) It is customary

to label the rows of such an array by the first index

and the columns by the second, but here it does not matter,

since I is

symmetrical, x..

zj

=

z..

(8.10)

jz

Clearly also,

Iii This diagonal also used) single

sum,

~summed)

= 2Zmr 2

called the trace of the tensor

in invariant under rotations

component

of

Iij

(8.11) (the German

of the coordinate

has already been encountered

Spur

system.

in (3.15)

is A

and the

261

formula

(3.16)

is a restricted

form of (8.6).

of I.. ~J are called coefficients products of inertia. It is the products Suppose

of inertia

they were all zero.

II

Iij =

The diagonal

elements

of inertia and the off-diagonal that make calculations

ones

difficult.

Then we would have

I2

0

0 1

Ii = III, etc.

(8.12a)

13

and

L

Ilmx~ + I2~y ] + I3ez~

(8.12b)

z = ~(zaO~x~ + _ h % ~ + z 3 % ~)

(8.12o)

=

This can always be achieved by the proper choice of axes with respect to the body in which they are fixed. e.g.,

Goldstein

details

1950, Konopinski

The fact is proved in many books, Rather than reproduce

the

here, we remark only that in most cases the body has axes of

symmetry and one merely needs following

8.2.

to align the axes with them.

The

example and problems will show how this occurs.

ExampZe I. Fig.

1969.

A uniform

To evaluate

slab in the shape of an isosceles

triangle,

Zmxy, divide the slab in strips like s I.

For

>

Figure 8.2

Isosceles-triangular slab of uniform thinkness.

each value of y the strip gives equal contributions negative x, so I12 = 0. Since positive vanish.

from positive

and

For I13 and 123, sum first along the z axis.

and negative values of z contribute

equally,

Thus even though the slab is not symmetrical

these also

with respect~to

262

y, its symmetry with respect diagonalize

to the other two axes suffices

to

the inertia tensor. Prove that for any inertia tensor reduced to diagonal

Problem 8.1.

form, I l + 12 ~ 13 ,

Problem 8.~.

A section of pipe w i t h inside and outside

r 2 rolls down an inclined plane. the two limiting

bar.

Find the moment

What

system

calculate

of inertia

tensor of a triangular

in a Rotating

but this,

ary axes.

coordinates

of course,

flat

Find a new

refers

It is not hard to express

rotating bodies

to motion with respect it with respect

on a few related

a be rigidly attached

xyz, which

dimensions

and

System

equation governing

is

to station-

to rotating

axes,

topics.

to a coordinate

system S,

is rotating with angular velocity ~ relative

a fixed system So, coordinates stationary

(0,i,0).

8.2 with literal

Coordinate

but before doing so we digress Let a vector

and

of inertia.

The basic differential (3.11),

h hangs

is its period of oscillation?

the slab in Fig.

its coefficients

8.3 D y n a m i c s

and give

in which the tensor will be diagonal.

Provide

Problem 8.5.

radii r I and

the acceleration,

~ and height

slab bounded by the points (a,0,O), (i,0,0) coordinate

(8.13)

pipe and a solid cylinder.

shop sign of width

from a horizontal

Problem 8.4.

Calculate

cases of a thin-walled

A wooden

Problem 8.3.

suspended

1 3 + I 1 ~ 12

12 + 13 > I 1 ,

XoYoZ o.

in S, moves with respect ~o = ~xa

If a is moving with respect

to

The tip of the vector,

to S o with a velocity (a fixed in S)

(8.14a)

to S at a rate ~, then this velocity

is

added to that just given, ~e = ~xa + ~

(a moving

This relation will presently be used to transform rigid bodies. the vector

To

see some of its further

r is the position vector

to the fixed axes the particle's

the equations

implications,

of a particle.

velocity

is

(8.14b)

in S)

suppose

for that

Then with respect

263

Write

~×r

+

~

(8.15)

v

=

~xr

+

v

t~.loj

v with respect

the absolute

to moving

axes.

again in

to fixed axes is

acceleration, :

~

0

~o is a hybrid,

fixed axes.

= & O0

(8.14b]

0

a

xr

+ ~ox~"

0

+

0

0

the rate of change of v (not vo) with respect

So that everything

a

to fixed

Now take the derivative

The rate of change of v ° with respect

a

axes use

0

v ° is the velocity of the particle with respect

the same way.

where

=

this as

Once more: axes;

ro

three times:

:

Lcoxm)xr

=

~xr

+

+

~xr

+

~x~mxr)

mx(mxr)

+

2~×v

+

mxv

+

mxv

+

v

+

(8.17a)

0

This can also be w r i t t e n a

=

gxr

+

as

(m.r)m

-

m2r

+

2mxv

+

(8.17b)

0

The first, corrects

third,

and last terms should be obvious.

the third when r is not p e r p e n d i c u l a r

in elementary physics, Like the centrifugal pays

for looking

~x~xr,

Fig.

to the room,

With respect

(approximately)

straight,

curve towards

of dynamics rotating

to describe

frame,

accelerations. apparent

however

the motions

they must contain

the marble's

on it,

path will be

it leaves on the turntable

it is started. of particles

forces

acceleration.

Put a piece of

and roll an inked marble

but the tracks

the left,

is

it is part of the price one

at the world from a merry-go-round. turntable

will

The second

to ~ as it usually

and the fourth term is the Coriolis

acceleration

paper onto a p h o n o g r a p h 8.3.

to

on the right will refer to moving

If we write

as seen in the

corresponding

If the real force on the particle

laws

to these

is F = ma ° the

force is

mv

=

F

-

m~×r

-

The third term is the centrifugal

m~xm×r

-

2mmxv

(8.18)

force and the last is the Coriolis

264

force.

Figure 8.3

(a) Path of a marble rolling on a rotating turntable as viewed from the room. (~) As viewed by an observer rotating with the turntable.

The Coriolis

force is most noticeable

southern hemisphere

the situation

If there is a high-pressure deflected towards

the northern hemisphere

region produces the relations

the direction

away from it is

counterclockwise

a clockwise

are opposite.

of highs

in the

as shown in Fig.8.3.

region at P, air flowing

the left and ends up circulating

around P; a low-pressure can often deduce

in the atmosphere;

is qualitatively

circulation.

In

Knowing

one

and lows from shifts

them, in the

wind as they go past.

Foucault's Pendulum Another

illustration

of the Coriolis

long pendulum hung carefully Fig.

8.4 shows a suitable

the earth's

set of coordinates,

= 0,

S is the earth's

small displacements,

~

y

= ficos/,

with respect

angular velocity

~

to w h i c h

= fisinl

(8.19)

and I is the latitude.

For

z

the force on the p e n d u l u m

F x = - ~ x£,

and omitting

of a

angular velocity has the components

x where

force is the behavior

so that it can swing in any direction.

the negligible

is

Py = -£Y

centrifugal

force gives

265

m~

= F -

(8.zo)

2m~xv

or

m~ = Fy

- 2mCcozx

- oJx~ )

LO Z

~K~ra 8.4

Since the pendulum's

Coordinates for Foucault~s pendulum.

vertical m o t i o n

is negligible,

these are

= - ~ x + 2~sinX~

=

To solve these neatly, a complex

2nsinX~

the xy

plane

as a complex plane with

coordinate

The equation

+ jy

=

~

j2

= -1

for E is = - ao2E-

phase

_

consider

x

This

_

is solved by setting of m o t i o n

locates points

is a V(-l)

2jasink~

~. = A e i v t

~o 2

where

g/~

the i that gives the time

that has nothing

on the plane tangent

=

to do with the j that

to the earth.

two square roots of -i; i and j may designate

There

are, of course,

the same one or

266

different ones. ently.

The point is that the designations

are made independ-

We find

~2 = ~0 2 + 2£j~%~

~h = ~sinl

which has two solutions

v1

= ij~ l +- (COo2 + ~12) ½

2

since we are neglecting

terms in ~2.

The general solution is

= Aei~l t + Be i~2t

= e-J~k t (Ae{wo t + Be-i~o t)

The pendulum must be carefully released from rest:

~(o)

--

A + B,

~(0)

=

o

from which f~X

A = ½ (1 - ij - ~ o ) ~ ( 0 ) , and

~(t) = e - J ~ t ~ ( O ) ( c o s ~ o t

The second term in the parentheses

+ j --~ sin~ot)

is very small.

Essentially,

(8.21)

the

pendulum swings at a frequency ~o in a plane that rotates clockwise with the angular velocity ~ .

There is no use mounting such a

pendulum on the equator. Foucault tried his pendulum first on a modest scale in 1851 and then installed a heavy iron sphere suspended by a 67-m wire from the dome of the Pantheon in Paris.

It created something of a sensation

as people realized that this was the first direct dynamical proof of the Copernican hypothesis sky,

that it is the earth that turns and not the

(Today one says more carefully that a description that takes

the sky as a reference system requires than one centered on the earth.

simpler equations of motion

To say that one turns and the other

267

does not is not a p h y s i c a l

Hamiltonian

Formulation

The H a m i l t o n i a n By (4.52)

statement.)

the change

in a rotating system contains

a kinematical

term.

in a d y n a m i c a l variable a c o r r e s p o n d i n g to an

i n f i n i t e s i m a l r o t a t i o n of coordinates Aa c

=

around the ith axis is

A@i (a,L i )

or, dividing by At,

ac = ~i(a'Li ) and this gives &

= (a,~o.L) + 0

w h e n we include the change & w i t h respect to the rotating axes.

This

is the change in a w i t h respect to fixed axes, given by the h a m i l t o n i a n as u s u a l ,

O

=

(a, s)

Thus the change in a w i t h respect to rotating axes can be w r i t t e n as

=

(~, ~eff)

in w h i c h the effective h a m i l t o n i a n

is

Her f = H - e.t This is useful where,

as in the example of the Foucault pendulum,

angular v e l o c i t y ~ is a p a r a m e t e r of the rotating system. we shall consider in Sec.

(8.22)

situations

Presently

in w h i c h it is a dynamical variable,

8.6 we shall see how to write down the H a m i l t o n i a n

the

and

for that

case.

Problem 8.6

If the M i s s i s s i p p i River is about 1 km wide at latitude

45 ° and the current flows at about 7 m/s, how m u c h higher

is the water

level on the west bank than on the east?

Problem 8.7

In 1833

mine shaft in Saxony.

(Dugas 1955)

F. Reich studied free fall in a

The shaft was 188 m deep and in 106 observations

he found that a test object fell an average 28 mm east of the point directly below w h e r e it was dropped. theory?

Is this in accordance with

268

Problem

v.

A ball is thrown vertically

8.8

Where will it strike

Problem

upward with initial velocity

the ground?

What is the shape of the curves described by (8.21)?

8.9

Show the function of the small second term. Problem

Use the hamiltonian

8.10

(8.22)

to derive

the equations

for

the Foucault pendulum. L a r m o r ts T h e o r e m

If an atom is immersed without changing theories

in a magnetic

its shape;

field it begins

to turn

this is the basis of semi-classical

of the Zeeman effect.

The general

statement

is Larmor's

theorem : If a system of identical each other,

charged particles,

and with a central mass,

its motion becomes of a constant

(except for centrifugal

rotation

interacting

is placed in a magnetic effects)

among field N,

the superposition

around the central mass and the accelerations

produced by the other forces.

The precessional

angular velocity

e B = = 2-mThe proof is a direct application on a particle

Then in the rotating

system, m~

is satisfied

theorem is applicable the stationary

(8 23)

of (8.18).

Let the total force

be given by F

and if (8.23)

is

f

=

+

(8.20) gives =

r

+

(8.24)

evxB

for each particle

vx(2m~+eB)

only nonmagnetic

in practice

central mass,

+

...

forces remain.

The

only to atoms because except

for

all the particles must have the same

ratio e/m.

8.4

Euler's Equations After this digression

we can q u i c k l y f o r m u l a t e t h e e q u a t i o n s

the angular velocity of a rigid body subject The equation of motion mass so that ~ = 0.

to arbitrary

torques.

is (3.11) with the origin at the center of

In the notation of Sec. [

= M O

8.3,

for

269

With respect

to axes fixed in the body, +

and if the axes are oriented

~xL

:

this is

(8.2s)

M

so that I is diagonal,

this is

Ii~x + (13 - I2)~y~z = M1 (8.26)

I2~y + (II - I3)~X~ z = M2 I3~z + (12 - Ii)~x~y = M3 These equations,

which sum up the theory of rigid bodies

ably symmetrical

and appealing

the comment tribus

"Summa totius theoriae motus corporum rigidorum

formulis

satis simplicibus

As we have mentioned

before,

in 8.1 as kinematical If Euler's

equations

object with torques object's

vectors,

applied,

8.5, but if the torques

equations

of M depend on the

further development,

the

in this case is to note that of energy and angular

L is constant with respect

and to specify the individual

angles which we are not ready to discuss,

body-fixed

coordinates,

L 2 is constant

(Prob.

to space-

components

but even in the

8.11).

We thus have

Izmx2 + I2my2 + I3~z2 = 2T (const.)

(8.27a)

I12~x2

(8.27b)

To find the general

+ 122~y2 + I32~z 2 = L 2 (const .)

solution

of the Euler equations we solve

for ~y and ~z' say, in terms of ~z and substitute first Euler equation,

z

which we postpone

are zero we can integrate

contain the conservation

The angular momentum

fixed axes, of course,

(2.19).

of anything. of a spinning

as they stand.

momentum. requires

the behavior

To specify what angular velocities

requires

The first step of the integration Euler's

~¢ were introduced

not as time derivatives

the components

his

A word of caution.

the angular velocities

angular orientation.

equations

continetur. ''1

are used to analyze

have to do with angles to Sec.

in a remark-

form, were given by Euler in 1760 with

The details

which yields

an elliptic

are left for Prob.

integral

of the form

8.12.

The whole theory of the motion of rigid bodies

these three rather simple formulas.

(8.27)

them into the

is contained

in

270

Asymmetric

Top

An ordinary blackboard three different becomes what

top,

will detect

into the air it

and with a little practice

in the classroom.

so that it spins nearly

around one of the axes of

w h i c h we shall name the third axis.

observed to precess

of an object with

If thrown

results may be demonstrated

Toss the eraser

about a fixed direction

The axis will be

in space,

that if the long axis is the one chosen,

is in the opposite axis

is an example

of inertia.

is known as an asymmetric

the following symmetry,

eraser

coefficients

is chosen,

direction

from the spin, whereas

the precession

is the other way,

and sharp eyes the precession

if the shortest

The following

analysis will show why. By the conventions momentum

of the experiment,

around one of the axes,

say axis

the initial

angular

3, is much greater

around the other two, so that ~z >> ~ x and ~ y , and Euler's

than that

third

equation becomes z3~ z ~ o

Thus ~z is approximately equations

constant;

(8.28)

call

it ~, and the other two

are Ii~ x +

(I 3 - I2)~O~y

= 0

(8.29) 12~y

These

equations

+

(I 1 - I 3 ) ~

x =

0

can be solved by the substitutions x

and the condition

= ae ~t ,

~

for solubility

X2

=

y

= beXt

(8.30)

turns out to be

(13-12) (Ii-13)

~z

(8.31)

IiI 2

The four possible

situations

are

I3

~ If,

12

X 2 ~< 0

13

> I 1 , 12

X 2 ..< 0

I 1

<

13

< I2,

12

< 13

<

I 1

12 > 0

271 If 12 < 0 the m o t i o n is periodic, while is unstable

and the axis wanders

the solution is left for Prob.

Symmetric

if 12 > 0 the initial m o t i o n

through large angles.

The rest of

8.12.

Top

If two of the moments of inertia are equal s i t u a t i o n simplifies. ~3 = ~, a constant.

(or nearly so),

Setting 12 = I 1 in ( 8 . 2 6 ) g i v e s

the

~3 = 0, or

The remaining two equations are

13 - I 1 $o + - - ~ x ii

0

=

y

(8.32) 13

-

I 1

-

~

y Introduce

ii

= 0 x

the a b b r e v i a t i o n 13 - I 1 P

11 (There is no occasion for

and solve these by setting ~x + iv y = ~.

both an i and a j because the m o t i o n is pure precession.)

- i~p~

=

This gives

0

and ~(t)

=

~(O)e i~pt

(8.33)

This gives the p r e c e s s i o n of the a n g u l a r - v e l o c i t y vector with respect to the b o d y - f i x e d coordinates. Something of the sort is seen in the motion of the earth, Fig. 8.5. Z

Figure 8.5 Careful m e a s u r e m e n t s

Wobbling of the earth on its axis.

have shown t h a t

the earth's axis of rotation

272 wanders

counterclockwise

around the North Pole in an irregular path

never more than about Sm from the Pole. 13

Since

I 1

-

1

(8.34) II

(we shall see in Sec. earth's rotation

8.5 how this value is determined),

is counterclockwise

of the precession

is correct.

than the 300 days predicted explained by the irregular discrepancy

~04

as seen from the pole,

The mean period

from (8.34). loading

The irregularities tides,

Then by (8.14a),

according

are

and the

lack of rigidity.

the precession

is in the same direction.

Let k be a unit vector along the axis of symmetry, z axis.

the sign

is about 50% longer

of atmospheric

in the period by the earth's

As seen from outside,

and since the

k moves with respect

which we call the

to space-fixed

axes

to ~:0 --- ~xk,

k II ,z

or

Thus

~0 ~ k o x + 6kO v = ~Y - 6 ~ x = - i ~ ( t ) and integration

using

(8.33) gives

<0 =

_

~(0)

(8.3s)

eimpt

P

The sense of the precession according Problem

is the same as that of ~ or opposite

as 13 > 11 o r 13 < I 1 , 8.11.

Show that Euler's

Fig.

8.6

equations

imply the constancy

of

g and L 2 as defined in ( 8 . 2 7 ) . Problem

8.12.

the Jacobian

Complete elliptic

to assign the labels The solution Problem

8.13.

the solution of Euler's

functions

sn, cn, and dn.

Suppose

that

in the reduction

been very nearly but not quite equal to I I.

in terms of

It will be convenient

i, 2, 3 to the axes by assuming

is given in Landau and Lifschitz

have been different?

equations that

L 2 > 213T.

(1969). leading

to (8.32) 12 had

How would the results

273 Problem 8.14.

Show

that

for

a symmetrical

L where

k is as b e f o r e

of s y m m e t r y . plane.

Thus

Draw

=

I1(~

a body-fixed

~,

diagrams

unit

the

for

> 0 and m

m

(8.36)

vector

space-fixed

P about

(Ii = 12),

k~p)

+

k, and

top

pointing vector

along

L all

the

lie

axis

in a

< 0 to s h o w h o w m and

k precess

P

L.

Figure 8.6

Precession of short and long symmetrical tops.

The Gyrocompass In earth

1852,

with

demonstrated form, its

Fig.

axis the

in

year

after

the

turn

11 = 12 i n

wheel.

If

space

device

around

to

with

consists the

the

we l e t

he had demonstrated

occurred

a smaller

8.7,

can

Since in

the

a pendulum , it

that

a gyroscope. of

spin

in

plane

xy

11 a n d I z r e m a i n

constant

with

and t o make them c o n s t a n t

reason ing

that

for

introducing

the

we c a n w r i t e

orientation down t h e

the of

as

we n e e d n o t the

inertia

z axis,

could

In its

a gyroscope

aligned

the

rotation it

of

the

be

simplest

suspended

so t h a t

vertical.

gyroscope, it

the

Foucault

rotating the

components

axes of

long axes xyz

the

as in

= ~sink

the

+ $

the

coefficients

axis

of

x and y axes spin

was t h e

first

changes vector

change,

X

the

fix the

as

~ that

is

only

place. the

of

Remember-

earth

rotates,

describes

the

274

=

~cos~sin~

=

~cos~cos~

Y Z

where ~ describes

(8.37)

the turning of the gyroscope's

axis.

7¢

Figure 8.7

Foucault gyroscope suspended above the earth's surface.

To find the equations we note that

if I 1 = I2,

of motion

(8.6)

Lx = I1~x,

in the non-spinning

becomes

Ly = Ii~y ,

where s is the spin angular velocity. fixed coordinates

is given as before by

I1~x + (13 - /1)~y~z z1~y + (zl

With the gyroscope e corresponds

suspended

to thousands

coordinates

Lz = I3(~z + 8) The transition (8.14b),

+ 13smy

z3)mx~ z

as in Fig.

from moving

and we find

=

M

x

z~8~ x = My

(8.38)

8.7, M

of revolutions

to

-- M -- O, and since x y per minute while co Z

275 corresponds constant.

to

less

With

than one revolution per day, we can take 8 to be

(8.37),

the vanishing

of M x then gives

Ii~ + (13 - ll)~2cos2lsin~cos~

The middle

term is negligible,

+ 138ficoslsin~ = 0

and if ~ is small the rest reduces

I3 $ + (Ti-~cosX)O

Equilibrium direction

= o

is when ~ = 0 and the gyroscope

it oscillates

to

(8.39)

points north;

around this

with a period

p = ~

I1

(

½

)

(8.40a)

/38flcosX As the ready recokoner will at once agree, 2~

x

366.25

=

= 365.25

x

24

×

7.292

×

1 0 -s

(8.40b)

S -I

602

and with s of the order of 102s -I, P is of the order of i minute. Foucault's gyrocompass

demonstration

to damp the oscillations, disturbances

that

largely replaced

apparatus

has been developed

that

result

never worked very well.

to keep it spinning, from changes

the magnetic

The

from it is equipped with devices of speed

compass where

and to compensate and course;

it has

accurate bearings

are

needed. Problem

Using

A gyroscope

8.15.

the non-spinning

the direction

of the gyroscope's

usual phenomena Problem

brium

8.16

spinning

coordinate

of the gyroscope

In what direction

around the y axis has I 1 = 12 < 13.

system evaluate axis

the moment

M when

is changed and show that the

are explained. does the gyrocompass

if it is being carried north at a velocity v?

point

at equili-

Give a numerical

estimate.

8.5

The Precession

of the Equinoxes

It has been known Since Hipparchus before

that,

that the North Pole traces out a circle

to put it another way, ecliptic

(~125 BC), and possibly

the equinoxes move backwards

at a rate of about

50 arc seconds per year.

long

in the sky, or around Fig.

the 8.8 shows

276

the plane of the ecliptic,

containing

the earth's orbit,

the equatorial

plane along the line g~.

line of nodes.

The sun moves clockwise

of the ecliptic.

At ~, the ascending

Astronomers

around the earth in the plane

node,

it passes

~

Figure 8.8 equatorial

plane;

at ~, the descending

of Pisces.

enters Aquarius

The precession

node,

it passes below it.

The

towards a point in the Zodiacal

The Age of Aquarius

is a gyroscopic Fig.

8.9.

is to begin when it

effect that arises because

The calculation

the

of the precessional

The sun exerts a torque on a spheriodal earth because the near side is attracted more strongly than the far side.

velocity will be done in four parts: deriving

ec|£pf£c

(Prob. 8.19).

earth is not a sphere,

Figure 8.9

above the

Precession of the equinoxes.

ascending node points at present constellation

intersecting

call this the

the potential

with the spheroidal

function

earth,

deriving

the equations

for the interaction

solving

the equations,

of motion,

of another body

and evaluating

the

effects produced by the sun and the moon.

Euler's Angles We have first to establish and angles. orientation

the relations

between angular velocity

The best way to do this is due to Euler:

define the

of the rotating body by means of angles and then express

277

the components

of ~ in terms of them and their derivatives.

8.10 shows an appropriate

construction

in two stages.

Fig.

To get from the

zo

Figure 8.10

The Euler angles are generated by rotating the ~ tipping the z axis.

space-fixed

axes to axes oriented with respect

but not spinning with it, first rotate with the line of nodes;

then rotate

the desired

of the z axis.

changing, of nodes

inclination

and if the body's

angular

is 9, the components

plane and then

to the spinning body,

the xy plane

so t h a t z coincides

the Vz plane so as to achieve If the angles

orientation

0 and ¢ are

relative

of ~ in the moving

to the line

frame can be written

down by inspection,

x = Csin0

:8.41)

V z

(If two of the

coefficients

of inertia

necessary

to fix the axes

designate

a rotation of the entire

axis;

see for example

in the body,

Goldstein

We can now proceed

are not equal,

so that it is

the third angle @ has to

coordinate

system around the z

1951.)

in either

of two ways:

find differential

equations

for 8, ~, and @ in terms of the moment M by Euler's

equations

in the form

(8.26),

or write down the Lagrangian

system and follow the route of Lagrange, Jacobi

to a solution.

Hamilton,

We shall use Lagrange's

for the

or Hamilton

equations.

and

278

The kinetic energy of the earth's rotation is

T which

½ [ll(~0X2 + ~0ya) + /3O~Z2 ]

=

is T = ½

The potential

[ZI(@2 + sinZ@$ 2) + Z3($COS@ + ~)2]

(8.42)

energy depends on the situation; we must next find one

to describe the i n t e r a c t i o n between the sun and the earth.

The Interaotion Potential Let us first evaluate

the c o n t r i b u t i o n of the sun.

is considered at rest at the origin,

If the earth

the sun moves around it in a

path which we shall take to be a circle of radius R traversed at a constant angular v e l o c i t y travels clockwise.)

x 0

=

(The negative

sign is because

it

is given by

Rcosnt,

In the m o v i n g coordinate these

-n.

Its p o s i t i o n

Yo

=

-

(8.43)

Rsinnt

system the sun's coordinates

are related to

by

x = XoCOS~ + y0sin~ y = (-x0sin~ + YO cos~)cos@ z

(8.44)

(x0sin¢ - YO cos~)sin@

=

(These are best derived by carrying out in succession the two rotations

shown in Fig.

8.10.)

With

(8.43), these take an obvious

form, x

=

Ecos(~

+

nt)

y = -Rsin(~ + nt)cose

(8.45)

z = Rsin(~ + nt)sine

We have now to calculate

the interaction p o t e n t i a l w h e n the sun is

at this point in the sky, Fig.

8.11.

The distance from the sun to the

element of mass dm is =

[(r-r')2] ½,

r.r = R 2

279

and

the p o t e n t i a l

is V =

- GM

[ d_.~m

J integrated perform

over

the

Legendre's

2_ = Z [~,2

spheroid

of the

expansion

2 _ 2r'.r

+ R2]½

:

earth.

Since

r' << R

, we

can

in L:

1 ~

r'.r + -7-

[1

+

3(r'.r) 2 - r ' Z R 2 2R"

+

"'']

M

/ Figure 8.11

The

Coordinates for calculating the attraction of a mass M by a spheriodal earth,

interaction

v(r)

:

potential

f J

- z..~ |o(x ',y',z')[1 + ~ R

2R~

r T2

- ~

Assume sense

is

that that

X' , y T , or

the p(x')

(x'

+

2X2

+ y

12~2

...]dxVdyVdz

earth's

density

= p(-x'),

(x'x + y'y + z'z) +

etc.

Z' go out and we h a v e

+ Z

,2Z2

+

2x'y

exy + ~y ,Z!

yZ

+

~xVz

v

is s y m m e t r i c a l l y Then left

all

terms

distributed

in the

containing

a single

Txz)

280 v(r)

=

___J aM

{:

p(=',y',z')

R

+ ~

term of the i n t e g r a l

the rest are c l o s e l y

r ' 2 ) x 2 + (3y '2 - r ' 2 ) y 2

-

m

related

dx'dy'dz'

is the p o i n t - m a s s

Vo = - R

while

'~

( 3 z '2 - r ' 2 ) z a ] }

+

The first

[(Sx

=

potential

f

Pd3r'

to the c o e f f i c i e n t s

of inertia.

From r I1 =

~

(r '2

_

x'2)Pd3r

+ 13 =

2

I r'2pd3r'

'

J and I I +

we r e a d i l y

deduce

that

J which,

Thus

v(r)=

or,

in terms

V(r)

R = - G~m

precession,

-

V(r)

aMm R

12

+ 13

Similar

ann u a l m o t i o n

GMm R

2I 1

results

hold

for a n a l o g o u s

+

is v e r y fast w i t h r e s p e c t this

(8.46)

+ nt) sin2@]

expression

over

to the

time.

the sun by a ring of the same mass

sin2(¢

GM ~R3

...

angles,

2R'[ (13 - II)[ 1 - 3sin2(¢ G~

Since

-

~M 2R, s (/3 - II)( x2 + y2. _ 2z 2)

and we can a v e r a g e

= -

' =

f i n a l l y we get

to r e p l a c i n g

the earth.)

- r,2)d3r

is I 3 - I i.

of the E u l e r

The sun's

amounts

p(3x,Z

since I I = 12,

expressions.

12

+ nt)

averages

(-r3 - I 1 ) ( 1

(This

encircling

to i/2, we have

3 - ~ sin2e)

(8.47)

281

S o l u t i o n of the Equations

The lagrangian (8.42)

and

that describes

the earth's

rotation

is formed

from

(8.46):

GM

+ ~

where we have omitted coordinates

(I3

the irrelevant

¢ and ~ are cyclic,

3

- Ii](l

first

- ~

(8.48)

sin28) The

term of (8.47).

so that we have at once two constant

momenta

~L

~--~ = (llsin2e

+ 13cos2B)$

+ 13~cos

8 : p@

(const.]

(8.49) ~--~= BL I3($cose + ~) = p~

where we have written more

rapid

(const)

~ for the daily rotational

than $ by a factor

of 365 x 26000,

P¢ = 13~cos8,

with the observed motion,

may once have been,

analogous

so the approximation Neglecting

and if the precession angular

constant.

in which whatever

to those of (8.33),

3GM

+ ~

(I 3 - /l)sinecos8

is uniform with

8 constant,

velocity 3GM I3 - II c o s e

to Kepler's

is there

are now very small,

to ~, we find that the equation

2R 3

According

This

wobbles

is good enough.

$ compared

I18 + 13nSsinS

precessional

Since ~ is

P% = I3~

from which we can see that 8 is very nearly consistent

rate ~.

these are very nearly

third

13

law,

R~

T2

for 8 is

= 0

this gives

for the

282

where T is one year.

Thus

$

where the negative the ecliptic.

I3 I__________ ! = 13

=

-

67[2 ( ~ T ) 2

13 - I] i3

COS0

sign means that the precession

The relevant

1 304

data, noting

0 =

(8.40b),

23o27 '

=

is backwards

along

are

7.29

x 1 0 - s s -I

"

and, for the sun's motion,

~f = 2~ x 366.

This gives a precessional

period of about 80,000 years, much too long. saved when we realize

that

the moon,

The calculation

the sun, is also much closer to the earth and actually more to the precession.

is

though much less massive

When its contribution

than

contributes

is included

(Prob.

8.17)

we find a value near the observed value

Pobs=

Problem

8.17.

Calculate

~obs

(8.$0)

25780y

the contribution

of the moon to the precession

of the equinoxes. Problem

8.18.

magazines,

the

According

March 21 to April 19. May 17 (depending that

whatever

of precession, 8.19.

8.20.

in Aries

arbitrary

and

from 17 to

of boundaries).

take no account of

when were they written down?

Find a chart of the sky t h a t

Calculate

in newspapers

from about April

assignment

the tables used by astrologers

and estimate when the Age of Aquarius Problem

published

the first sign of the zodiac,

It is actually

on a somewhat

Assuming

Problem

to the horoscopes

sun is in Aries,

shows the vernal

equinox

will begin.

the rate of uniform precession

of the top

shown in ~ig. 8.12, The top's nutation can he calculated by the equations derived here. It involves either elliptic integrals or their trigonometric example Goldstein Problem

8.21.

explanation

approximations

and is not very difficult

(see for

1950), but we shall not pursue the question.

If one did not believe

for the precession

relatiyity

theory,

of planetary perihelia

a possible

is that the sun

283

is slightly oblate. value to Mercury

Assuming

an oblateness

(43.1" per century,

that gives the correct

e = 0.2056, T = 88 days), use

(8.46) with @ = ½~ (and the oblateness now that of the sun) to find the precession to be expected for the earth e = 0.0167).

The result of Prob.

(S.0 ± 1.2" obs.,

5.9 will be useful.

l

Figure 8.12 Spinning top. 8.6

Quantum Mechanics of a Rigid Body Although the quantum theory of rigid-body motion is a hybrid of

quantum dynamical structure,

laws and purely classical

it nevertheless provides

nuclear spectra,

ideas of rigidity and

insight into both molecular and

and thus has some contact with reality.

In analyzing

it we shall also have occasion to develop more clearly some ideas about rotating

coordinates

for the subsequent

that will be needed

in quantum mechanics

sections.

In the work thus far we have started from Euler's or Lagrange's equations of motion,

but quantum mechanics

from a hamiltonian.

That given in (8.22) will not do here because it

applies

starts most naturally

to situations where the angular velocity ~ is given; here it

is a dynamical variable and we must start again. however, we pause to study the commutation

momentum

relations for angular

as expressed in a rotating system of

The Commutation

Relations

Before doing so,

coordinates.

for Angular Momentum

In order to explain the origin of the angular-momentum operator we have derived in Sec. 4.4 a special case of it: gives infinitesimal y and z.

angular displacements

Quantum mechanically,

in the coordinate picture, components

the operator that

applied to functions

we were dealing with orbital quantities

and the commutation relations

of h follow directly

of x,

(Prob.

for the

8.22) from those for the

284 linear momentum. For the derivation to come we need a more direct and general approach which is provided by the theory of this chapter. be an arbitrary vector fixed in a rotating coordinate

Let a

system.

Then

in a time 6t its tip will move a distance 6a 0 = ~ x a 6 t

with respect to the fixed frame.

(8.51)

It will be convenient

for the

moment to consider the variation of the scalar quantity A

=

(8.52)

x.a

where the I. are a set of arbitrary non-transforming constants. z Further, we introduce the infinitesimal angular displacements during the time 6t:

50.

=

m.6t

i

=

x,

Y,

(8.53)

z

Then by the rule for permuting dots and crosses, Problem 8.23,

6Ao = X . 6 O x a = - 6 O . X x a In quantum mechanics, variable,

suppose

(8.54)

that ~ is some vectorial dynamical

in general a function of coordinates, momenta,

and A = k.8.

spins, etc.,

In the form of (4.45) we express the change in A in

terms of commutation with an operator J defined by

6~

=

i6o.[3,~]

(8 5 s )

The geometrical meaning of a rotation requires that (8.54) hold in quantum mechanics

also, so that since 68 is arbitrary ^

[~,

(x.~)]

= ix×~

(8.56)

This can be written in component form if we introduce the totally antisymmetric tensor eij k = ±l:

cijk

= -ejik

= -~ikj,

e123

= I

(8.57)

That is, eijk = +l when the sequence ijk can be obtained from 123 by an even number of permutations write any vector product

and -I otherwise.

Using this we can

in component form as (AxB) i

= eijkAjB k

(8.58)

285 and ( 8 . 5 6 )

becomes ^

~j[Ji,aj] : iEijkhj~ k With ~. arbitrary, we deduce that J ^

.

[Ji,aj] This

is

the familiar

cyclic

^

: ~ijkak

(8.59)

relation

[Jl,a2] = ia 3

etc.

(8.60)

^

and i f ,

as a s p e c i a l

case, ~ = J, ^

it

gives

^

iJ 3

[Ji,J2] =

etc.

(8.61)

A familiar example of operators that satisfy this relation is the components of orbital angular momentum, Prob. 8.22.

Real angular

momentum contains a factor of ~ which the reader can insert where necessary. The theory of rigid-body motion is expressed in terms of rotating coordinate frames.

In such a frame, the rotation can be described in

a way perfectly symmetrical to what we have just done with respect to fixed frames:

consider the apparent change $ in the rotating frame

of a vector that is fixed in space. o

=

0

By (8.14b), =

~xa+a

or = -~xa

(8.62)

Let K be the operator in the rotating frame that generates angular displacements in the same way that J does in the fixed frame. The derivation goes through exactly as before except for the negative sign; we find that [Ki,~j]:-

i~ijkak

(8.63)

and

[ki,kj] = -i~ijkK k k represents angular momentum in the rotating frame just as represents it in the fixed frame.

(8.64)

286

Problem 8.22.

and using

Defining

the operator

the commutation

commutation

practice,

as

i~6ij

=

for the factor of ~ the components

relations

Problem 8.23

angular momentum

relations

[~i,Pj] show that except

of orbital

of L satisfy

the

(8.61).

Verify

(8.58)

from the definition

use these relations ax[bxe]

to derive =

(a.c)b

(8.57)

and, for

the vector formulas -

(a'b)c

and a.[bxc]

Problem 8.24.

=

To see the dynamical

[axb].c

content

of (8.61),

consider

a

A

rotating

system with a magnetic moment

gyromagnetic

ratio.

In classical

given by M = yL, where y is the

physics

exert a torque on it equal to -BxM.

a magnetic

field B will

In quantum mechanics

and compare

it with the classical

Problem 8.25.

formula.

Solve the equations

set up in the preceding

that is, solve the equation of motion find the eigenfunctions

for L in classical

and eigenvalues

problem;

physics

in quantum physics.

the relation between the two solutions which may seem, to be so different

the inter-

Find d/dt

action is described by a term -B.M in the hamiltonian.

and

Explain

at first sight,

as to be almost unrelated.

The Equations of Motion Although scopic

rigidity

is even more of an idealization

scale that it is with laboratory

body in terms of the classical

apparatus,

on the micro-

we define a rigid

hamiltonian

K22 x32)

+ v

H = 2__ii +

I2 +

I3

(8. ss)

287

where

the potential

is expressed

in terms of the Euler angles.

The

justification

for this form is that it leads to the right equations

motion

8.26).

(Prob.

(12 = Ii)

We shall consider

in force-free motion.

transcribed

from

(8.65),

here only a symmetric

For this,

of

top

the quantum-mechanical

can be written as

(8.66)

The eigenfunctions

and

eigenvalues

those of $3 and $2; the negative makes no difference

of K~ and ~2 correspond

~k,m k

to

sign in the c o m m u t a t i o n relation

to the eigenvalue

write down the eigenvalues

closely

spectrum and we can at once

of H as

= 1 ~211_!. k ( k + l ) ~ Zl

+ (I__ 1 ~] z3 - Y~'l)m~

(8.67a)

where

k = O,

Because

1,

2....

the classical

is essentially not expect

and

-k

theory from which

<. m k

(8.67b)

<, k

these expressions

originate

a theory of the orbital motion of particles,

to find half-odd values

of k, and in experiments

one does none are

found. R o t a t i o n a l States of Nualei

If we try to apply the abstract situations

Suppose nucleus

in the real world,

for example

the others. nucleus

But what does

Thus neither

well

the individual

any differently

in the restricted

consists

it mean to a particle Nothing:

a rotating

nucleons

at rest. spectra.

of particles,

each

provided by

to say that the spherically

symmetri-

from one that does not rotate.

nor the nucleus made up of them

in a spherical

have no rotational

above to

symmetric

symmetric potential

is indistinguishable

than in the same nucleus shells)

is a spherically

The nucleus

in a spherically

as a whole rotates?

cal potential behaves

that the rotator

with I 1 = 12 = 13.

one of which moves

formalism developed

we at once run into complications.

nucleus

Spherical

imagined

nuclei

to be rotating

(those with closed

The same applies when I 1 = 12

sense that the symmetrical

object does not rotate

288

about its axis of symmetry

and the possible

states 2 are therefore

only

those with m k = 0: ~2

Ek, mk Rotational

effects

least evident) numbers

are most evident

in the rotation

of neutrons

of k are even.

2i I k(k + l) (i.e.,

and protons.

For such nuclei,

symmetry

through the nucleus

contains

an even number of particles.

the resulting wave even in k. shows

divides

function

a set of rotational

compared w i t h theoretical given.

effects

the allowed values

it into halves

of

each of which

Thus if the halves are exchanged

is invariant

of sign takes place

under the interchange;

the odd levels

do not occur.

Table

levels of U 238 obtained by Coulomb values

are

nuclei with even

if we note that the plane

an even number of changes

Experimentally,

level be correctly

single-nucleon

spectra of spheroidal

This can be understood

particle by particle,

(8.67c)

adjusted by requiring

The discrepancy

and

that is, 8.1

excitation

that the first

is a measure

of the depart-

ure from rigid rotation. Table

8.1 ~

Rotation Levels of U 238

k

Eob s (KEY)

Eth (Key)

0

0

0

2

Problem

Problem

-+ 2

149

+ 1

6

309

+ 3

313

+ 1

8

523

+ 4

536

+- 2

787

+ 6

819

+ 4

12

1098

+ 8

1162

+- 5

Use

(4.57)

hamiltonian

8.27.

transcribing

(44.7+.2)

148

i0

8.26.

classical

44.7+.2

4

to derive Euler's

equations

Show that the quantum-mechanical (8.65)

(8.26)

from the

(8.65). hamiltonian

formed by

does not commute with k 3 if all I's are different,

2 The reader may already have encountered an example of this situation in considering the specific heat of a diatomic gas, to which molecular rotation contributes two degrees of freedom and not the three that one w o u l d expect if the molecule could rotate about its axis. See Andrews 1975, Ch. ii. 3

F.S.Stephens,

3, 435 (1959).

Jr.,

R.M.Diamond,

and I.Perlman,

Phys.

Rev. Letters

289

and that therefore energy eigenfunctions cannot be taken to be eigenfunctions

Problem

8.28.

r = roA~3,

The usual expression

where r 0 = 1.2fm.

from the data in Table the nucleus 8.7

of this asymmetrical rotator

of ~2 and 23. 4 for the radius of a nucleus is

Compare the moment of inertia calculated

8.1 with that estimated on the assumption that

is roughly a sphere of radius r.

Spinors We have seen in Chapter 4 one way to introduce a change of

coordinate axes.

If it is an infinitesimal

rotation around the third

axis, for example, we write fCxl,x2) corresponding an angle (8.51),

e. in

to

a clockwise

which

if

corresponding as

~ 6t

= e,

z

of

describe

rotations

a geometric

the

a clockwise

object

the

ex2,x2

on a vector

= ~

we h a v e

x

y

= 0,

rotation.

In

the

telling

called

of

the

what

a spinor

axes (not

(8.68) through

the

axes)

is

6a o = 0

We c a n

following

+ ~xi)

coordinate

operation

rotation

vector. by

of

-

6ay ° = eax,

a counterclockwise

rotation

~

= -eay,

to

) = f(xl

rotation

The c o r r e s p o n d i n g

8axo

tion

ie ~3)fCxl,x2 + -~--

÷ (1

describe

basis

or

do

to

that

can be used

a rota-

a clockwise

discussion,

they

such

we s h a l l

vectors

and, to

later,

represent

to a

vector.

Orthogonal

Transformations

A linear transformation of a vector can be written in the form a'.

=

c..a.

~j

J

(summed)

(8.69a)

or equivalently in matrix notation a' = ca A rotation in any number of dimensions

(8.69b) is defined as a transformation

that leaves the length of a vector invariant:

ai'a i' = aia i = c i j a j c i k a k How to determine the energy levels in this case is shown in Landau and Lifschitz 1958, Sec. i01. A brilliant and very complete discussion is Casimir 1931.

290

and if this

cijcik Introducing write

a i we must have

is to hold for any vector

the notation

T to

8jk

=

denote

the

(8.70a) transpose

of a matrix,

we c a n

this as T

o jiOik = 8jk or,

in matrix

notation, T

c c = 1 from w h i c h

it follows

by d e f i n i t i o n 0

Transformations

so r e s t r i c t e d

Problem 8.29. tion is that

Show

that

T

that

=

O-

that

(8.70a,d)

.

another

the m a t r i x w h i c h

Problem 8.30. orthogonal,

In order

and

{~5

property

=

rotates

to see why

by it into two orthogonal

(8.51)

~o

orthogonal

transformations.

of an o r t h o g o n a l

transforma-

(8.70d)

6ik

axes

in the

xy plane satisfies

the t r a n s f o r m a t i o n

is called

An

vectors.

infinitesimal

rotation

in 3 dimensions

is defined

by

(8.53), a ÷ a t = a + 8Oxa

Writing

70c)

that two o r t h o g o n a l vectors a and b are t r a n s f o r m e d

show

Problem 8.31.

i

are called

cijckj and show

(8.70b)

(8.71a)

aid = Bid + Yij' or e = 1 + y, show that (8.71a)

is r e p r e s e n t e d

by the m a t r i x

y =

In order

to describe

v e c t o r we shall

introduce

Co 03 8@ 3

0

802

801

the

-8 1

infinitesimal

three m a t r i c e s

rotations

Ji by w r i t i n g

(8.71b)

of a space (8.71)

as

291

6a

o

= -i(80.3)a

(8.72a)

with

J1

=

0

-i

i

J2

:

0

0

0

0

0

J3

=

0

0

0

0

(8.72b)

Problem 8.32.

Show that these matrices

Problem 8.33.

Show that the matrices

relations

(8.61).

The negative (8.68)

from (8.71b).

J. satisfy the commutation

It is for this reason that we have called them J.

sign in (8.72a)

rotates

can be extracted

reflects

the basis clockwise,

the fact that whereas

J in (8.72)

rotates

~ in

a vector

clockwise. Problem 8.34.

(8.61),

Since the matrices

they represent

angular momentum?

an angular momentum.

That is, what is j2?

(You may need to consult the eigenvalues

J. satisfy the commutation

relations

What is the value of this

Find the eigenvalues

a book such as Arfken

of J3.

1970 to see how to find

of a matrix.)

Spinors

It has happened devices

that were

several

times in physics

first introduced

have turned out to contain profound physics. theory

is an example.

Another

example

by which Klein was able to simplify the top

(Sommerfeld

that mathematical

in order to simplify

The Hamilton-Jacobi

is the Cayley-Klein

some calculations

1952, Klein 1896, Whittaker

the theory of rigid-body show how they arose, will be similar

of spin ~.

motion

It is not necessary

a embedded

in it.

1950).

earlier:

to repeat

but we shall

and what they have to do with spin.

rotation of the rigid body by telling what happens vector

in the theory of

turned out to be the

in the new variables,

to that we have followed

parameters,

1937, Goldstein

In the hands of Pauli and Dirac these parameters key to a theory of particles

calculations

The approach

to describe

the

to an arbitrary

292

A spinor to represent

is a vector with an ordinary

the following way.

2 complex components which can be used

3-dimensional

vector with real components

The spinor u that represents

a vector

in

a is defined

by the relations aI

2ReUl*U2,

a2 = 2 I m U l *

from which it follows

at once that aia ~•

Thus any transformation complex

length

=

~=

(l~xl

Here the dagger represents

lull

=

the

(8.75)

conjugate,

conjugate

defined as the

and the transpose:

for

e,

The vector independent

=

c

*T

(8.76)

a is overspecified by u because whereas

real components,

u has

2 complex ones,

The nature of the redundancy

spinor u (~=i , 2) represents represents

a rotation preserves

1~21 = = ~ %

+

the hermitian

cf

numbers.

(8.74)

u, defined as

formed by taking the complex

any matrix

I~21=3 =

= +

which represents

lul 2 of the spinor I~1 ~ =

matrix

=

exactly

the same vector.

defined by 4 real

is clear from

a certain vector

a has 3

(8.73):

if a

a, then the spinor

e iX U

s

We shall remove this redundancy

in a moment.

Transformations

of u

An arbitrary

linear transformation u+u'

where

the matrix A depends

of u has the form

= au

(8.77)

on four complex numbers, (8.78)

The a d j o i n t

transforms

by t h e

adjoint

matrix,

u%' = utAt and so if (8.75)

is to be invariant we must have u t , u , = utAtAu

293

This

is satisfied

for all u provided

that

ATA = I Such transformations form

(8.78)

(8.79)

are called unitary,

the elements

and if A is written

are thereby restricted

(Prob.

in the

8.55) by the

relations I~I = +

I~I ~ =

But the A so defined is A' = eiCA where compare Prob.

lal ~ = =,

+ya~--

and we have already

of a.

It follows

zero is the obvious

and it is these transformations that satisfies

A

but rather

=

that

8.37)

and

Thus we make A i: (8.81)

to rotations

of a.

~ ) ,c~,2 + ,~,2 = 1

(8,82)

a ~

the general properties

of such an A, we

transformations.

Transformations

The most general matrix unity that satisfies

in the infinitesimal

neighborhood

of

(8.82) has the form A =

e2 + iE1

I I + ie 3 e2 +

where

{but

[8.81) has the form

shall look at its infinitesimal Infinitesimal

CProb.

det A = I that correspond

( -8a ~

than investigate

(8.79)

i.e., with d e t e r m i n a n t

AiA = 1,

2x2 matrix

seen

so

that X take some

one to choose.

not only unitary but also unimodular;

Any

from

of A is of the form e iX with X real

value;

(8.80)

since if A is unitary,

so we can fix the phase of A simply by requiring particular

0

that A' and A both give rise to exactly the same

of the components

the determinant

~s*

is still too general,

# is any real phase,

8.56)

transformation

Isl ~ +

ze I

] - ie3

(8.83)

J

the ~. are real infinitesimals and quantities of order ~2 are z We w i s h to see what transformations of a are induced by

neglected.

such transformations (8.75)

of u.

It is found

(Prob.

8.58) by means

of

that they are a

÷

a'

=

a

+

2~:xa

C8.84)

294

where e is the vector whose components are ¢i" Comparison with (8.71a) shows that these are the rotations we have already seen, with

¢i The g e n e r a l

form

(8.83)

can be written

unimodular

(8.85)

(8.8s)

as

1 0 -i 0 ) + g2( i 0 )

0 A = I - i[¢i(i and this, with

= ½ a°i

I 0 + ¢3( 0 _•)]

allows us to write the infinitesimal unitary

t r a n s f o r m a t i o n s of u in a form exactly analogous

to that of

(8.72a), 6u

where the m a t r i c e s

ol

0 = (1

a. are the Pauli m a t r i c e s

I 0 )"

0 -i ~2 = ( i 0 )"

These matrices have the p r o p e r t y that called hermitian.

(8.86)

= -i(6@.½~)u

~i = ~ti; such

matrices

(8.87)

are

They generate rotations of a via the spinor u just

as the matrices J generate

them directly.

If we look at the finite t r a n s f o r m a t i o n s infinitesimal

1 0 = (0-1 )

o3

c o r r e s p o n d i n g to the

(8.83) we encounter a remarkable

feature of spinors.

Let

the rotation be around the third axis so that ¢i = e2 = O and

U

As in Sec.

-~

I I+ig 0

0) E3

U

1-ie

=

½

~03

3

4.5, the finite t r a n s f o r m a t i o n is formed by iteration,

Lira

1+2 N

~,~o

o

O

A(O3) 1 - =i

or

e-~ s

and there are similar formulas Prob.

8.41.

for the other two e l e m e n t a r y rotations,

If the angle of r o t a t i o n is 2~, so that a returns

original orientation,

(8.88)

to its

the components of u are m u l t i p l i e d by -I, and

it is not until a has rotated through 4~ that u returns to its

295

original value.

It is natural

oddity has any counterpart suprisingly,

is yes.

to ask whether

this mathematical

in the physical world.

A simple demonstration

The answer, perhaps

popularized

by Dirac shows

that it is indeed possible

to perform an experiment which tells

whether

2~ has been made but is unable to detect a

a rotation

rotation

through

through 4~.

Attach three

2-ft pieces

piece of cardboard hand now rotates the triangle

of string to the corners

and give them to three hands to hold.

the cardboard

through

A fourth

4~ around a horizontal

is held still it is now possible

strings without

of a triangular

to disentangle

letting go the ends so that no evidence

axis.

of the

rotation remains,

but if the rotation

be disentangled.

That this fact is indeed a physical manifestation

spinor transformations topological

is through 2z the strings cannot

argument. 5

out. s

An iron foil is magnetized strips.

wave functions determined

effectively

8.35.

Problem

8.36.

and we may

8.37.

directions

along

and the change in phase can be

pattern.

through

has been carried

through the foil have their The results

show clearly the

2z.

Show that the most general (8.80). Show that if A yields

A' = eitA yields Problem

in opposite

rotated,

by the interference

restricted by

Such an experiment

Slow neutrons passing

sign change under rotation Problem

not topology,

there is any dynamical phenomenon which could detect a

rotation of 2~ but not one of 4z. parallel

of

can be shown by a subtle but straightforward

The subject of this book is dynamics, ask whether

If

the

form of a unitary A is C8.78)

a certain transformation

of a,

the same transformation.

Show from the properties

the determinant o f A,

of determinants

that if D is

(8.79) requires

[Di 2 = I

whence

D = e ~X

for some real X. Problem

8.38.

Show that if A given by (8.83)

ding transformation Problem

s

8.39.

E.D.Bolker,

acts on u, the correspon-

of a is (8.84).

Show that the matrices

½~i' with a~ as in (8.87),

Am. Math. Monthly 80, 977 (1973).

A.G.Klein and G.I.Opat, Letters 37, 238 (1976).

Phys, Rev. DII,

523 [1975);

Phys. Rev.

296

satisfy the commutation earlier matrices

Problem 8.40.

=

the last relation

Problem 8.41. other way,

for angular momentum

Show that the Pauli matrices

aiaj where

relations

like the

J. in (8.72a).

Eijkak

satisfy

and

ai 2 = 1

is true for each value of i.

With the derivation of

(8.88)

as a model or in some

find the matrices A corresponding

around the first and second coordinate

to finite rotations

of a

axes.

Spinors and Vectors In (8.73) we showed how to find the components of u.

The m o t i v a t i o n was

ad hoc.

of a given those

(8.74), but the substitution

Let us find a heater

form

for

(8.73)

looks somewhat

and also solve the

inverse p r o b l e m of finding u given a. Since the components

of a are bilinear

functions

of u and u t, there must exist three matrices for every u, the corresponding

a + a + 6exa, This

gives

u

(Prob.

(8.89)

= utMu

the unknown matrices

rotation of coordinates

M i with the property that

a is given by a

We can identity

of the components

if we carry out the infinitesimal

given by + u

-

½ i(~e.~)u,

ut + u t

+ ½ iut(6e.a)

8.42)

gijk~@jak

= ½

i6ejut[~j,Mi]u

(8.89a)

and since this is to be true for all 8@j, the use of (8.89) gives

~ijkUtMk u = ½ Since this,

in turn,

iut[ajaMi]u

is to be true for all u, M must satisfy

(8.9o)

½ [Mi,a j] = i~ijkMk It follows

from the result of Prob.

~i this relation

is satisfied,

the only solution. and a m u l t i p l i c a t i v e

8.39 that if M. is proportional

and a little thought

[Mi contains four numbers,

(8.90)

factor remains undetermined.]

to

shows that this is is three relations, It follows

from

297

direct c a l c u l a t i o n

(Prob:

8.43) that u%o.u

with

which

compact from

we h a v e

expression

solved for

the

the

(8.91)

= a.

problem

set

relations

in

(8.73)

(8.89), with

by giving

which

a is

a

found

u. Our next

task

is

to

find

u given

a.

From

(8.73)

and

(8.74)

we

have a I

a which

is

satisfied

ia 2

-

=

2UlU2

w i t h U c h o s e n so that +

I.~1 ~

U1

a 3

by u I = p ( a 1 - i a 2 ),

I.~l ~

~

=

(8.74)

I~1~% ~

u2

~(a

=

-

a 3)

is also satisfied:

+ ==~ + a~ _ = ~

+ =~)

=

~1.1~=~

- =~) :

so that °

i a 2 ) e ~'×

(a 1 U 1

=

,

[2Ca

-

U 2

[ ½(a - a3)]½e ix

=

a3)] ½

w h e r e X is an a r i b t r a r y phase common to both. more t r a n s p a r e n t form if we express angles

(8.9z)

These formulas take a

a in terms of the usual polar

@ and ¢: a 1 = asin@cos¢,

a 2 = asinesin¢,

a 3 = acose

whence a I -

We find

(Prob.

ia 2 =

asin@e

-i~

8.45)

u I =

a½cos½Se

-i~/2,

w h e n X has b e e n set equal to

u2 =

a½sin½@e

¢/2 for symmetry.

i~/2

(8.93)

Note again that

changes sign w h e n ¢ = 2~ and returns to its original value w h e n

u ¢=

4~.

Spinors are of interest today b e c a u s e they enter the c o n s t r u c t i o n of q u a n t u m - m e c h a n i c a l wave functions. way,

of course,

functions

as products.

They can enter them in a trivial

For example,

of h y d r o g e n c o r r e s p o n d i n g

quantum number n are of the form

the three p - s t a t e wave

to a given value of the radial

298 ½

I::>

= 2-

11o>

= X3fn(r)

I:-:>

(xi + ix2]fn(r)

= 2-½(x I - ~x2)fn(r)

If v is the spinor that represents

= 2½Vl*V2fn(r)

I:o>

=

But this and formulas

Iv21bfn(r)

~ -

into other terms. containing

an arbitrary product

Ivll 2 +

spin

Iv212

transcriptions

(fermions),

of the

We get something new when

a single spinor as a factor or,

of spinor components.

It turns

the spins of

and it is this fact, to be

that gives spinors

the discussion

given here.

Problem

8.42.

Derive Eq.

Problem

8.43.

Show by direct calculation

their names and motivates

(8.89a). that

of a using the spinor components

Problem

8.44.

Derive

the formulas

68.92).

Problem

8.45.

Derive the formulas

(8.93].

8.8

r =

(8.94b)

of this kind are needed to describe

of half-odd

discussed briefly below,

component

,

like it are only trivial

wave functions

out that expressions particles

(Ivll

= ~½vlv2*fn(r)

vectorial wave functions more generally,

the vector ×, these are

11:>

I:-I>

we construct

(8.94a)

(8.91) holds for each

of (8.92).

Particles with Spin The angular-momentum

the angular dependence in (8.94), describes

for example, a particle

certain directional

properties

of particles

of their wave functions.

are associated with We have already seen

how the vectorial wave function ~ = rf(r)

of spin i. properties;

A spinor is a geometric

object with

let us see how it can be combined

into

a wave function. The three wave functions the components

in (8.94a)

of the 3-component

are linear combinations

vectorial wave function rf(r),

of

299

chosen so as to diagonalize

J3"

The wave function

= uf(r)

is

an a n a l o g o u s

angular

(8.9s)

2-component object.

The o p e r a t o r

momentum when t h e wave f u n c t i o n

is

that

represents

a 2-component spinor

S = ½ ~o and the expectation a certain vector from

conjugate

is (8.96)

values of the components

spinor u and its hermitian

the

u%,

of S are formed using the

If the spinor corresponds

a, then we find the expectation

to

value of S at once

(8.91): <S> =

Thus although physical

space

It follows

in spin space

½ha

the spinor has only 2 components,

it represents,

as before,

from the principles

a quantity

in this way has an intrinsic

(Since f(r)

is spherically

symmetric,

that the object

angular momentum equal to 1/2.

there

is in this case no orbital

To see this let the basis vectors

be ~ and 6, so that an arbitrary u is w r i t t e n components

in

in 3 dimensions,

of quantum mechanics

represented

angular momentum.)

(8.97)

of the u-space

in terms of its (complex)

as

= Ul~ + U26 In this basis

the basis

vectors have components

1 a = (0)

These are

the

two i n d e p e n d e n t

0 6 = (1)

and eigenfunctions

Saa = ½ ~ a , and t h u s

they represent

o r down.

In the state

values

S 3 = ½~ a n d -½~

the states described

of S3:

S36 = - ½ ~ 6 in which the by ( 8 . 9 3 ) ,

spin

is

certainly

the probabilities

a r e cos2½@ a n d s i n 2 ½ e r e s p e c t i v e l y .

is obvious mathematically;

what iS n o t o b v i o u s m a t h e m a t i c a l l y

nature

to play with

has g i v e n us t h i n g s

formalism. such as e ,

It has been found that p, n , p ,

such as A, Z*, E*,

correspond

a number of the

and ~- have spin 3/2.

of spin

Higher

this

is

that

particles

several others

It is a relatively

relativistic

O, 1/2, and i.

All

to the

familiar

A, I, and ~ have spin 1/2, while

matter to find the wave equations, for particles

that

up

of the

simple

and nonrelativistic

spins have been an

300

unusually stubborn problem which seems finally to have been solved in recent years. Nothing in the foregoing argument provides any information as to the dynamics of the systems described;

requires further hypotheses.

that

we got the classical hamiltonian for rigid-body motion by putting the body together out of point particles each of which obeys Newton's laws. Clearly no such simple c o n s t r u c t i o n

is possible here.

It is assumed

in the modern theory that the hamiltonian contains no part corresponding to a particle's energy of spin; such a part, if it did exist, would ordinarily be constant and not participate in any dynamical exchanges of energy.

Only in an a t t e m p t

to treat transitions between

the states S(S = ½, m = 1190 MeV) and Z * ( S = 3/2, m = 1383 MeV), for example, would such a thing come into play, and nothing at all simple has come out a t t e m p t s

to make a theory.

(Readers with anti-

quarian i n t e r e s t s may consult Pauli 1946). The interaction between spin and an external electromagnetic field is introduced through the hypothesis known as minimal electromagnetic coupling, as follows: write the field-free nonrelativistic hamiltonian in the form ~o

(o'~) ~

= it= 2m

2m

C8 98)

where the equivalence of the two forms follows from the algebraic properties mentioned in Prob. 8.40.

Then use the rule (4.18) that

includes a magnetic field by the substitution p + p

-

eA

and finally, add the scalar potential e V .

[8.99)

On simplifying [ ~ . C p - e A ) ]

2

we find =

(P"eA)2 2m

-

~ S.B m

+ eV

C8 lOO)

in which the middle term represents the coupling of a particle with gyromagnetic ratio e/m to the magnetic field. We see that the electron's magnetic interaction emerges out of the hypothesis C8.98). It should be noted t h a t we have merely expressed one hypothesis in terms of another, 8 though the step [8.99) can be justified by fundamental arguments

(Park 1967, p. 188).

7

W.J. Hurley, Phys. Rev. D4, 3605 (1971).

8

J.Kalckar, Nuovo cim. 8A, 759 C1972),

301

Historically, "derivation" wards,

(8.100) was written down by Pauli in 1927.

given here made its way into the literature

and its only merit

electron's

gyromagnetic

in which the electron

is that it gives a way of understanding

ratio without becoming

is pictured

as a spinning

The real value of these considerations from rotational

transformations

in four dimensions. relativistic

well as the existence

in all of physics.

8.46.

Derive

(8.100)

from

Problem

8.47.

Show from (8.100)

(8.98)

gyrocompass?

is now one of the The matrices

now

ratio emerges,

as

and (8.99).

that d<S>/dt belongs

Can a hydrogen nucleus

which may

of positrons.

equation of motion as classical physics 8.48.

of charge.

This was done by Dirac in

but the same gyromagnetic

Problem

Problem

distribution

wave equation

and properties

the

in arguments

to Lorentz transformations,

1928 and the resulting

most solidly based relations

involved

lies in their generalization

be viewed as rotations

have 4 rows and columns,

The

long after-

to the same

gives for the same situation.

in a hydrocarbon

serve as a

CHAPTER 9

CONTINUOUS SYSTEMS

If we consider the motions of a continuous

s y s t e m - a stretched

string or the air in a room-- it might at first seem that we would have to deal with the infinite limit of an N-particle complexities would arise. to understand everything not so ambitious.

the individual molecules are doing, but we are

The right approach is to forget all about discrete-

ness and deal from the beginning with continuous coordinates.

system and that vast

This would of course be true if we wanted

This does not always work.

functions of the

If for example we want to

study the elastic vibrations

of a crystal we must start from the inter-

molecular

of this kind go back to Cauchy in 1822

forces.

Arguments

and are of a much higher order of difficulty than any to be attempted here.

We shall consider a few examples of mechanical vibrations--

stretched strings,

vibrating membranes,

sound w a v e s - and then an

example of a field that can be treated in much the same w a y - the matter field ~. 9.1

Stretched Strings The simple one-dimensional

and vibrating transversely

system of a string fastened at the ends

is a good introduction to the entire sub-

ject, since the extension to more than one dimension is only a matter of detail.

In the continuum limit the string has a number f of degrees

of freedom that becomes infinite,

and its configuration can be speci-

fied by giving the displacement u(t) corresponding along the string.

This suggests

to every point x

that f is not only infinite but that

it has the power of the continuum-- like the points in a line, the degrees of freedom cannot even be counted. kind of generality,

But we do not need that

for the string is continuous

and every point moves

very much like the other points in its immediate neighborhood; restriction will greatly simplify the analysis.

this

We label the points

on the string by the variable x and specify the displacement by the continuous

function u(x,t)

(Fig.

9.1a) which,

in the case considered

here, must vanish at the two ends: u(O,t)

Another way to characterize

=

u(Z,t)

=

(9.1)

0

the string is to express u(x,t) as a

Fourier decomposition, u(x,t)

- , , imKx = ~ am[~Je

K =

~

where the value of K is explained in Fig. 9.1b:

(9.2) the longest wave-

303

length, u(x,t)

corresponding

to m = +i,

is 2£.

Because

the displacement

is a real number, we have co

u(x,t)

= u*(x,t)

co

= 7~ a m

*e - i m K x

E a

=

--oo

so that the coefficients

-m

*e i m K t

_oo

will satisfy

(9.3)

a m*(t ) = am(t )

t~

t

•

,

\

%__-

x=O

Figure 9.1

×=L

In the Fourier r e p r e s e n t a t i o n infinity,

This results

the various (9.3)

coordinates

it by treating

move

independently

a more general

if u(x,0)

special

and &(x,#)

u(z,t) will remain real at all subsequent It will be instructive

on

as a The condi-

since one prefers

to have

of each other, but we can in which

to take on complex values, cases by the imposition are real,

for example,

times.

to study the problem

x descr.

Fourier descr.

lagrangian

1

3

hamiltonian

2

4

which we shall take up in order.

of u(x,t)

class of problem,

is at liberty

out the desired

of the points

the analysis.

of an inconvenience,

is not used and u(x,t) conditions:

and not t h a t

simplify

coordinates

but it is a countable

from the assumed continuity

is something

and then selecting boundary

in number,

the infinity of the integers

(9.5)

overcome

zl

the am(t ) are the generalized

They are infinite

function of x, and it will greatly tion

t

(a) String secured at the ends. (b) Representation of its normal modes as odd harmonics of a wave twice as long.

of the system. a line.

o

in four ways:

of then

304 9.2

1)

Four Modes of Description

Lagrange's Equations,

x Description

Let T be the tension of the cord, a shape given by uCx,t).

and let it be pulled aside into

The old length was £.

The new length is

~9.4)

~' = I de = Io [I + u'2Cx, t)]~dx =Io[I + ½ u'2Cx, t)]dx where u' = ~u/gx. the displacement

We have made the approximation is small.

of assuming

that

This is called the linear approximation,

since it leads to a linear equation of motion.

Problem 9.2 shows

that things become much more complicated when nonlinear terms are included. The slightly displaced

string is stretched by an amount

£'-

~

=

#

u'adx 0

and the work required

to do this is the potential

v=~ z If p is the linear mass density, see Prob.

9.22),

energy,

u ,2dx

(9.Sa)

o which we shall assume constant

(but

then the kinetic energy is obviously

T = ~

~2dx

C9.5b)

o where & = ~u/~t. The Lagrangian

of the string is then

o This is the sum of contributions the string.

S :

Ldt = Jt 0

where L,

the lagrangian

dx 0

density, L =

In g e n e r a l

from each element of length along

The action is given by

Csee P r o b l e m 9 . 3 ) ,

dtLCu',~)

C9.7a)

to

is

% Cp; 2 -

(9.7b)

~u '2)

L is a function

LCu,u',~ ) .

S is also

305

the sum of the actions belonging string,

each of which moves

exerted

by the adjacent

to successive

in response

forces

that the lagrangian

can be written

in terms of the system's

is a little

long

forces

is the potential

is true but not quite obvious.

show generally energies

dx of the

to time-dependent

That ½ Tu'2dx

elements.

energy produced by these

elements

of a continuous

mechanical

total kinetic

(Yourgrau and M a n d e l s t a m

To system

and potential

1968,

Chap.

8) and

The reason is that it is of no

we shall not pursue the matter here.

general use to be able to do so, for the main utility of variational methods

today is in the theory of fields, where

whole field at once; with the string,

principle

Problem

as can be done

of m o t i o n of the string are derived from varying S.

6u vanishes

at t O and t I by the terms of Hamilton's

Hamilton's

principle

and two independent

the string

~-u =

In our particular

aL

~u

-

~ ax

is not free to

6S = 0 is thus a problem

variables,

~L au,

in one

which has been shown in

1.21 to lead to the Euler-Lagrange ~L

motion

the

elements.

and at x = 0 and x = £ because

move there. dependent

one does not put it together,

out of individual

The equation The v a r i a t i o n

one considers

equation

~ aL ~-~ = o

-

case L is independent

(9.8~

of u, and the equation of

is TU" - p~

= 0

or u"

This

-

is d'Alembert's

~2

u(x,t)

it.

~/p

(9.9)

equation and its solutions

for any doubly differentiable

satisfies

v2 =

~. -- 0

= f(x

- vt)

+ g(x

That the sum of two solutions

the result of linearity,

and the velocity

is again a solution

is independent

does not change of amplitude

at the speed v.

and frequency.

of a system are the motions resulting

In

as the wave progresses

of each part is periodic with the same frequency. is m, the normal modes

is

and f and g represent waves of arbitrary

the w a v e f o r m

The normal modes

general,

+ vt)

w a v e f o r m m o v i n g to right and left respectively this a p p r o x i m a t i o n

are extremely

function of the form

in which the motion If the frequency

from (9.9) are the solutions 2 u" + ~-f u = 0

of (9.10)

306

specified by the appropriate boundary conditions.

Problem

For many field calculations boundary conditions

9.1.

like

(9.1) are inappropriate because they introduce reflected waves. alternative

is the periodic boundary condition u(Z) = u(0).

An

This

changes the value of K in (9.2) and also the conditions on ~u in Hamilton's principle. Problem

9.2.

Show how the theory developed above is changed.

Find the wave equation that results if the wave amplitude

is great enough so that the first three terms in the expansion

(9.4)

must be used. Problem

9.3.

A stretched string is attached at intervals to a

straight bar by springs of unstressed

Figure 9.2

length d, Fig. 9.2.

Find the

To illustrate Problem 9.3.

wave equation and give a solution.

Assume the springs are close

enough together so that their effect is essentially continuous. Problem

9.4.

The normal-mode vibrations

of a string are those in

which each part of it moves sinusoidally with the same frequency. Find the normal modes and their frequencies for the stretched string and also for the modification shown in Figure 9.2. Problem

9.5.

A bent board stores potential energy because the fibres

on one side of the median plane are stretched and those on the other side are compressed.

Assuming

that the fibres obey Hooke's law, show

that the stored energy is given by an expression of the form

V = o

u"2dx 0

Find Lagrange's diving board.

equation for the free oscillations

of a uniform

The boundary conditions are u = u' = 0 at the left end

307

and u"

= 0 at

frequency

of

the the

right

because

no

lowest

mode of

oscillation.

FT

string

9.6.

applied

there.

Find the

To illustrate Problem 9.5.

Find the equation

fixed at the ends

is

T

Figure 9.3

Problem

torque

for longitudinal

if a static

vibrations

tension f produces

of a

a stretch

ef£ in a string of length £.

2)

Hamilton's

Equations,

x Description

We define the m o m e n t u m

~

conjugate

to the variable u by

aL and the h a m i l t o n i a n

density H by H = z~

The

equation

of

motion

for

z

is aL

for

arbitrary

~H = "n'6~ + ~

T h u s we c a n

regard

variations

~

in

u,

aL 6"~ ~L Tu au - a-~ - ~,

a function =

where

the functional

while

(9.13) gives

(9.11)

~L

(9.12)

ax a u '

- aL

fl a s

L

(9.8),

{ = g~uwhile

-

of

~,

6u' = uS~ -

~,

aH aH aH - ~ + ax au

derivative

and u',

u,

= -

and

~L

6u -

u',

~H %-~u'

~L

gg,

and

6u'

(9.12)

(9.13)

becomes

(9.14a)

is of the same form as that in (1.46),

_- aH

6H

(9

14b)

308

These are Hamilton's

equations

for a one-dimensional

continuous

system.

We can easily verify that H is the energy density by seeing that its linear integral H is conserved.

we

a(u,u',~,w')

For any density

with

have •

d-T =

plus terms evaluated (9.14)

•

~a ~ + ~a

C-~-~ u + ~ d ' u ' + 5-4-

~)&

~-,

at the boundaries

which will normally vanish.

By

this is dA

6a ~H

d-T =

~a ~H

( ~ ~ - ~ ~-~)dx

(9.15)

o The resemblance the conservation

to [4.57)

defining

Poisson brackets

of energy follows

In the present case,

is obvious

and

at once.

from (9.7b), ~r =

pu

(9.16)

and

~2

T u,2

(9.17a)

while the total energy is

I~

I'£ 0

(9.17b)

Tu,2)d x

0

as one could have written with much less trouble from

Problem 9.7.

Find Hamilton's

equations

normal mode of the system of Fig.

Problem

g.8.

Find Hamilton's

(9.5).

and solve them for the lowest

9.2.

equations

for a nonuniform

cord in which

p is a function of x.

3) Lagrange's Equations, Fourier Description In this description am(t) and the velocities mentioned,

the coordinates

are the Fourier amplitudes

are their time derivatives.

we shall not impose the conditions

but allow them to follow from the boundary complex it is not obvious how to minimize

(9.3)

As already on the coordinates

conditions. or maximize

But if u is a complex S:

309

is -21 smaller

or larger than i?

The solution

is to make S automatic-

ally real by defining

L=~ noting

that

if,

the old one.

as we a n t i c i p a t e ,

Putting

u

into

is

real,

(9.18)

C9.18) the

new

L is

m ~°°

The integral

the

same

as

gives

da ~m = dtm

i ~S co C~ ama*m' - -Emint ,l(2ama,m,)ei(m-m')KXdx

L =

to

(9.2)

~T I~,I ~

I~1 ~

m t=_oo

of e

i(m-m')Kz

vanishes

unless m' = m, and it is then equal

~:

z

c = ~

5"~

(0 I~m I ~ -

m2Z2

laml 2)

We could take Rea m and Ima m as the coordinates, to take a

m

and a ~ ( P r o b .

9.12).

m

6L ~a ~ m

The

(gig)

but it is more natural

equation

~3L -~'-~-

d aL 2"%~-~ "-~= o

m

m

gives

~" or, with

d ~

~ maK2a m

p • -~ a m )

(9.9),

am + (mKv) 2am for each m, and ~L/~a m = 0 gives of the continuous simple harmonic coordinates.

= Am e im~°t

where A m and B m are complex conditions problem

conjugate.

The problem

to that of a set of independent

is, the am(t ) are the normal-mode is

+ B m e -im~°t constants

and the conditions

(9.20)

~o = Kv

(9.21)

to be determined by the initial

at the boundaries.

We have solved the

in Fourier variables w i t h about as much labor as it took to

state it in terms of x. initial

That

The solution of (9.20)

am(t)

0

the complex

cord is thus reduced

oscillators.

=

conditions.

To complete

the solution,

we must put in the

Suppose we are given the initial

configuration

310

and the initial velocity u(x,O)

u(x,@)

of the cord at each point.

We

have

u(x,o)

= ~

(A m + B m ) e i m K x

(9.22a)

m(A m - B m ) e i m K x

(9.22b)

oo

u(x,O)

= ico o

Z

By Fourier analysis we can find the coefficients Bm) and then solve for A m and B m.

m(A m

real, then a m obeys in detail in Sec. 4)

Hamilton's

(9.3)

If u(x,O)

9.14).

and u(x,O)

are

We shall work out an example

9.3.

Equations,

The momentum

(Prob.

A m + B m and

Fourier

conjugate

to a

Description

is m

2z_p_~ ,

at Pm = ~ - - = m

and, of course, of this,

Pm

the momentum

m

conjugate

The hamiltonian

to a

is the complex conjugate m

is easily seen to be

co

H : Hamilton's

equations

2 C-~

z

%T IPm 12 + -T-

laml 2)

m2K2

lead at once to (9.20),

(9.23)

and the energy comes out

as

E when a

=

z2~

is given by (9.21).

z

m2Clnm 12 +

IBml =)

The time-dependent

(9.24)

terms have cancelled

m

and E is

constant.

Problem

9.9.

Derive the hamiltonian

Problem

9.10.

Show that Hamilton's

Lagrange's Problem

equations

8.11.

9.12.

Evaluate

E with particular

and Ima . m

m

are equivalent

to

attention

to the cancella-

terms.

Show that the equations

a m and am* i n d e p e n d e n t l y

Rea

equations

for the system just discussed.

tion of t i m e - d e p e n d e n t Problem

(9.23).

are equivalent

obtained

from (9.19) by varying

to those obtained by varying

Problem

9.14.

Fourier

amplitudes

9.3

Show that if u(x,o)

Example:

derived from

and u(x,O)

(9.22)

are real,

satisfy

then the

(9.3) automatically.

A Plucked String

In this section we shall work out an example of the general considerations

given above and propose

Fig.

the initial position

9.4 shows

0

I/Z

Figure 9.4 and released

u(x,O) =

Since u(x,O)

a few corollary problems.

of a string pulled to one side

String displaced at the middle.

from rest at t = 0.

~2hZ-ix

(O<x<~,/2)

L 2hg-~(z-x)

(z/2<x<~)

= 0, the time dependence

,

~(x,O)

of the normal

=

0

coordinates

(9.2s)

is

given by c o s i n e s , and u(x,t)

=

Z

A eimKxcosmKvt

(9.26)

m

The constants conditions.

can now be chosen so as to satisfy the boundary In order that u(x,t)

must go together

= 0 at x = 0 and £, the exponentials

to form sines,

u(x,t)

= Z B sinmKxcosmKvt 1

m

With this, co

u(x,O)

and

B

m

is readily

= Z B sinmKx 1 m

found from

2 B m = -~

u (x, O) sinmKxdx 0

K = ~/i

(9.27)

312

B m -- ~

Thus B

m

= 0 for m even,

8h

sin

m~T

and m-1

Sm = ( - I ) ~

8h

odd)

(m

~T2m~

(9.28)

The motion of the string is given by

u(x,t)

= ~8h

I

(sinT~xcosKvt

The wavelengths

are 2 ~ / f ,

from an elementary

~

2~/3K,

construction.

harmonics

depend on the squares

therefore

vary as I, 1/34 . . . . .

understood Fig.

by sketching

1

sin3Kxcos3fvt

...

+ ~ T sinSKxcos5Kvt

, or 2Z, 2£/3,

The intensities of the Fourier

...

- ...)

(9.29)

, as is clear

of the various

components

of u and

Why the even terms vanish can be

some of the even

modes

and comparing

them with

9.4.

Euler's

Sums

The fourier application.

expansion

just used has an interesting mathematical

With 0 5 x 5 £ / 2 ,

n

the expansion

is

Z J _ . L sin % 1 sin n ~ x odd ~ 2 n 2 £

-

2hx £

1

Let x

=

~/2:

n

8h ~2n2

odd

sin

2 n~

- - =

2

1

2

n

odd

8h - - = ~2n2

h

1

so that 7T 2

=

So

2 n=1,3,5,...

-n-2 = - -8

(9.30)

Let oo

S

Then

=

2 n=l

1 n2

a

Se =

X n--£ n = 2 , 4, 6, . . .

(9 . 31)

313

S=S

I But also S e = ~ S

(Prob.

o

These

=

e

4 Thus S = ~ S O and

9.15).

~2 S

+S

72

- -

6

"

SO

sums are not especially

were obtained by Euler

~

- -

8

~2 S

"

easy to derive

=

e

(9.3z)

- -

24

in other ways.

They

in 1737.

Problem

9.15.

1 Show that S e = ~ S.

Problem

9.16.

Evaluate

Problem

8.17.

What

Z n -4. 1

is the harmonic

content

of the sound produced when

a string

is held at the point x = x o and released

x

where n is an integer?

o

=

£/n

Problem

plucked.

Assuming

the h a r m o n i c Problem

A piano

9.18.

string

a piano

dissonant with the note. order not to excite

not

string at x = xo, find

of the sound produced.

Show that the ninth harmonic

9.19.

What if

is set in motion by being struck,

that the hammer hits

content

from rest?

it?

Where

of a given note is

should the hammer

Are the m a n u f a c t u r e r s

strike

the string

of grand pianos

in

aware

of this fact? Problem

An electron

9.20.

well with infinite properly

normalized.

Practical We have

computations

shown in Sec.

can do something finding what

measured

Use of V a r i a t i o n

easier

quite

2.13 that Maupertuis's

similar.

In the double-integral

9.4,

that if the electron's (n~/Z) 2 ( ~ 2 / 2 m ) ?

Principles

Consider

variational

principle makes

and in continuum mechanics for example

mode of a string.

it is, and that will be useful

-iat

into a potential

it will turn out to be

in point mechanics,

the lowest vibrational

let u ~ e

introduced

What is the p r o b a b i l i t y

energy is subsequently

9.4

is m i r a c u l o u s l y

sides with a wave function of the form of Fig.

in assessing

some we

the problem of

(We know of course the approximation.)

principle

with ~ to be determined.

The integration

over t is now

314

trivial,

Suppose

and we have

the string stretches

from x = -i to x = +i, and let ~ = p~o2/T

be the unknown quantity that gives w. t1

6 ~

Then

(;~I.l ~ - l.'l~)d= = 0

(9.34)

J-I with

6u = 0 at the ends.

The calculus

of variations

(Prob. 9.23)

leads

to the equations we have already solved,

but it will be instructive

pretend for a while

the problem

that we cannot

To solve the problem single antinode, parameters.

approximately,

satisfying

We calculate

parameters make

let us invent a curve with a

the boundary

=

Suppose

conditions

for example

- x ~)(c o

(1

+

in (9.34)

16

8

s = C-i-~ x - ~)°o and the equations

@S/Be

z

°

and containing

free

of the

that (9.35)

e l x 2)

This is zero at x = +i and is symmetrical of the integral

to

exactly.

the action and then find what values

it a minimum. u

solve

right and left.

The value

is 16

88 )o

+ C-~-~5 ~ - -~)°o°~ + C ~ = 0 and

~S/~o

I

=

0

2

( ~ ; ~ - 5)°0 + (7 ;~ - I ) ~ i

~ - ~-~

2

give =

0

(9.36) (2~, - 7 ) % + (~ ; ~ - : I ) o I = o In order for these vanish,

to have any solution

and this gives

the eigenvalue ~2

Whose smallest

root

(lowest l

The exact value

=

_

28h

+

63

frequency) 14

-

at all,

1/]--~ =

=

2.46744

TF 2

The error is about ~0~%.

-~- =

0

is

is =

their determinant

must

condition

2. 4 6 7 4 0

C9.37)

315

Notes:

They don't always

a)

of a trial interest

in connection

16

s =

8

(-ff x -

~)o °

2

one,

our choice

approximations

is of

to ~.i

- x ~) is not too bad:

Co(I ~S

,

Clearly

so much so that the result

with algebraic

Even an approximation

b)

come out this well.

function was a happy

16

~ =

8

0 = 2o o ( - i Y ~ - ~ ) "

~ = 2.5

0

We h a v e r e a l l y

c)

normalization extra

unknown i s

The g r e a t

d)

o n l y f o u n d one p a r a m e t e r

is undetermined, generally

but

simpler.

accuracy with which the

n o t matched by a c o r r e s p o n d i n g substitute

The e x a c t

~ into

we f i n d

Uva r

Co(1

solution

-

1.2207x

an e r r o r

fractional

example, with

root

of that

Problem

9.21.

- 1.2337x

Problem

9.22.

of the

Problem

the 9.23.

variations Problem

equation

i

given

of a String

of the

Quart.

for

9.7 that

the

of the

/(6-~0%) =

square

~%.

(9.34) was not a proof. writing

down a solution

that it satisfies

secured

(9,34).

at x = ±i is given by

(-l~x~+l)

the solution

string

(9.38)

l o w e s t n o r m a l mode. of

obtained is rather

of motion has been studied

S. Ramanujan,

case,

= XoCOS2 ~x4

to the results

A piano

~ + ...)

= 0.7071

in Sec.

on t, and showing

The aensity

Show t h a t

(½)

is of the order

the wave equation,

periodically

frequency

see

In this

The demonstration

leads

9.24.

We s h a l l

eigenvalue.

l(x) Estimate

~)

2 + 0.2537x

Uexac t

in the eigenfunction

Fill the gap by deriving that depends

2 + 0.2207x

c o = 1,

o f a b o u t ~% .

error

I f we

is

Uvar(½) = 0.7086, with

has been determined

in the eigenfunction.

the approximation

Uexac t = c o c o s ~ x = c o ( 1 At x = ½, f o r

eigenvalue

accuracy

(9.36) =

of u, namely el/C ° since

the homogeneous approach with the

J. Math.

(9.34)

of

earlier. stiff.

in Prob.

45, 350

by t h e c a l c u l u s

How t o f i n d 9.5.

(1914).

its

F i n d t h e phase and

is

316 group velocities for the propagation carry the problem point where results.

of determining

a difficult

Require

of waves

down such a string and

its normal-mode

transcendental

equation

frequencies

for the frequencies

that u and u' vanish at the ends.

four dynamical methods

to the

Any or all of the

developed above may be used.

Approximate

the

frequency of the nth normal mode to the first order in the stiffness parameter

c.

Problem 9.25.

Assuming

carry out a variational

a reasonable calculation

form for the lowest of the piano

string's

eigenfunction, fundamental

frequency.

9.5

More Than One Dimension The equation

same argument

for the vibration

of a drumhead

as that used to derive

the drumhead's

vertical

the equation be u~x,y,t~.

displacement

follows

from the

for the string.

Let

Then if we consider

an element of area dxdy to be drawn on it when u = 0, the x direction by a factor 1 + ½ ~u/~x) ~

will be stretched

ly for the y direction,

as in ~9.4), and similar-

so that the area will

change to

~u 2][ 1 + ½ L'y;y .~u) 2] dxdy [1 + ½ (~-d) and t h e

increase

in area

is

thus 8u 2

SA=

If will

the

drumhead

is

in

be p r o p o r t i o n a l

V = ~

Problem 9.26. deriving

~[C~)

isotropic to

[(~x )

this

tension

the

potential

energy

stored

quantity,

+ (~y)2]dxdy =

Let the drumhead's

its equation

~u ~

%-F) ls=@

+

~

(9.39)

(Vu) 2dxdy

area density be s, and finish

of motion

~2U ~x2

~2U + ~-~--

I

~2U

v 2 ~t 2 -

o

(9.40)

How d o e s v 2 d e p e n d on P and o?

Changes of Variables Most drumheads

are round,

given most conveniently

and the boundary condition

if u is considered

as a function

is therefore of r and @,

317 with u(a,@)

where a is the radius operator

of the drum. formula

to make the transformation of Vu are the spatial directions,

du/~x

The variables

in the laplacian

in the variational

integral.

Choose the directions

of increasing r and

au

du

d--7 "

(Vu)e

=

~

1 du =

de

r

becomes

and the entire action

1 (~u) 2]rdrd e

integral

[ { ~d (~-~) dU 2

s =

The general problem

u r = au/dr,

is

- ~[

(~_uu)2 1 (-~) au dr + 7-~

2]}rdrded t

is of the form

6 ff[

L(U, Ur, U e ) r d r d @ d t

u e = du/d@.

Carrying

= 0

out the variation

6ue)drdOdt

= 0

~ ur) - -~ (r ~-~O)]6udrdedt +

+

uis continuous

infinite,

gives

the second and third terms by parts:

~u - ~

If

The components

directions:

II

Integrate

or one may

but it is also very convenient

rates of change of u in two orthogonal

(VU)r = (9.39)

in tables,

and du/dy.

@ as two new orthogonal

where

(9.41)

in (9.40) may be changed by direct calculation,

look up the necessary

Thus

= 0

constant,

line vanishes.

ff

[r ~aL Ur

r=R

6u]r = O dedt +

fl

~t

[r ~ u e

~U]°

e=o

drdt

= 0

a t r = 0, and 6u = 0 at r = R, where R may be or a function

of 8, the first term in the second

(It may be necessary

to think for a moment to see why

318 this is so.) The last term vanishes because @ = 0, and we have left 6(rL)

~u

as the Euler-Lagrange equation. to denote partial

0

(9.42)

In the present case, using subscripts

differentiation,

L and

=

@ = 2~ is the same line as

=TUt°2

_ ~2 CUr2 + ~1 u@2)

(9.43)

(9.42) gives 1

1

(9.44)

C~Utt - ~(Urr + r Ur + -~T u@@) = 0 The expression dimensions,

in parentheses

and the method

any kind of coordinate coordinates xl, x2,

is capable

... qy, given as functions

the

volume element

integral

to

If the new

of the Cartesian

(x)

becomes =

Jdq1...dqr

is

[

S =

/[u(q) ....

Jdql...dqrdt

and this gives at once the Euler-Lagrange taken as the lagrangian. they include

described by Maxwell's

Of course,

(9.45)

equation

for u when JL is

there are many other systems

than

here that are described by a laplacian

the drumhead considered operator;

generalization

= ~--'(-~

dx1...dx r The a c t i o n

in two

find the Jacobian J

so t h a t

of immediate

system in any number of dimensions.

are ql, q2,

... mr,

is indeed the laplacian operator

continuous mechanical and Schr~dinger's

systems

equations.

as well as fields We shall discuss

the latter separately below.

Wave Equation

in Polar Coordinates

The wave equation 1

in the surface 1

is

1

Urr + ~ ur + -~T u80 - -~T u t t = 0

v 2

= ~/o

(9.46)

S i n c e an a r b i t r a r y waveform can be formed o f normal-mode v i b r a t i o n s

Fourier superposition,

it is sufficient

to consider vibrations

at

by

319

angular frequency m, for w h i c h 1

1

42

Urr + ~ u r + 7~-u00 + 4~u = 0 (This is sometimes called H e l m h o l t z ' s one of the ii v a r i e t i e s 5.10).

equation.)

Polar coordinates

for w h i c h the wave equation is separable

are

(Sec.

If we set

u(r,O) then

(9.47)

= m2/V

R(r)@(O)

=

(9.47) becomes

(R"

"~ ,7. R! + 42R) @ + r~ RG" = 0

+

or r2 R

(R" + / R + 12R) = r @

Since the left side is i n d e p e n d e n t of @ and the right side is independent of r, b o t h must be constant. Set the constant equal to m 2. (9"

The @ equation is -m2(9

=

whence @ = A sinm@ + B cosm@ m m

(9.48)

and c o n t i n u i t y on traversing a complete circle requires that m be real and an integer.

The r e q u a t i o n is now

R"

+

This is Bessel's e q u a t i o n solutions,

!r R' + (42

m2 -

(Arfken 1970).

7£ )R

=

0

(9.49)

It has two classes of

roughly analogous to the sine and cosine solutions of

(9.10),

R = CmJm(lr) The Neumann functions Nm, kind,

are all infinite

in 1764.

(9.50)

also called Bessel functions of the second

at r = 0 and so have no place here.

functions of the first kind, Jm' w e r e Euler,

+ DmNm(4r )

(predictably)

The Bessel

first studied by

They are r e p r e s e n t e d by the series

Jm(X) = (½x)m m

[I

~ - I(m+1)

~½x)~ + 1.2(m+l)(m+2) . . . . ]

(9.51)

320 and for x > > m

are given a s y m p t o t i c a l l y by

~m ( x )

(~) %os (~ -

~

Jm 's

Figure 9 • S shows the first few extensively tabulated

7

-

~-)

(9.52)

as a function of

(Abramowitz and Stegun 1964)

x

They are

and available in

computer subroutines.

Figure 9.5

Three Bessel Junctions Jm(X).

The solution we have found is of the form

u ( r , O ) -- Jm(hr)(Amsinm@ + BmCOSm@) and the complete s o l u t i o n m u l t i p l i e s t.

this by a sinusoidal

function of

Since drums are u s u a l l y struck into motion, we shall look at

solutions

u(r,@,t)

that satisfy

u(r,O,o)

= o,

u(r,O,o)

(9.S5)

= Vo(r,O)

so that

u(r,O,t)

=

First, we must find the frequencies ~m" the r e q u i r e m e n t that n u m b e r Of zeros; the nth zero of by

(9 . s 4 )

2 Jm(Xr) (AmSinm@ + BmCOSmO)sinmmt m=O

Jm(~a)

= 0.

For each

They are d e t e r m i n e d by

m, Jm(X)

has an infinite

the first few are listed in Table 9.1.

Jm(x).

Then

Jm(~a)

= 0 implies that

Let x

ha = Xmn

mn

be

or,

(9.47) mn

V a

= - x

mn

(9.55)

B2'1

These

are the frequencies

not in the ratios

present

of small

not in any harmonic

in the sound of a drum.

integers

(or any integers)

They are

and therefore

are

series. Table

Zeros of Jm (x)

9.1

Numbers in parentheses are calculated from (9.52). first

second

third

2.40

5.52

8.65

11.79

fourth (11.78)

3.83

7.02

10.17

13.32

(13.35)

5.14

B.42

11.62

14.80

(14.92)

6.38

8.76

13.02

16.22

(16.49)

To satisfy the initial condition we write ~(r,@,0) =

Z ~mnJm(hmna) ~mnSinm@ + BmnCOSm@ ) = Vo(r,@ )

(9.56)

mj n where we have

introduced

extra indices

corresponding

to the various

zeros of each J . For the stretched string we solved the corresponding m (9.22) by Fourier inversion. The same is possible here

equations because

the Helmholtz

equation

equation with eigenvalues different,

The eigenvalues

and the differential

eigenfunctions

operator

are all orthogonal.

that they form a complete determined

(9.47) has the form of an eigenvalue

kmn"

set.

from a knowledge

are all real and

is hermitian;

A more advanced

It follows

of v(r,@)

therefore

the

investigation

that the A

shows

and B

can be

What

frequen-

mn mn and the problem, from the formal

point of view, is solved.

Problem 9.27.

A round drum is hit in the exact center.

cies are heard? approximate there be?

formula

numerical

values

for the rest.

Problem 9.28.

for the first few and an

Roughly how many frequencies

You may w i s h to experiment

of different

beaten?

Give

beating

will

a drum with implements

sizes. What

frequencies will be present when a square

Are they h a r m o n i c a l l y

related?

drum is

How would a square drum

sound compared with a round one?

Problem 9.29. solution 5.52008.

Estimate

of Bessel's

the two lowest

equation.

zeros of Jo(x)

The correct values

by a variational

are 2.40483

and

322 9.6

Waves in Space In this section we shall consider sound waves as a prototype of

other kinds.

The mathematical

as those in aerodynamics,

Propagation

functions to be encountered are the same

electromagnetic

theory,

and quantum theory.

of Sound

The lagrangian for sound waves can be found by evaluating potential and kinetic energies of an elastic medium

the

(we shall speak of

air, but only in order to be specific).

This argument is more

complicated than the underlying physics,

however

(Goldstein 1950, Sec.

11.3), and we shall follow a shorter path. Let the constant background pressure and density of the air be Po and

0o, the sound wave producing small fluctuations so that p and p

vary periodically. may be called x.

Consider a plane wave moving in a direction that Fig. 9.6 shows an element of volume.

"1

Its mass is

F+ P ' I

x ×l+dx Figure 9.6

Element of volume of a gas with applied pressures.

pAdx, which differs from

PoAdXby

terms of higher order,

force on it acting to the right is -Adp. ~v

PoAd x

and the net

Newton's second law is

x = -Adp ~t

or

~V

,==_~

~t

Po ~x

(9.57)

Where we use partial derivatives because at each point variables such as p, p, and the fluid velocity v are functions of both x and t. vectorial

form (9.57)

In

is ~._xv = _ !

~t

Po

vp

(9. s8)

323

The motion of the air must satisfy the equation of continuity which states that air is not created or destroyed, ~P + v . Cpv)

o

=

@t

Again to first order in the variations,

this is

~-~@t + Po v'v = 0 Finally,

the increments

(9.59)

in pressure and density are related by the

bulk modulus of the gas, B: ~P = i

Po

We can use t h i s

to eliminate

t h e wave e q u a t i o n continuity

is

for

p ~or p)

the pressure.

found from

(9.59)

(9.60)

Ap

B

from the e q u a t i o n s , I n terms o f p,

L e t us f i n d

the e q u a t i o n o f

and ( 9 . 6 0 ) :

v.v=_iaP

B ~t

To e l i m i n a t e

v,

take the time derivative

of this

and compare i t

with

the divergence of (9.58):

a-T v . v

=

5

=0

-

~

at2

=

-

p--j

VZP

or

This

is

d'Alembert's

B/no

equation for

the pressure,

(961)

and p s a t i s f i e s

the

same e q u a t i o n . To f i n d that

it

B we need some h y p o t h e s i s

obeyed B o y l e ' s

temperature

a b o u t t h e gas.

l a w and d e r i v e d B = Po"

Newton assumed

T h i s assumes t h a t

remains constant as the sound wave goes through.

waves in the ordinary frequency range the variations

the

But for

are far too rapid

for this and we do better to assume that the compressions and rarefactions take place adiabatically.

The adiabatic law is pV Y = const, or p = KpY

where y is the ratio of the specific heat at constant pressure to that at constant volume,

equal to 1.403 for air at 0°C and one atmosphere.

Thus Ap = K y p Y - : A p

and dividing the last two equations gives

324

Ap

_

Ap

po- -Co for departures

from the background

speed of sound V

At a pressure

is (ypo/Po)½

=

of 76 cm of mercury

Po

=

1"0132x10S

(9.62)

= YPo

B

and the computed

Thus

values.

at 0°C,

nm-2'

PO

=

1.2929

kg m -3

and V = 331. 6 ms -I

in agreement

with observation.

The lagrangian

density L

where,

as before,

that it leads Solution

to the d'Alembert

according

(Sec.

5.10),

Cartesian

9.32]

(9.61].

topic,

for there are many kinds

conditions

treatment

knowledge

of quantum mechanics

coordinates

are easy,

in each

1932,

to show the

on the one hand and

on the other.

of the

to appropriate

of

and for a

1970, Bateman

a few lines

of the drumhead

can be separated

and each one leads

imposed,

(Arfken

Here we shall only sketch

The variables

(Prob.

Equation

to the earlier

to the reader's

63]

(9

one easily verifies

we refer to other books

1949).

is

- V1{ ~2 ]

equation

to the boundary

discussion

Sommerfeld relation

, since

is a long and complex

solutions general

½[(Vp]2

=

p = @p/Bt

o f the Wave

This

for sound waves

ii St[ckel

systems

sets of functions.

but there are few rectangular

boxes

in

nature. Here we shall discuss only spherical polar coordinates. The wave equation in these coordinates can be derived by changing variables in the lagrangian

9r2

~ ~r

If we consider

integral

~

~

only a single

(Sec.

(sin@

9.5), Prob.

9.40),

and we find

+ r2sin2@ 2@ 2- v-[ ~t2 =

frequency

to the last term becomes

(m/v]Zp.

325

We begin by separating

the radial

p(r,e,¢)

variable

from the angular

ones:

= R(r)~(e,¢)

where

~-~IR=O

7 a (sin@ ~-Y) + 1 ~21~ r 2 ~ " 4- r2 R'+ X2R)Y + [s-~ "~ 30 sin2@ - -

If we divide by RY the variable constant

of separation

r is separated

X - - -v

out, and introducing

a

K gives R"

F2 R ~ + (h2

+

-

K~ - ) R

=

O

(9.66)

and

7 3 sin@ TO If the quantum-mechanical angular momentum,

BY)

(sine

7

3e

+ si~

operator

omitting

-

so that

(9.66)

for the square the result

1 3 sine n-----~ si 3--~

is the eigenvalue

We know that the eigenvalues

There

is

-£,

....

a second

by the functions

set

of

are however magnetic

essential

theory,

p m

=

the

of

kind,

because

that the

P£m(cosO)eim¢

(9.69)

associated

(9.66) Q m.

Legendre

in which

These

they become

in many calculations

notably

(9.68)

harmonics

are

solutions

of the second

use in quantum mechanics

(9.67)

lore of quantum mechanics

are the spherical

+£ a n d t h e

3~

~

£ = 0 , 1 , 2 ....

Y~m(e,O) m :

coordinates

is

K are

and it is part of the standard

where

l

3-'@-

of the orbital into polar

= K~'(o.,¢)

K = Z(Z+I)

y(@,@)

3

(9.66)

equation

~2:z(e,¢)

functions

+ KY = 0

the ~, is transformed

(see any book on quantum mechanics), ~2 =

32/"

~

p m

replaced

are almost never of

infinite

at e = 0.

in acoustics

those of the design

is

functions.

They

and electro-

of loudspeakers

and

antennas. With

(9.68) we return

to the radial wave equation

almost but not quite of the form of Bessel's ~(r)

=

~(r)

(Xr) ½

equation,

[9.65).

It is

but if we write

326

it changes to z"

+

-I

z '

r

+ 2FX

~ ]

z =

(9.70)

0

This is Bessel's equation of order ~ + ½, and it has two solutions,

J~+½(Ir), which is finite at the origin, and N£+½(Ir), which is singular there.

The radial function R is therefore of the form

R(r) = j ~ ( t r )

n~(tr)

or

(9.71)

where

~+~(~r)

JR+½(Xr) j~(kr) = are called expressible

(hr) ½ ,

n~(kr)

(~r) ½

s p h e r i c a l B e s s e l and Neumann f u n c t i o n s . i n t e r m s o f s i n e s and c o s i n e s :

Jo (x)

no(x)

= sin Xx

(9.72)

They are all

COSX X

(9.73)

J l (X) - sinXx2

cOSXx

nl(x)

cosx X2

sinx .~

These functions are appropriate to the solution of standing-wave problems;

incoming and outgoing waves are formed from linear combina-

tions such as

i lix Jo(X ) ± ino(X) = x ~ e etc.

(9.74)

They are called Hankel functions. These few remarks are enough to show why most of the mathematical apparatus of the quantum theory of angular momentum lay ready to hand when the theory was first invented. The angular part of the solutions of the wave equation in polar coordinates is standard, and only the radial equations, when quantum mechanics came along, were somewhat unfamiliar.

Problem 9.30.

Derive the laplacian operator for spherical coordinates

by changing variables in the v~riational integral.

Problem 9.31.

It is possible to compute the average molecular

velocity in a gas from its bulk properties by kinetic theory, and the sound velocity from (9.61).

ProbZem 9.32.

How do they compare?

Show that (9.63) is the lagrangian density for sound

waves and find the corresponding hamiltonian density.

Find the

327 numerical

factor that makes this an energy density. Starting

Problem

9.33.

derived

in the previous

acoustic

from the general problem,

energy transmitted

formula for energy density

find a general

it to a plane wave and show that the result

is reasonable.

not know how to do this, look at the analogous current density Problem

in elementary Assume

9.34.

that when sound waves

next to the surface

and formulate

the appropriate discuss

derivation

waveguides

wave equation

Using the result of Prob. What happens to this except

require

a little more thought.)

Problem

9.35.

Solve the preceding

cross section, 9.7

9.33,

and boundary

conditions.

evaluate

that will

the sound energy

(The theory of electromagnetic the boundary

that

problem

conditions

for a pipe of circular

radius a.

The Matter Field In his first paper on wave mechanics,

1926, 2 SchrSdinger Hamilton-Jacobi

made a strange proposal.

action is something

ing to avoid introducing proposed

submitted on 27 January Recognizing

that the

like a phase, yet obviously wish-

complex numbers

into physical

quantities,

he

to write S in the form

where K is a constant Jacobi equation

S = KZn@

(9.75)

to be determined.

In terms of ~, the Hamilton-

is x

a~L

H(xi" ~ ~x. In c a r t e s i a n

coordinates, (v~)~

(9.76)

ahead and solves

Annalen

) = E

_ 2___m [E

Ka

- V(r)]~

2 =

0

of classical physics;

it ones gets nothing new.

d. Physik

(9.76)

is

But this is merely a transcription

2

the

(this is not quite true),

if the sound frequency presented

is lower than t h i s limit? is similar

of the

the motion of sound waves down a pipe of rectan-

passing down the pipe. to the pipe

Specialize (If you do

reach a solid surface

do not move

gular cross section a x b and find the lowest frequency propagate.

for the

quantum mechanics.)

air molecules Using these,

expression

per second through a unit area.

79, 361 (1926).

Schr~dinger

if one goes proposed

328

instead a physical principle:

~

is to be chosen so as to make the

volume integral of the quantity on the left a minimum and not necessarily

zero.

We have therefore a variational problem of the form

I {(V~)2 - K22m [E - V ( r ) ] ~ 2 } d v which yields the differential

eigenvalues of this

v(r)]~

equation,

= o

(9.78)

as e v e r y b o d y knows, c o i n c i d e

V(r) = .e2/r and K = ~.

with the Balmer levels when

In a note added in proof, SchrSdinger tion:

(9.77)

equation ~m [ ~ _

The d i s c r e t e

= 0

suggests a better formula-

Write the integral to be varied as

[KaT(r. ~-~) + V ( r ) , 2 ] d v

(9.79a)

where T is the classical expression for kinetic energy, subject to the condition that ~ remain normalized

to unity,

f~2dv This is an equivalent,

9.36.

reluctance

(9.79b)

but neater formulation in terms of what is

called an isoperimetric problem,

Problem

= 1

to be discussed next.

The strange form of (9.75) reflects Schr6dinger's

to introduce complex numbers

instead with ~ = exp(iS/K),

into mechanics.

Starting

show how he could have phrased his argument

so as to introduce a complex ~.

Isoperimetric

Problems

There is a class of problems prototype

in the calculus of variations whose

is to be found in the Aeneid: ~

is given has the largest area?" answer is trivially a circle. problems of the kind:

"What figure whose perimeter

It is called Dido's problem,

and the

It is a special case of a class of

What function y(x) maximizes

or minimizes

the

integral

S =

I

f(y,y',x)

dx

(9.80a)

x0

where f is given,

3

Aeneid,

the variations vanish at the endpoints,

I, lines 367-8.

and another

329

integral,

T =

g(y,yV,x) dx

(9.80b)

X

is at the same time required

to have a given numerical value?

On varying y(x), we are requiring tionary, while is a number

~T = 0 because

to be chosen,

that ~S = 0 because S is sta-

T is fixed.

Let S' = S + XT, where

called a Lagrange multiplier.

Then

6S' = 0 is a necessary depending

condition

on the value

Problem 9 . 3 7 . be m a x i m i z e d

are satisfied

a nonrotating

The area to

[r 2 + r'CO)2]½dO located

equation.

A uniform chain of length ~ is suspended between

(Xo, yo ) and

Problem 9.39. planetary

is solved.

of a circle w i t h its point arbitrarily

the Euler-Lagrange

two points

takes on its given value,

use polar coordinates.

d~=Jo

[r2dO2 + dr2]

Show that the equation

Problem 9.38.

to find a

I o2~ ½r2d@, while the perimeter is

is

P =

satisfies

C9.80b)

and the problem

In Dido's problem,

a y(x,X)

If now it is possible

value of I such that T calculated by all the conditions

(9.81)

on y(x), and its solution yields

of X chosen.

X

Somewhere planet)

radii

(xt,yl).

What

is the equation

in the universe

suspended

in height.

the

for its curve?

there may be an antenna

from towers

(above

far apart and several

Find the formula for the curve of the

suspended wire.

SchrBdinger's

Variational Principle

In Schr~dinger's

s'

where

revised version,

=

[~-~ ( v ~ ) ~ + v ( r ) ~

X is the Lagrange multiplier.

(9.77) and so of course

the results

a little clearer

that the desired

integral

exists

to i.

(9.79b)

the integral

This

X~]dv

(9,8Z)

is of the same form as

are the same, but it now becomes

functions

at all--since

That is, a ~ corresponding

2 +

to be varied is

~ are those for which

if it exists

to a stationary

the

it can be set equal state must be

330

normalizable. SchrSdinger's

second paper ~ explored

and the Hamilton-Jacobi the time-dependent of mechanics

equation,

Schr6dinger

in Chapter i.

new discovery,

similar

but having no logical

The variational

principle

a very general property of eigenvalue Suppose K represents function belonging

principle

problems

any hermitian

to the eigenvalue

for (9.82) was a for a typical

connection with it,

~ does not refer to any mechanical

system represented.

(9.78)

equation with which we began the study

His variational

in form to that given in C9.63)

spatial wave phenomenon, since Schr6dinger's

the relation between

and introduced what is now called

property of the

does, however,

reflect

as is easily seen.

operator

and f is an eigen-

~:

kf -- ~f Now write

(9.83)

K as ~^

K and imagine

~z_ZLL~__Cq_ ~

that f is varied slightly

The quantity

< given by (9.84)

have a value nearby.

Varying

(9 84)

= if~fdq

from the exact eigenfunction.

is no longer an eigenvalue,

but it will

f and < in the equation

< I f*fdq = ; f*Kfdq gives

6~ I f*fdq + ~ I (f*6f + f6f*)dq = I ~f*Kfdq + I f*K6fdq and by the use of (9.83) and the hermiticity 6< Thus if

6f

f f q = 0

6~ = 0

this

to (9.85)

e, ~< is of the

fact has already been noted in connection

(9.34). We can also prove very easily

energy by variational ~n be the exact let

or

is of the order of some small parameter

order of e 2 or smaller; with

of K this reduces

some

that

(but unknown)

eigenfunctions

varied function ~ be expanded

=

Annalen

d. Physik

in calculating

a

ground-state

means we always obtain too high a value.

79, 489

in

Z en~ n n=O

(1926).

of the hamiltonian

terms

of them:

Let H, and

331

where if ~ and the @n are normalized, z I%12 n:O

= I.

The expectation value of H in the state ~ is

=

Z m,n

I Cm*~m*HCn~ndq

If E o is the ground-state

=

Z n=O

Icnl2E

n

energy then

< H > : Z I%I E n

Z I%I E o

or

so that E

Problem

O

>

(9.86)

E 0

is a lower bound on .

9.40.

Knowing the form of the wave function for the ground

state of a simple harmonic oscillator, make at least two variational to that of an anharmonic oscillator with VCx)

approximations

Which approximation

Example

I

The Helium

Examples

= -~ Kx ~.

is the best?

Atom

of the use of Schr~dinger's variational principle

for

finding stationary states are given in every text on quantum mechanics, but it may be useful to outline one such calculation,

omitting computa-

tional details which at first sight obscure the simplicity of what is being done. ed in Sec.

The system is a quantum~mechanical

The problem is to estimate function of a helium atom. completely

analog of that discuss-

7.6.

intractable

energy and wave

It is a three-body problem and therefore

in classical mechanics because the details of

motion are so complicated. the details;

the ground-state

But in quantum mechanics we do not follow

the indeterminacy principle deprives them of meaning.

Instead, we treat it as a system with a very simple behavior. The idea is to assume that the wave function for each electron in the ground state is not very different from that of an electron in a hydrogen-like charge be Ce.

atom of suitable but unknown nuclear charge.

Let the

We shall solve the problem by varying the parameter

~.

The normalized wave function for two electrons in the ground state is

332

(rl'r2)

Ta 3

=

The complete H a m i l t o n i a n

=

where

-

a = ~ m:~2 e2

for the two-electron

2-m (Vz 2 + V2

Z is the nuclear

operator

e-a(rl+r2)

charge,

Ze 2

Ze 2

r I

r 2

(9.87)

system is e2

+

and the expectation

(9.88)

value of this

in the assumed state is found to be

~ )~] me ~ 2R2

W = 2[~ 2 - 2(Z where m e ~ / 2 ~ 2 = 1 Rydberg

= 13.606

eV.

(9.89)

W goes through a minimum when

is chosen equal to Z-5/16; we explain this p i c t u r e s q u e l y that each electron

is shielded

5/16 of the time.

The energy

from the nucleus is then

E = Wmi n = - 2 ( Z For helium,

This

one begins

eV.

{9.90)

The experimental

is perhaps

comparison with what we could achieve but if one compares motion,

- /~)2Ry

this is -5.695 Ry = -77.49

-78.98 eV; the error is 1.9%.

by saying

by the other electron

not impressive

value

is

by

in simple vibration problems,

it instead with the three-body problem of orbital to appreciate

the simplifications

brought by

quantum mechanics.

Problem

9.41.

Carry out the integrations

Problem

9.42.

Estimate

simple pendulum function

to derive

(9.90).

the two lowest quantum energy states of a

variationally.

satisfy

necessary

What criterion must a variational

if it is to yield an estimate

wave

of the first excited

state? Problem

9.43.

Show that the lagrangian

density of the complex matter

field is

~2 L : ~ Problem 9.44.

{~*~ - ~*~) + ~

Iv~l 2 + V(r) l ~ [ 2

(9.91)

Show by c a l c u l u s o f v a r i a t i o n s t h a t the c o n d i t i o n

^

= 0, w i t h ~ n o r m a l i z a b l e , leads to ( 9 . 7 8 ) . 9.8

C l a s s i c a l and Quantum D e s c r i p t i o n s o f Nature As f a r as anyone knows, quantum mechanics i s r i g h t ,

and one might

suppose t h a t c l a s s i c a l mechanics i s t h e r e f o r e "wrong," or at best some approximation to the c o r r e c t t h e o r y .

C l a s s i c a l physics does not

333

contain h and in the course of deriving equal to zero.

example de Broglie's

relation,

and let h approach of units,

zero.

procedure.

set h

Take for

as already noted in Chapter I, kp

changes

it one must somewhere

But this is not an unambiguous

=

h

If we are not to become

involved in trivial

this can be done in two ways: p

fixed

X

fixed

or

p÷O

k÷O The first leads, as we have shown several the second, mechanics without

to a classical

and wave optics

anybody

limiting invoked

theory of waves.

except Hamilton

to support

It was possible

for

to exist side by side for more than a century realizing

cases of the same fundamental

them could be perceived

times, to classical mechanics;

that they might be different

theory.

The relation between

only by a mathematician,

since the experiments

them had little to do with each other and were

ordinarily

described

in quite different

connection

of classical physics with quantum physics we must stop

worrying

about which one is right,

remark:

the question physics

languages.

To understand

the

and remember Niels Bohr's profound

can answer

is not what nature is, but

rather what can be said about it. Classical mechanics talking

about nature,

and quantum mechanics

and classical mechanics

terms used in quantum mechanics. warns us that the language take it too literally,

for there are limits of experiments

are embodied in ordinary

in the indeterminacy language without

Bohr's principle confusing physical

transgressing

of complementarity

quantities

apparatus

and how to express physics

them is the subject of

(Park 1974, p. 58).

It is very

to a massive

since the "physical

to think of them as belonging more

than to nature as it "really

volume,

What is a particle? object,

following

situated

of

can never be directly known to us in is."

Much of this book has been concerned with the dynamics particles.

for

These limits

in terms of "the perturbation

any way and hence it is appropriate to our conceptual

if we

to its applicability

by the act of measurement,"

about to be perturbed

is deceptive

in microphysics.

relations,

to explain indeterminacy

quantities"

for

At the same time, quantum mechanics

of classical mechanics

explaining

the results

are languages

provides many of the

In classical physics

at a point or occupying

an exactly definable

trajectory

of

the word refers a very small

in space and time

334

that is determined by external fields. mechanics

To the student of quantum

the concept of particle may seem weakened and vague, but

that is because he is trying to find a way to fit a classical concept into another theory in which its role is quite different. essence,

"In its

it is not a material particle in space and time but,

in a

way, only a symbol on whose introduction the laws of nature assume an especially simple form."

(Heisenberg 1952, p. 62.)

If one understands

this one can stop worrying about which slit a photon passes through in an experiment on diffraction. The laws of nature themselves

are clear and economical descrip-

tions from which one can predict what will happen in experiments have not yet been performed. these descriptions

that

By what sometimes seems a miracle,

are sometimes expressed in such general and

universal mathematical

language that we can feel as Galileo did when

he wrote that in contemplating them we are perceiving God himself perceives

it.

But these descriptions

the contemplation of man.

the world as

are made by and for

They derive from experience,

logical or necessary way, and thus they are not unique; have value for different purposes.

but not in a different ones

This is especially evident when

two theories overlap, when they offer a choice between different ways of describing

the same set of facts.

the subjects discussed in this book. those of classical optics

Such is often the situation with Three languages are used here:

(phase, wavelength, ...); classical mechanics

~osition, momentum, mass, ...); and quantum mechanics, which uses a larger and more mathematical vocabulary.

And, of course,

in the

classical mechanics of elastic media as described in this chapter there are also terms of the classical wave theory from which, by analogy, the wave terminology of optics and quantum physics are derived. does not derive one language

One

from another, but one can make accurate

translations when the subject is one which can be discussed adequately in both, and it often helps our thought to do so. Classical mechanics

talks about a world in which particles are

things which can be described in an objective manner. mechanics

typically answers

the question:

physical system using a certain experimental procedure, probability

Quantum

"If I measure a certain

£hat I will obtain a certain answer?"

what is the

There is a long

and imposing history of debate on how the word "probability" as used here should best be defined.

(See for example Jammer 1966, 1974).

Even knowing this, one often says for example that the ground-state energy of a hydrogen atom "is" -13.6 eV.

We know enough about physics

to know that one will rarely if ever get into trouble saying such a

335

thing, but the language

is not that of quantum mechanics

derived from it; it is simply borrowed,

for convenience,

and cannot be from classical

physics. It is useful

in physics

their classical meanings

really need quantum mechanics situation,

words

to use words

for their elucidation.

from the old languages

but rather as metaphors

like wave and particle

in

in order to help explain phenomena which

or parables.

Here,

in a new

are not to be used literally

In quantum theory the wave is

not a wave in any physical medium but only in a certain mathematical function,

and a particle

that these are metaphors

is not a thing.

have exact and literal meanings. that new theories

are formulated

It is by this linguistic process and progress

of this book has had an opportunity formal relationships

We must always remember

expressed by words which in other contexts is made~ and the reader

to perceive not only the close

between the equations

of the old theories

those of the new, but also the vastly different they describe

the world.

languages

and

in which

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