Classical ill Electrodynamics I Second Edition D. JACKSON J. Vector Formulas a • (bxc) = b • (cxa) = c • (axb) a x (b x c) = (a • c)b-(a • b)c (axb) • (cxd) = (a • c)(b • d)-(a • d)(b • c) VxVi// = V-(Vxa) = Vx(Vxa) = V(V-a)--V2a V = + • (i|/a) a • Vi|/ i|/V • a V = a+ x x (i//a) Viff , and are well-behaved scalar or vector functions, is a three-dimensional volume with volume element d*x, S is a closed twodimensional surface bounding V, with area element da and unit outward normal n at da. A A V | • d 3 x = | • n da (Divergence theorem) 3 Vijjd x = ifmda J J VxA j* d3x = nxA da J = 2 (V i//+ V • Vi|0 d3x [ n-V*ltda J (Green's first identity) = -nda d 2 2 2 (V i//-i|/V ) x j" (<(>Vi(f-i(rV) J (Green's theorem) C In the following S is an open surface and is the contour bounding it, with line element dl. The normal n to S is defined by the right-hand side rule in relation to the sense of the line integral around C. A j* (VxA) = n da • • d\ (Stokes's theorem) j" nxViff da = ^ \\t d\ Classical Electrodynamics Digitized by the Internet Archive 1 in 2013 http://archive.org/details/classicalelectroOOjack_0 Classical Electrodynamics Second Edition JOHN DAVID JACKSON Professor of Physics, University of California, Berkeley JOHN WILEY & SONS, New York • Chichester • Brisbane • Toronto © & Copyright 1962, 1975, by John Wiley Sons, Inc. All rights reserved. Published simultaneously in Canada. Reproduction or translation of any part of this work beyond that permitted by Sections 107 or 108 of the 1976 United States Copyright Act without the permission of the copyright owner is unlawful. Requests for permission or further information should be addressed to the Permissions Department, John Wiley & Sons, Inc. Library of Congress Cataloging in Publication Data: Jackson, John David, 1925Classical electrodynamics. Bibliography: p. Includes index. 1. Electrodynamics. I. Title. QC631.J3 1975 537.6'01 ISBN 0-471-43132-X 75-9962 Printed in the United States of America 10 9 8 To the memory of my father, Walter David Jackson Preface In the thirteen years since the appearance of the first edition, my interest in classical electromagnetism has waxed and waned, but never fallen to zero. The subject is ever fresh. There are always important new applications and examples. The present edition reflects two efforts on my part: the refinement and improvement of material already in the first edition; the addition of new topics (and the omission of a few). The major purposes and emphasis are still the same, but there are exten- A sive changes and additions. major augmentation is the "Introduction and Survey" at the beginning. Topics such as the present experimental limits on the mass of the photon and the status of linear superposition are treated there. The aim is to provide a survey of those basics that are often assumed to be well known when one writes down the Maxwell equations and begins to solve specific examples. Other major changes in the first half of the book include a new treatment of the derivation of the equations of macroscopic electromagnetism from the microscopic description; a discussion of symmetry properties of mechanical and electromagnetic quantities; sections on magnetic monopoles and the quantization condition of Dirac; Stokes's polarization parameters; a unified discussion of the frequency dispersion characteristics of dielectrics, conductors, and plasmas; a discussion of causality and the Kramers-Kronig dispersion relations; a simplified, but still extensive, version of the classic Sommerfeld- Brillouin problem of the arrival of a signal in a dispersive medium (recently verified experimentally); an unusual example of a resonant cavity; the normal- mode expansion of an arbitrary field in a wave guide; and related discussions of sources in a guide or cavity and the transmission and reflection coefficients of flat obstacles in wave guides. Chapter 9, on simple radiating systems and diffraction, has been enlarged to include scattering at long wavelengths (the blue sky, for example) and the optical theorem. The sections on scalar and vectorial diffraction have been improved. vii viii Preface Chapters 11 and 12, on special relativity, have been rewritten almost completely. The old pseudo-Euclidean metric with x4 = ict has been replaced by g^" (with g 00 = + l, g u =-l, i=l, 2, 3). The change of metric necessitated a complete revision and thus permitted substitution of modern experiments and concerns about the experimental basis of the special theory for the time-honored aberration of starlight and the Michelson-Morley experiment. Other aspects have been modernized, too. The extensive treatment of relativistic kinematics of the first edition has been relegated to the problems. In its stead is a discussion of the Lagrangian for the electromagnetic fields, the canonical and symmetric stress-energy tensor, and the Proca Lagrangian for massive photons. Significant alterations in the remaining chapters include a new section on transition radiation, a completely revised (and much more satisfactory) semiclassical treatment of radiation emitted in collisions that stresses momentum transfer instead of impact parameter, and a better derivation of the coupling of multipole fields to their sources. The collection of formulas and page references to special functions on the front and back flyleaves is a much requested addition. Of the 278 problems, 117 (more than 40 per cent) are new. The one area that remains almost completely unchanged is the chapter on magnetohydrodynamics and plasma physics. I regret this. But the book obviously has grown tremendously, and there are available many books devoted exclusively to the subject of plasmas or magnetohydrodynamics. Of minor note is the change from Maxwell's equations and a Green's function to the Maxwell equations and a Green function. The latter boggles some minds, but is in conformity with other usage (Bessel function, for example). It is still Green's theorem, however, because that's whose theorem it is. Work on this edition began in earnest during the first half of 1970 on the occasion of a sabbatical leave spent at Clare Hall and the Cavendish Laboratory in Cambridge. I am grateful to the University of California for the leave and indebted to N. F. Mott for welcoming me as a visitor to the Cavendish Laboratory and to R. J. Eden and A. B. Pippard for my appointment as a Visiting Fellow of Clare Hall. Tangible and intangible evidence at the Cavendish of Maxwell, Rayleigh and Thomson provided inspiration for my task; the stimulation of everyday activities there provided necessary diversion. This new edition has benefited from questions, suggestions, comments and criticism from many students, colleagues, and strangers. Among those to whom I owe some specific debt of gratitude are A. M. Bincer, L. S. Brown, R. W. Brown, E. U. Condon, H. H. Denman, S. Deser, A. J. Dragt, V. L. Fitch, M. B. Halpern, A. Hobson, J. P. Hurley, D. L. Judd, L. T. Kerth, E. Marx, M. Nauenberg, A. B. Pippard, A. M. Portis, R. K. Sachs, W. M. Saslow, R. Schleif, V. L. Telegdi, T. Tredon, E. P. Tryon, V. F. Weisskopf, and Dudley Williams. Especially helpful were D. G. Boulware, R. N. Cahn, Leverett Davis, Jr., K. Gottfried, C. K. Graham, E. M. Purcell, and E. H. Wichmann. I send my thanks and fraternal greetings to all of these people, to the other readers who have written to me, and Preface ix the countless students who have struggled with the problems (and sometimes written asking for solutions to be dispatched before some deadline!). To my mind, the book is better than ever. May each reader benefit and enjoy! Berkeley, California, 1974 J. D. Jackson Preface to the First Edition Classical electromagnetic theory, together with classical and quantum mechanics, forms the core of present-day theoretical training for undergraduate A and graduate physicists. thorough grounding these subjects is a requirement for more advanced or specialized training. Typically the undergraduate program in electricity and magnetism involves two or perhaps three semesters beyond elementary physics, with the emphasis on the fundamental laws, laboratory verification and elaboration of their consequences, circuit analysis, simple wave phenomena, and radiation. The mathematical tools utilized include vector calculus, ordinary differential equa- tions with constant coefficients, Fourier series, and perhaps Fourier or Laplace transforms, partial differential equations, Legendre polynomials, and Bessel functions. As a general rule a two-semester course in electromagnetic theory is given to My beginning graduate students. It is for such a course that my book is designed. aim in teaching a graduate course in electromagnetism is at least threefold. The first aim is to present the basic subject matter as a coherent whole, with emphasis on the unity of electric and magnetic phenomena, both in their physical basis and in the mode of mathematical description. The second, concurrent aim is to develop and utilize a number of topics in mathematical physics which are useful in both electromagnetic theory and wave mechanics. These include Green's theorems and Green's functions, orthonormal expansions, spherical harmonics, A cylindrical and spherical Bessel functions. third and perhaps most important purpose is the presentation of new material, especially on the interaction of relativistic charged particles with electromagnetic fields. In this last area My personal preferences and prejudices enter strongly. choice of topics is governed by what I feel is important and useful for students interested in theoretical physics, experimental nuclear and high-energy physics, and that as yet ill-defined field of plasma physics. The book begins in the traditional manner with electrostatics. The first sb xi xii Preface to the First Edition chapters are devoted to the development of Maxwell's theory of electromagnet- ism. Much of the necessary mathematical apparatus is constructed along the way, especially in Chapters 2 and 3, where boundary-value problems are E discussed thoroughly. The treatment is initially in terms of the electric field D and the magnetic induction B, with the derived macroscopic quantities, and H, introduced by suitable averaging over ensembles of atoms or molecules. In the discussion of dielectrics, simple classical models for atomic polarizability are described, but for magnetic materials no such attempt is made. Partly this omission was a question of space, but truly classical models of magnetic susceptibility are not possible Furthermore, elucidation of the interesting phenomenon of ferromagnetism needs almost a book in itself. The next three chapters (7-9) illustrate various electromagnetic phenomena, mostly of a macroscopic sort. Plane waves in different media, including plasmas as well as dispersion and the propagation of pulses, are treated in Chapter 7. The discussion of wave guides and cavities in Chapter 8 is developed for systems of Q arbitrary cross section, and the problems of attenuation in guides and the of a cavity are handled in a very general way which emphasizes the physical processes involved. The elementary theory of multipole radiation from a localized source and diffraction occupy Chapter 9. Since the simple scalar theory of diffraction is covered in many optics textbooks, as well as undergraduate books on electricity and magnetism, I have presented an improved, although still approximate, theory of diffraction based on vector rather than scalar Green's theorems. The subject of magnetohydrodynamics and plasmas receives increasingly more attention from physicists and astrophysicists. Chapter 10 represents a survey of this complex field with an introduction to the main physical ideas involved. The first nine or ten chapters constitute the basic material of classical A electricity and magnetism. graduate student in physics may be expected to have been exposed to much of this material, perhaps at a somewhat lower level, as an undergraduate. But he obtains a more mature view of it, understands it more deeply, and gains a considerable technical ability in analytic methods of solution when he studies the subject at the level of this book. He is then prepared to go on to more advanced topics. The advanced topics presented here are predominantly those involving the interaction of charged particles with each other and with electromagnetic fields, especially when moving relativistically. The special theory of relativity had its origins in classical electrodynamics. And even after almost 60 years, classical electrodynamics still impresses and delights as a beautiful example of the covariance of physical laws under Lorentz transformations. The special theory of relativity is discussed in Chapter 11, where all the necessary formal apparatus is developed, various kinematic consequences are explored, and the covariance of electrodynamics is established. The next chapter is devoted to relativistic particle kinematics and dynamics. Although the dynamics of charged particles in electromagnetic fields Preface to the First Edition xiii can properly be considered electrodynamics, the reader may wonder whether My such things as kinematic transformations of collision problems can. reply is that these examples occur naturally once one has established the four-vector character of a particle's momentum and energy, that they serve as useful practice in manipulating Lorentz transformations, and that the end results are valuable and often hard to find elsewhere. Chapter 13 on collisions between charged particles emphasizes energy loss and scattering and develops concepts of use in later chapters. Here for the first time in the book I use semiclassical arguments based on the uncertainty principle to obtain approximate quantum-mechanical expressions for energy loss, etc., from the classical results. This approach, so fruitful in the hands of Niels Bohr and E. J. Williams, allows one to see clearly how and when quantum-mechanical effects enter to modify classical considerations. The important subject of emission of radiation by accelerated point charges is discussed in detail in Chapters 14 and 15. Relativistic effects are stressed, and expressions for the frequency and angular dependence of the emitted radiation are developed in sufficient generality for all applications. The examples treated range from synchrotron radiation to bremsstrahlung and radiative beta proc- esses. Cherenkov radiation and the Weizsacker-Williams method of virtual quanta are also discussed. In the atomic and nuclear collision processes semiclassical arguments are again employed to obtain approximate quantum-mechanical results. I lay considerable stress on this point because I feel that it is important for the student to see that radiative effects such as bremsstrahlung are almost A entirely classical in nature, even though involving small-scale collisions. student who meets bremsstrahlung for the first time as an example of a calculation in quantum field theory will not understand its physical basis. Multipole fields form the subject matter of Chapter 16. The expansion of scalar and vector fields in spherical waves is developed from first principles with no restrictions as to the relative dimensions of source and wavelength. Then the properties of electric and magnetic multipole radiation fields are considered. Once the connection to the multipole moments of the source has been made, examples of atomic and nuclear multipole radiation are discussed, as well as a macroscopic source whose dimensions are comparable to a wavelength. The scattering of a plane electromagnetic wave by a spherical object is treated in some detail in order to illustrate a boundary-value problem with vector spherical waves. In the last chapter the difficult problem of radiative reaction is discussed. The treatment is physical, rather than mathematical, with the emphasis on delimiting the areas where approximate radiative corrections are adequate and on finding where and why existing theories fail. The original Abraham-Lorentz theory of the self-force is presented, as well as more recent classical considerations. The book ends with an appendix on units and dimensions and a bibliography. In the appendix I have attempted to show the logical steps involved in setting up xiv Preface to the First Edition a system of units, without haranguing the reader as to the obvious virtues of my choice of units. I have provided two tables which I hope will be useful, one for converting equations and symbols and the other for converting a given quantity of something from so many Gaussian units to so many mks units, and vice versa. The bibliography lists books which I think the reader may find pertinent and useful for reference or additional study. These books are referred to by author's name in the reading lists at the end of each chapter. This book is the outgrowth of a graduate course in classical electrodynamics which I have taught off and on over the past eleven years, at both the University of Illinois and McGill University. I wish to thank my colleagues and students at both institutions for countless helpful remarks and discussions. Special mention must be made of Professor P. R. Wallace of McGill, who gave me the opportunity and encouragement to teach what was then a rather unorthodox course in electromagnetism, and Professors H. W. Wyld and G. Ascoli of Illinois, who have been particularly free with many helpful suggestions on the treatment of various topics. My thanks are also extended to Dr. A. N. Kaufman for reading and commenting on a preliminary version of the manuscript, and to Mr. G. L. Kane for his zealous help in preparing the index. Urbana, Illinois January, 1962 J. D. Jackson Contents Introduction and Survey 1.1 Maxwell Equations in Vacuum, Fields, and Sources 2 1.2 The Inverse Square Law or the Mass of the Photon 5 1.3 Linear Superposition 10 1.4 The Maxwell Equations in Macroscopic Media 13 1.5 Boundary Conditions at Interfaces between Different Media 17 1.6 Some Remarks on Idealizations in Electromagnetism 22 References and Suggested Reading 25 Chapter 1. Introduction to Electrostatics 27 1.1 Coulomb's Law 27 1.2 Electric Field 28 1.3 Gauss's Law 30 1.4 Differential Form of Gauss's Law 32 1.5 Another Equation of Electrostatics and the Scalar Potential 33 1.6 Surface Distributions of Charges and Dipoles and Discontinuities in the Electric Field and Potential 35 1.7 Poisson and Laplace Equations 38 1.8 Green's Theorem 40 1.9 Uniqueness of the Solution with Dirichlet or Neumann Boundary Condi- tions 42 1.10 Formal Solution of Electrostatic Boundary-Value Problem with Green Function 43 1.11 Electrostatic Potential Energy and Energy Density, Capacitance 45 References and Suggested Reading 49 Problems 49 Chapter 2. Boundary-Value Problems in Electrostatics : I 54 2.1 Method of Images 54 2.2 Point Charge in the Presence of a Grounded Conducting Sphere 55 2.3 Point Charge in the Presence of a Charged, Insulated, Conducting Sphere 58 2.4 Point Charge Near a Conducting Sphere at Fixed Potential 60 2.5 Conducting Sphere in a Uniform Electric Field by the Method of Images 60 2.6 Green Function for the Sphere, General Solution for the Potential 62 2.7 Conducting Sphere with Hemispheres at Different Potentials 63 2.8 Orthogonal Functions and Expansions 65 XV xvi Contents 2.9 Separation of Variables, Laplace Equation in Rectangular Coordinates 68 A 2.10 Two-dimensional Potential Problem, Summation of a Fourier Series 71 2.1 1 Fields and Charge Densities in Two-dimensional Corners and Along Edges 75 References and Suggested Reading 78 Problems 79 Chapter 3. Boundary-Value Problems in Electrostatics: II 84 3.1 Laplace Equation in Spherical Coordinates 84 3.2 Legendre Equation and Legendre Polynomials 85 3.3 Boundary-Value Problems with Azimuthal Symmetry 90 3.4 Behavior of Fields in a Conical Hole or near a Sharp Point 94 Y 3.5 Associated Legendre Functions and the Spherical Harmonics lm (0,$) 98 3.6 Addition Theorem for Spherical Harmonics 100 3.7 Laplace Equation in Cylindrical Coordinates, Bessel Functions 102 3.8 Boundary- Value Problems in Cylindrical Coordinates 108 3.9 Expansion of Green Functions in Spherical Coordinates 110 3.10 Solution of Potential Problems with Spherical Green Function Expansion 113 3.11 Expansion of Green Functions in Cylindrical Coordinates 116 3.12 Eigenfunction Expansions for Green Functions 119 3.13 Mixed Boundary Conditions, Conducting Plane with a Circular Hole 121 References and Suggested Reading 127 Problems 128 Chapter 4. Multipoles, Electrostatics of Macroscopic Media, Dielectrics 4.1 Multipole Expansion 4.2 Multipole Expansion of the Energy of a Charge Distribution in an External Field 4.3 Elementary Treatment of Electrostatics with Ponderable Media 4.4 Boundary- Value Problems with Dielectrics 4.5 Molecular Polarizability and Electric Susceptibility 4.6 Models for the Molecular Polarizability 4.7 Electrostatic Energy in Dielectric Media References and Suggested Reading Problems 136 136 142 143 147 152 155 158 163 163 Chapter 5. Magnetostatics 5.1 Introduction and Definitions 5.2 Biot and Savart Law 168 168 169 Contents 5.3 The Differential Equations of Magnetostatics and Ampere's Law 5.4 Vector Potential 5.5 Vector Potential and Magnetic Induction for a Circular Current Loop 5.6 Magnetic Fields of a Localized Current Distribution, Magnetic Moment 5.7 Force and Torque on and Energy of a Localized Current Distribution in an External Magnetic Induction H 5.8 Macroscopic Equations, Boundary Conditions on B and 5.9 Methods of Solving Boundary-Value Problems in Magnetostatics 5.10 Uniformly Magnetized Sphere 5.11 Magnetized Sphere in an External Field, Permanent Magnets 5.12 Magnetic Shielding, Spherical Shell of Permeable Material in a Uniform Field 5.13 Effect of a Circular Hole in a Perfectly Conducting Plane with an Asymptotically Uniform Tangential Magnetic Field on One Side References and Suggested Reading Problems xvii 173 175 177 180 184 187 191 194 197 199 201 204 205 Chapter 6. Time-Varying Fields, Maxwell Equations, Conservation Laws 6.1 Faraday's Law of Induction 6.2 Energy in the Magnetic Field 6.3 Maxwell's Displacement Current, Maxwell Equations 6.4 Vector and Scalar Potentials 6.5 Gauge Transformations, Lorentz Gauge, Coulomb Gauge 6.6 Green Functions for the Wave Equation 6.7 Derivation of the Equations of Macroscopic Electromagnetism 6.8 Poynting's Theorem and Conservation of Energy and Momentum for a System of Charged Particles and Electromagnetic Fields 6.9 Conservation Laws for Macroscopic Media 6.10 Poynting's Theorem for Harmonic Fields, Field Definitions of Impedance and Admittance 6.11 Transformation Properties of Electromagnetic Fields and Sources under Rotations, Spatial Reflections, and Time Reversal 6.12 On the Question of Magnetic Monopoles 6.13 Discussion of the Dirac Quantization Condition References and Suggested Reading Problems 209 210 213 217 219 220 223 226 236 240 241 245 251 254 260 261 Chapter 7. Plane Electromagnetic Waves and Wave Propagation 269 7.1 Plane Waves in a Nonconducting Medium 269 7.2 Linear and Circular Polarization, Stokes Parameters 273 xviii Contents 7.3 Reflection and Refraction of Electromagnetic Waves at a Plane Interface between Dielectrics 7.4 Polarization by Reflection and Total Internal Reflection 7.5 Frequency Dispersion Characteristics of Dielectrics, Conductors, and Plasmas 7.6 Simplified Model of Propagation in the Ionosphere and Magnetosphere 7.7 Waves in a Conducting or Dissipative Medium 7.8 Superposition of Waves in One Dimension, Group Velocity 7.9 Illustration of the Spreading of a Pulse as It Propagates in a Dispersive Medium D 7.10 Causality in the Connection between and E, Kramers-Kronig Relations 7.11 Arrival of a Signal After Propagation Through a Dispersive Medium References and Suggested Reading Problems 278 282 284 292 296 299 303 306 313 326 327 Chapter 8. Wave Guides and Resonant Cavities 8.1 Fields at the Surface of and within a Conductor 8.2 Cylindrical Cavities and Wave Guides 8.3 Wave Guides 8.4 Modes in a Rectangular Wave Guide 8.5 Energy Flow and Attenuation in Wave Guides 8.6 Perturbation of Boundary Conditions 8.7 Resonant Cavities Q 8.8 Power Losses in a Cavity, of a Cavity 8.9 Earth and Ionosphere as a Resonant Cavity, Schumann Resonances 8.10 Dielectric Wave Guides 8.11 Expansion in Normal Modes, Fields Generated by a Localized Source in Guide 8.12 Reflection and Transmission by Plane Diaphragms, Variational Approxi- mation 8.13 Impedance of a Flat Strip Parallel to the Electric Field in a Rectangular Wave Guide References and Suggested Reading Problems 334 335 339 343 345 346 350 353 356 360 364 369 375 380 384 385 Chapter 9. Simple Radiating Systems, Scattering, and Diffraction 9.1 Fields and Radiation of a Localized Oscillating Source 9.2 Electric Dipole Fields and Radiation 9.3 Magnetic Dipole and Electric Quadrupole Fields 9.4 Center-fed Linear Antenna 9.5 Multipole Expansion for Localized Source or Aperture in Wave Guide 391 391 394 397 401 405 Contents xix 9.6 Scattering at Long Wavelengths 9.7 Perturbation Theory of Scattering, Rayleigh's Explanation of the Blue Sky, Scattering by Gases and Liquids 9.8 Scalar Diffraction Theory 9.9 Vector Equivalents of Kirchhoff Integral 9.10 Vectorial Diffraction Theory 9.11 Babinet's Principle of Complementary Screens 9.12 Diffraction by a Circular Aperture, Remarks on Small Apertures 9.13 Scattering in the Short-Wavelength Limit 9.14 Optical Theorem and Related Matters References and Suggested Reading Problems 411 418 427 432 435 438 441 447 453 459 460 Chapter 10. Magnetohydrodynamics and Plasma Physics 10.1 10.2 10.3 10.4 10.5 10.6 10.7 10.8 10.9 Introduction and Definitions Magnetohydrodynamic Equations Magnetic Diffusion, Viscosity, and Pressure Magnetohydrodynamic Flow between Boundaries with Crossed Electric and Magnetic Fields Pinch Effect Instabilities in a Pinched Plasma Column Magnetohydrodynamic Waves Plasma Oscillations Short-wavelength Limit on Plasma Oscillations and the Debye Screening Distance References and Suggested Reading Problems 469 469 471 472 475 479 482 485 490 494 497 498 Chapter 11. Special Theory of Relativity 11.1 The Situation before 1900, Einstein's Two Postulates 11.2 Some Recent Experiments 11.3 Lorentz Transformations and Basic Kinematic Results of Special Relativity 11.4 11.5 11.6 Addition of Velocities, Four- Velocity Relativistic Momentum and Energy of a Particle Mathematical Properties of the Space-Time of Special Relativity 11.7 Matrix Representation of Lorentz Transformations, Infinitesimal Generators 11.8 Thomas Precession 11.9 Invariance of Electric Charge, Covariance of Electrodynamics 11.10 Transformation of Electromagnetic Fields 11.11 Relativistic Equation of Motion for Spin in Uniform or Slowly Varying External Fields 503 504 507 515 522 525 532 536 541 547 552 556 xx Contents 11.12 Note on Notation and Units in Relativistic Kinematics References and Suggested Reading Problems 560 561 562 Chapter 12. Dynamics of Relativistic Particles and Electromagnetic Fields 12.1 Lagrangian and Hamiltonian for a Relativistic Charged Particle in External Electromagnetic Fields 12.2 On the Question of Obtaining the Magnetic Field, Magnetic Force, and the Maxwell Equations from Coulomb's law and Special Relativity 12.3 Motion in a Uniform, Static, Magnetic Field 12.4 Motion in Combined Uniform, Static, Electric and Magnetic Fields 12.5 Particle Drifts in Nonuniform, Static Magnetic Fields 12.6 Adiabatic Invariance of Flux through Orbit of Particle 12.7 Lowest-Order Relativistic Corrections to the Lagrangian for Interacting Charged Particles, the Darwin Lagrangian 12.8 Lagrangian for the Electromagnetic Field 12.9 Proca Lagrangian, Photon Mass Effects 12.10 Canonical and Symmetric Stress Tensors, Conservation Laws 12.11 Solution of the Wave Equation in Covariant Form, Invariant Green Functions References and Suggested Reading Problems 571 572 578 581 582 584 588 593 595 597 601 608 612 613 13.1 13.2 13.3 13.4 13.5 13.6 13.7 13.8 Chapter 13. Collisions between Charged Particles, Energy Loss, and Scattering Energy Transfer in a Coulomb Collision Energy Transfer to a Harmonically Bound Charge Classical and Quantum-Mechanical Energy-loss Formulas Density Effect in Collision Energy Loss Cherenkov Radiation Energy Loss in an Electronic Plasma Elastic Scattering of Fast Particles by Atoms Mean Square Angle of Scattering and the Angular Distribution of Multiple Scattering References and Suggested Reading Problems 618 619 623 626 632 638 641 643 647 651 651 14.1 14.2 Chapter 14. Radiation by Moving Charges Lienard-Wiechert Potentials and Fields for a Point Charge Total Power Radiated by an Accelerated Charge: Larmor's Formula and its Relativistic Generalization 654 654 658 Contents 14.3 14.4 14.5 14.6 14.7 14.8 14.9 Angular Distribution of Radiation Emitted by an Accelerated Charge Radiation Emitted by a Charge in Arbitrary, Extremely Relativistic Motion Distribution in Frequency and Angle of Energy Radiated by Accelerated Charges Frequency Spectrum of Radiation Emitted by a Relativistic Charged Particle in Instantaneously Circular Motion Thomson Scattering of Radiation Scattering of Radiation by Quasi-Free Charges, Coherent and Incoherent Scattering Transition Radiation References and Suggested Reading Problems xxi 662 665 668 672 679 683 685 693 694 15.1 15.2 15.3 15.4 15.5 15.6 15.7 Chapter 15. Bremsstrahlung, Method of Virtual Quanta, Radiative Beta Processes Radiation Emitted during Collisions Bremsstrahlung in Coulomb Collisions Screening Effects, Relativistic Radiative Energy Loss Weizsacker- Williams Method of Virtual Quanta Bremsstrahlung as the Scattering of Virtual Quanta Radiation Emitted During Beta Decay — Radiation Emitted During Orbital-Electron Capture Disappearance of Charge and Magnetic Moment References and Suggested Reading Problems 701 702 708 715 719 724 725 727 733 733 Chapter 16. Multipole Fields 16.1 Basic Spherical Wave Solutions of the Scalar Wave Equation 16.2 Multipole Expansion of the Electromagnetic Fields 16.3 Properties of Multipole Fields, Energy and Angular Momentum of Mul- tipole Radiation 16.4 Angular Distribution of Multipole Radiation 16.5 Sources of Multipole Radiation, Multipole Moments 16.6 Multipole Radiation in Atomic and Nuclear Systems 16.7 Radiation from a Linear, Center-Fed Antenna 16.8 Spherical Wave Expansion of a Vector Plane Wave 16.9 Scattering of Electromagnetic Waves by a Sphere 16.10 Boundary-Value Problems with Multipole Fields References and Suggested Reading Problems 739 739 744 747 752 755 758 763 767 769 775 776 776 xxii Contents 17.1 17.2 17.3 17.4 17.5 17.6 17.7 17.8 Chapter 17. Radiation Damping, Self-Fields of a Particle, Scattering and Absorption of Radiation by a Bound System Introductory Considerations Radiative Reaction Force from Conservation of Energy Abraham-Lorentz Evaluation of the Self-Force Difficulties with the Abraham-Lorentz Model Covariant Definitions of Electromagnetic Energy and Momentum Integrodifferential Equation of Motion, Including Radiation Damping Line Breadth and Level Shift of an Oscillator Scattering and Absorption of Radiation by an Oscillator References and Suggested Reading Problems 780 780 783 786 790 791 796 798 801 806 807 Appendix on Units and Dimensions 1 Units and Dimensions, Basic Units and Derived Units 2 Electromagnetic Units and Equations 3 Various Systems of Electromagnetic Units 4 Conversion of Equations and Amounts between Gaussian Units and MKSA Units 811 811 813 816 817 Bibliography 822 Index 828 Classical Electrodynamics Introduction and Survey Although amber and lodestone were known to the ancient Greeks, electrodynamics developed as a quantitative subject in less than a hundred years. Cavendish's remarkable experiments in electrostatics were done from 1771 to 1773. Coulomb's monumental researches began to be published in 1785. This marked the beginning of quantitative research in electricity and magnetism on a worldwide scale. Fifty years later Faraday was studying the effects of timevarying currents and magnetic fields. By 1864 Maxwell had published his famous paper on a dynamical theory of the electromagnetic field. The story of the development of our understanding of electricity and magnetism and of light is, of course, much longer and richer than the mention of a few names from one century would indicate. For a detailed account of the fascinating history, the reader should consult the authoritative volumes by A Whittaker* briefer account, with emphasis on optical phenomena, appears at the beginning of Born and Wolf. This book is self-contained in that, though some mathematical background (vector calculus, differential equations) is assumed, the subject of electrodynamics is developed from its beginnings in electrostatics. Most readers are not coming to the subject for the first time, however. The purpose of this introduction is therefore not to set the stage for a discussion of Coulomb's law and other basics, but rather to present a review and a survey of classical electromagnetism. Questions such as the current accuracy of the inverse square law of force (mass of the photon), the limits of validity of the principle of linear superposition, the effects of discreteness of charge and of energy differences are discussed. "Bread and butter" topics such as the boundary conditions for macroscopic fields at surfaces between different media and at conductors are also treated. The aim is to set classical electromagnetism in context, to indicate * Italicized surnames are used to denote books that are cited fully in the Bibliography. 1 2 Classical Electrodynamics Sect. 1.1 its domain of validity, and to elucidate some of the idealizations that it contains. Some results from later in the book and some nonclassical ideas are used in the course of the discussion. Certainly a reader beginning electromagnetism for the first time will not follow all the arguments or see their significance. It is intended, however, that for others this introduction will serve as a springboard into the later parts of the book, beyond Chapter 5, as well as a reminder of how the subject stands as an experimental science. 1.1 Maxwell Equations in Vacuum, Fields, and Sources The equations governing electromagnetic phenomena are the Maxwell equations, which for sources in vacuum are V • E = 47rp C dt C (1.1) VxE + i^ = C dt VB = Implicit in the Maxwell equations is the continuity equation for charge density and current density, ^+V-J = dt (v 1.2) ' This follows from combining the time derivative of the first equation in (1 . 1) with the divergence of the second equation. Also essential for consideration of charged particle motion is the Lorentz force equation, F=q(E+^xB) (1.3) that gives the force acting on a point charge q in the presence of electromagnetic fields. These equations have been written in Gaussian units, the system of electromagnetic units used in this book. (Units and dimensions are discussed in the Appendix.) The Maxwell equations are displayed in the commoner systems of units in Table 2 of the Appendix. Apart from the fields E and B and the sources p and J, the equations involve a parameter c. This quantity has the dimensions of velocity and is the speed of light in vacuum. It is fundamental to all electromagnetic and relativistic phenomena. Based on our units of length and time, presently defined separately in terms of two different atomic transitions, as Sect. 1.1 Introduction and Survey 3 discussed in the Appendix, this parameter has the empirical value c = 299,792,456.2± 1 . 1 meters/second* This result comes from an experiment using a highly stabilized helium-neon laser in which both the frequency and the wavelength were measured (3.39 fxm methane-stabilized line). In passing we note that the precision here is such that the present definition of the meter is likely to be replaced by one using c and the second. Other evidence [see Section 11.2(c)] indicates that to high accuracy the speed of light in vacuum is independent of frequency from very low frequencies to at least i^ 1024 Hz (4GeV photons). For most practical purposes we can approximate c — 3xl0 8 m/sec or to be considerably more accurate, c = 2.998 x10 s m/sec. The electric and magnetic fields E and B in (1.1) were originally introduced by means of the force equation (1.3). In Coulomb's experiments forces acting between localized distributions of charge were observed. There it is found useful (see Section 1.2) to introduce the electric field E as the force per unit charge. Similarly, in Ampere's experiments the mutual forces of current-carrying loops were studied (see Section 5.2). With the identification of NAqv as a current in a A N conductor of cross-sectional area with charge carriers per unit volume moving at velocity v, we see that B in (1.3) is defined in magnitude as a force per unit current. Although E and B thus first appear just as convenient replacements for forces produced by distributions of charge and current, they have other important aspects. First, their introduction decouples conceptually the sources from the test bodies experiencing electromagnetic forces. If the fields E and B from two source distributions are the same at a given point in space, the force acting on a test charge or current at that point will be the same, regardless of how different the source distributions are. This gives E and B in (1.3) meaning in their own right, independent of the sources. Second, electromagnetic fields can exist in regions of space where there are no sources. They can carry energy, momentum, and angular momentum and so have an existence totally independ- ent of charges and currents. In fact, though there are recurring attempts to eliminate explicit reference to the fields in favor of action-at-a-distance descrip- tions of the interaction of charged particles, the concept of the electromagnetic field is one of the most fruitful ideas of physics, both classically and quantum mechanically. The concept of E and B as ordinary fields is a classical notion. It can be thought of as the classical limit (limit of large quantum numbers) of a quantum mechanical description in terms of real or virtual photons. In the domain of macroscopic phenomena and even some atomic phenomena the discrete photon aspect of the electromagnetic field can usually be ignored or at least glossed over. For example, 1 meter from a 100 watt light bulb, the root mean square *K. Evenson et al., Phys. Rev. Letters 29, 1346 (1972). 4 Classical Electrodynamics Sect. 1.1 electric field is of the order of 0.5 volts/cm and there are of the order of 10 15 FM visible photons/cm2 x sec. Similarly, an isotropic antenna with a power of 100 watts at 8 10 Hz produces a r.m.s. electric field of only 5 microvolts/cm at a distance of 100 kilometers, but this still corresponds to a flux of 10 12 photons/cm2 x sec, or about 9 10 photons in a volume of 1 wavelength cubed m (27 3 ) at that distance. Ordinarily an apparatus will not be sensible to the individual photons; the cumulative effect of many photons emitted or absorbed will appear as a continuous, macroscopically observable response. Then a completely classical description in terms of the Maxwell equations is permitted and is appropriate. How is one to decide a priori when a classical description of the electromag- netic fields is adequate? Some sophistication is occasionally needed, but the following is usually a sufficient criterion: When the number of photons involved can be taken as large but the momentum carried by an individual photon is small compared to the momentum of the material system, then the response of the material system can be determined adequately from a classical description of the FM electromagnetic fields. For example, each 10 8 Hz photon emitted by our A antenna gives it an impulse of only 2.2xl0~ 34 newton-seconds. classical treatment is surely adequate. Again, the scattering of light by a free electron is governed by the classical Thomson formula (Section 14.7) at low frequencies, but by the laws of the Compton effect as the momentum hoj/c of the incident photon becomes significant compared to mc. The photoelectric effect is nonclas- sical for the matter system, since the quasi-free electrons in the metal change their individual energies by amounts equal to those of the absorbed photons, but the photoelectric current can be calculated quantum mechanically for the electrons using a classical description of the electromagnetic fields. The quantum nature of the electromagnetic fields must, on the other hand, be taken into account in spontaneous emission of radiation by atoms, or by any other system where there are no photons present initially and only a small number of photons present finally. The average behavior may still be describable in essentially classical terms, basically because of conservation of energy and momentum. An example is the classical treatment (Section 17.2) of the cascading of a charged particle down through the orbits of an attractive potential. At high particle quantum numbers a classical description of particle motion is adequate, and the secular changes in energy and angular momentum can be calculated classically from the radiation reaction because the energies of the successive photons emitted are small compared to the kinetic or potential energy of the orbiting particle. The sources in (1.1) are p(x, t), the electric charge density, and J(x, t), the electric current density. In classical electromagnetism they are assumed to be continuous distributions in x, although we consider from time to time localized distributions that can be approximated by points. The magnitudes of these point charges are assumed to be completely arbitrary, but are known to be restricted in Sect. 1.2 Introduction and Survey 5 reality to discrete values. The basic unit of charge is the magnitude of the charge on the electron, |qe | = 4.803250(21) x 10" 10 esu = 1.6021917(70)x -19 10 coulomb where the errors in the last two decimal places are shown in parentheses. The charges on the proton and on all presently known particles or systems of particles are integral multiples of this basic unit. The experimental accuracy with which it is known that the multiples are exactly integers is phenomenal (better than 1 part in 10 20 ). The experiments are discussed in Section 11.9 where the question of the Lorentz invariance of charge is also treated. The discreteness of electric charge does not need to be considered in most A macroscopic applications. 1 microfarad capacitor at a potential of 150 volts, A for example, has a total of 10 15 elementary charges on each electrode. few A thousand electrons more or less would not be noticed. current of 1 microampere corresponds to 6.2 x 10 12 elementary charges/second. There are, of course, some delicate macroscopic or almost macroscopic experiments in which the discreteness of charge enters. Millikan's famous oil drop experiment is one. His droplets were typically 10"4 cm in radius and had a few or few tens of elementary charges on them. There is a lack of symmetry in the appearance of the source terms in Maxwell equations (1.1). The first two equations have sources; the second two do not. This reflects the experimental absence of magnetic charges and currents. Actually, as is shown in Section 6.12, particles could have magnetic as well as electric charge. If all particles in nature had the same ratio of magnetic to electric charge, the fields and sources could be redefined in such a way that the usual Maxwell equations (1.1) emerge. In this sense it is somewhat a matter of convention to say that no magnetic charges or currents exist. Throughout most of this book it is assumed that only electric charges and currents act in the Maxwell equations, but some consequences of the existence of a particle with a different magnetic to electric charge ratio, for example, a magnetic monopole, are described in Chapter 6. 1.2 The Inverse Square Law or the Mass of the Photon The distance dependence of the electrostatic law of force was shown quantitatively by Cavendish and Coulomb to be an inverse square law. Through Gauss's law and the divergence theorem (see Sections 1.3 and 1.4) this leads to the first of the Maxwell equations (1.1). The original experiments had an accuracy of only a few percent and, furthermore, were at a laboratory length scale. Experiments at higher precision and involving different regimes of size have been performed 6 Classical Electrodynamics Sect. 1.2 over the years. It is now customary to quote the tests of the inverse square law in one of two ways: (a) Assume that the force varies as 2+£ l/r and quote a value or limit for e. (b) Assume that the electrostatic potential has the "Yukawa" form (see Section 12.9), _1 _tir re and quote a value or limit for fx or 1 /m" . Since m = lJL myC/h, where y is the assumed mass of the photon, the test of the inverse square law is sometimes phrased in terms of an upper limit on tru,. m Laboratory experiments usually give e and perhaps fx or 7 ; geomagnetic m experiments give jut or 7 . The original experiment with concentric spheres by Cavendish* in 1772 gave an upper limit on e of |e|<0.02. His apparatus is shown in Fig. 1.1. About 100 years later Maxwell performed a very similar experiment at Cambridget and set an upper limit of |e|<5xl0~ 5 . Two other noteworthy laboratory experiments based on Gauss's law are those of Plimpton and Lawton,$ which gave |e|< A 2x 10~ 9 , and the recent one of Williams, Faller, and Hill.§ schematic drawing of the apparatus of the latter experiment is shown in Fig. 1.2. Though not a static experiment (v—4x 106 Hz), the basic idea is almost the same as Cavendish's. He looked for a charge on the inner sphere after it had been brought into electrical contact with the charged outer sphere and then disconnected; he found none. Williams, Faller, and Hill looked for a voltage difference between two concentric shells when the outer one was subjected to an alternating voltage of ±10 kV with respect to ground. Their sensitivity was such that a voltage difference of less than V 10" 12 could have been detected. Their null result, when interpreted by means of the Proca equations (Section 12.9), gives a limit of e = (2.7±3.1)x 10~ 16 . Measurements of the earth's magnetic field, both on the surface and out from the surface by satellite observation, permit the best limits to be set on e or m equivalently the photon mass 7 . The geophysical and also the laboratory observations are discussed in the reviews by Kobzarev and Okun' and by Goldhaber and Nieto, listed at the end of this introduction. The surface measurements of the earth's magnetic field give slightly the best value (see Problem 12.14), namely, m7 <4xl0-48 gm or /x-^10 10 cm m For comparison, the electron mass is e = 9.1x 10"28 gm. The laboratory experi- ment of Williams, Faller, and Hill can be interpreted as setting a limit m-y<1.6x -47 10 gm, only a factor of 4 poorer than the geomagnetic limit. * H. Cavendish, Electrical Researches, ed. J. C. Maxwell, Cambridge University Press (1879), pp. 104-113. t Ibid., see note 19. $S. J. Plimpton and W. E. Lawton, Phys. Rev. 50, 1066 (1936). § E. R. Williams, J. E. Faller, and H. A. Hill, Phys. Rev. Letters 26, 721 (1971). c Fig. 1.1 Cavendish's apparatus for establishing the inverse square law of electrostatics. Top, facsimile of Cavendish's own sketch; bottom, line drawing by a draughtsman. The inner globe is 12.1 inches in diameter, the hollow pasteboard hemispheres slightly larger. Both globe and hemispheres were covered with tinfoil "to make them the more perfect conductors of electricity." (Figures reproduced by permission of the Cambridge Univer- sity Press.) 7 Fig. 1.2 Schematic diagram of the "Cavendish" experiment of Williams, Faller, and A MHz Hill. The concentric icosahedrons are conducting shells. 4 voltage of 10 kV peak is applied between shells 5 and 4. Shell 4 and its contiguous shells 2 and 3 are roughly 1.5 8 Sect. 1.2 Introduction and Survey 9 A rough limit on the photon mass can be set quite easily by noting the existence of very low frequency modes in the earth-ionosphere resonant cavity (Schumann resonances, discussed in Section 8.9). The double Einstein relation, hv= 2 rriyC , suggests that the photon mass must satisfy an inequality, m-,110), both in the atomic energy levels and in the nuclear Coulomb energy.* At the present time there is no evidence for any classical nonlinear behavior of vacuum fields at short distances. There is a quantum-mechanical nonlinearity of electromagnetic fields that arises because the uncertainty principle permits the momentary creation of an electron-positron pair by two photons and the subsequent disappearance of the pair with the emission of two different photons, as indicated schematically in Fig. 1.3. This process is called the scattering of light by light. t The two incident plane waves eikl '*~k°1< and e*2 ~ x i0i2t do not merely add coherently, as expected with linear superposition, but interact and (with small probability) transform into two different plane waves with wave vectors k3 and k4 . This nonlinear feature of quantum electrodynamics can be expressed, at least for slowly varying fields, in * An investigation of the effect of a Born-Infeld type of nonlinearity on the atomic energy levels in superheavy elements has been made by J. Rafelski, W. Greiner, and L. P. Fulcher, Nuovo Cimento 13B, 135 (1973). t When two of the photons in Fig. 1.3 are virtual photons representing interaction to second order with a static nuclear Coulomb field, the process is known as Delbriick scattering. See Section 15.8 of J. M. Jauch and F. Rohrlich, The Theory of Photons and Electrons, Addison-Wesley, Reading, Mass. (1955). 12 Classical Electrodynamics Sect. 1.3 terms of electric and magnetic permeability tensors of the vacuum: where X E Di = € ik k , k X Bi = j^ikHk k = + - + 7B B eik 5ik g4ft A- 4 7 [2(E 2 2 )fi» k ]+ t k ••• -£ 7£ £ = + u,k Sik 4J eh 47 71?n c [2(B 2 + 2 )§ik ]+- i k •• m Here e and are the charge and mass of the electron. These results were first We obtained by Euler and Kockel in 1935.* observe that in the classical limit (h—>0), these nonlinear effects go to zero. Comparison with the classical Born-Infeld expression (1.4) shows that for small nonlinearities, the quantum- mechanical field strength plays a role analogous to the Born-Infeld parameter b. Here r = e 2/mc 2 — 2.8 x 10~ 13 cm is the classical electron radius and e/r 2 = 1.8x 10 18 volts/cm is the electric field at the surface of such a classical electron. Two comments in passing: (a) the eik and /mik in (1.5) are approximations that fail for field strengths approaching bq or when the fields vary too rapidly in space or time (h/mc setting the critical scale of length and 2 fi/mc of time); (b) the chance numerical coincidence of bq and e/2r 2 is suggestive, but probably not significant since bq involves Planck's constant h. In analogy with the polarization P = (D-E)/47T, we speak of the field- dependent terms in (1.5) as vacuum polarization effects. In addition to the scattering of light by light or Delbriick scattering, vacuum polarization causes very small shifts in atomic energy levels. The dominant contribution involves a virtual electron-positron pair, just as in Fig. 1.3, but with only two photon lines instead of four. If the photons are real, the process contributes to the mass of the photon and is decreed to vanish. If the photons are virtual, however, as in the electromagnetic interaction between a nucleus and an orbiting electron, or indeed for any externally applied field, the creation and annihilation of a virtual electron-positron pair from time to time causes observable effects. The first effect is a reduction in the observed charge of the nucleus from its value in the absence of interaction. This renormalization of the bare charge can be under- stood in simple electrostatic terms. The electron of the pair is attracted and the positron repelled by the positive charge of the nucleus. This vacuum polarization effect causes the nuclear charge to be screened and to appear less in magnitude than before. Since charged particles are always surrounded by this cloud of virtual electron-positron pairs, their observed charges must be interpreted as *H. Euler and B. Kockel, Naturwiss. 23, 246 (1935). Sect. 1.4 Introduction and Survey 13 their renormalized charges. Beyond the unobservable renormalization of charge, the vacuum polarization induces a charge density within distances of the order of h/2mc or less that causes the electrostatic potential energy between two charges to be greater in magnitude than the Coulomb potential energy. This causes a very small shift in atomic energy levels in the direction of increased binding. The lowest order added potential is proportional to aqext , where a = e 2/hc= 1/137 and qext is the charge producing the external field. It is thus linear in the external field and produces a small linear modification of the Maxwell equations. It is nonlinear in the sense that the strength of the effect depends on the fine structure constant times the external field and so involves the third power of charge in the added potential. Higher order effects, such as Fig. 1.3 with three of the photons corresponding to the third power of the external field, give totally nonlinear vacuum polarization effects. In electronic atoms the vacuum polarization effects are a small part of the total radiative correction, but are still observable. In mu-mesic atoms, the effects are relatively larger because the atomic orbits are mainly inside the region where the potential is modified. Then vacuum polarization effects are important in their own right. The final conclusion about linear superposition of fields in vacuum is that in the classical domain of sizes and attainable field strengths there is abundant evidence for the validity of linear superposition and no evidence against it. In the atomic and subatomic domain there are small quantum-mechanical nonlinear effects whose origins are in the coupling between charged particles and the electromagnetic field. They modify the interactions between charged particles and cause interactions between electromagnetic fields even if physical particles are absent. 1.4 The Maxwell Equations in Macroscopic Media So far we have considered electromagnetic fields and sources in vacuum. The Maxwell equations (1.1) for the electric and magnetic fields E and B can be thought of as equations giving the fields everywhere in space, provided all the sources p and J are specified. For a small number of definite sources, determina- tion of the fields is a tractable problem, but for macroscopic aggregates of matter the solution of the equations is almost impossible. There are two aspects here. One is that the number of individual sources, the charged particles in every atom and nucleus, is prohibitively large. The other aspect is that for macroscopic observations the detailed behavior of the fields, with their drastic variations in space over atomic distances, is not relevant. What is relevant is the average of a field or a source over a volume large compared to the volume occupied by a We single atom or molecule. call such averaged quantities the macroscopic fields and macroscopic sources. It is shown in detail in Section 6.7 that the macroscopic 14 Classical Electrodynamics Maxwell equations are V-D = 4ttp ' Sect. 1.4 c dt c (1.6) VxE+±^ = c dt VB = where E and B are the averaged E and B of the microscopic or vacuum Maxwell D equations (1.1). The two new field quantities and H, usually called the electric displacement and magnetic field (B is then called the magnetic induction), have components given by V , a* / Hu = B c< -4t7(Mq +- • •) The quantities P, M, Q'^, and similar higher order objects, represent the macroscopically averaged electric dipole, magnetic dipole, and electric quadrupole, and higher moment densities of the material medium in the presence of applied fields. Similarly, the charge and current densities p and J are macroscopic averages of the "free" charge and current densities in the medium. The bound charges and currents appear in the equations via P, M, and Qap. The macroscopic Maxwell equations (1.6) are a set of eight equations involving the components of the four fields E, B, D, and H. The four homogeneous equations can be solved formally by expressing E and B in terms of the scalar potential and the vector potential A, but the inhomogeneous equations cannot D H be solved until the derived fields and are known in terms of E and B. These connections, which are implicit in (1.7), are known as constitutive relations, D = D[E, B] H = H[E, B] (1.8) In addition, for conducting media there is the generalized Ohm's law, J = J[E,B] (1.8') The square brackets are intended to signify that the connections are not necessarily simple and may depend on past history (hysteresis), may be nonlinear, etc. In most materials the electric quadrupole and higher terms in (1.7) are M completely negligible. Only the electric and magnetic polarizations P and are significant. This does not mean, however, that the constitutive relations are then simple. There is a tremendous diversity in the electric and magnetic properties of Sect. 1.4 Introduction and Survey 15 matter, especially in crystalline solids, with ferroelectric and ferromagnetic M materials having nonzero P or in the absence of applied fields, as well as more ordinary dielectric, diamagnetic, and paramagnetic substances. The study of these properties is one of the provinces of solid-state physics. In this book we touch only very briefly and superficially on some more elementary aspects. Solid-state books such as Kittel should be consulted for a more systematic and extensive treatment of the electromagnetic properties of bulk matter. In substances other than ferroelectrics or ferromagnets, for weak enough fields the presence of an applied electric or magnetic field induces an electric or We magnetic polarization proportional to the magnitude of the applied field. then say that the response of the medium is linear and write the Cartesian D H components of and in the form,* The tensors €aP and iA'af} are called the electric permittivity or dielectric tensor and the inverse magnetic permeability tensor. They summarize the linear response of the medium and are dependent on the molecular and perhaps crystalline structure of the material, as well as bulk properties like density and temperature. For simple materials the linear response is often isotropic in space. D Then €a3 and /ll^ are diagonal with all three elements equal, and = eE, H=fx'B. To be generally correct Eqs. (1.9) should be understood as holding for the Fourier transforms in space and time of the field quantities. This is because the basic linear D H connection between and E (or and B) can be nonlocal. Thus D Z = a (x, Jdvjdt'e^x', t')E,(x-x', t-t') (1.10) where €qP (x', t') may be localized around x' = 0, = t' 0, but is nonvanishing for some range D E away from the origin. If we introduce the Fourier transforms a (k, to), p (k, to), and €a0 (k, a>) through Oe-— /(k, a>) = Jd3 xjdt/(x, Eq. (1.9) can be written in terms of the Fourier transforms as D = £ a (k, to) ea3 (k, l. Bismuth, the most diamagnetic substance known, has — (/Xaa— 1) 1.8x 10~ 4 . Thus diamagnetism is a very small effect. If the basic atomic unit of the material has a net angular momentum from unpaired electrons, the substance is paramagnetic. The magnetic moment of the odd electron is aligned parallel to the applied field. Hence jLtaa i, 2o>2 , + o>i co2 , coi-o)2 , as well as the original co, and w2 . From cubic and higher nonlinear terms an even richer spectrum of frequencies can be generated. With the development of lasers, nonlinear behavior of this sort has become a research area of its own, called nonlinear optics, and also a laboratory tool. At present, lasers are capable of generating light pulses with peak electric fields approaching 10 10 or even 10 11 volts/cm. The static electric field experienced by the electron in its orbit in a hydrogen atom is e/a 2 — 5xl0 9 volts/cm. Such laser fields are thus seen to be capable of driving atomic oscillators well into their nonlinear regime, capable indeed of destroying the sample under study! References to some of the literature of this specialized field are given in the suggested reading at the end of this introduction. The reader of this book will have to be content with basically linear phenomena. 1.5 Boundary Conditions at Interfaces between Different Media The Maxwell equations (1.6) are differential equations applying locally at each point in space-time (x, t). By means of the divergence theorem and Stokes's V theorem, they can be cast in integral form. Let be a finite volume in space, S the closed surface (or surfaces) bounding it, da an element of area on the surface, and n a unit normal to the surface at da pointing outward from the enclosed volume. Then the divergence theorem applied to the first and last equations of (1.6) yields the integral statements (j> D-nda = 47r| pd 3 x (1.13) (j>B-nda = (1.14) * Handbook of Chemistry and Physics, ed. R. C. Weast, Chemical Rubber Publishing House, Cleveland, Ohio. American Institute of Physics Handbook, ed. D. E. Gray, McGraw Hill, New York, 3rd edition (1972), Sects. 5.d and 5.f. 18 Classical Electrodynamics Sect. 1.5 D The first relation is just Gauss's law that the total flux of out through the surface is proportional to the charge contained inside. The second is the magnetic analog, with no net flux of B through a closed surface because of the nonexistence of magnetic charges. C Similarly, let be a closed contour in space, S' an open surface spanning the contour, d\ a line element on the contour, da an element of area on S', and n' a unit normal at da pointing in the direction given by the right-hand rule from the sense of integration around the contour. Then applying Stokes's theorem to the middle two equations in (1.6) gives the integral statements Equation (1.15) is the Ampere-Maxwell law of magnetic fields and (1.16) is Faraday's law of electromagnetic induction. These familiar integral equivalents of the Maxwell equations can be used directly to deduce the relationship of various normal and tangential components of the fields on either side of a surface between different media, perhaps with a surface charge or current density at the interface. An appropriate geometrical arrangement is shown in Fig. 1.4. An infinitesimal Gaussian pillbox straddles the boundary surface between two media with different electromagnetic properties Fig. 1,4 Schematic diagram of boundary surface (heavy line) between different media. The boundary region is assumed to carry idealized surface charge and current densities cr V and K. The volume is a small pillbox, half in one medium and half in the other, with the normal n to its top pointing from medium 1 into medium 2. The rectangular contour C is partly in one medium and partly in the other and is oriented with its plane perpendicular to the surface so that its normal t is tangent to the surface. Sect. 1.5 Introduction and Survey 19 C Similarly, the infinitesimal contour has its long arms on either side of the boundary and is oriented so that the normal to its spanning surface is tangent to We the interface. first apply the integral statements (1.13) and (1.14) to the volume of the pillbox. In the limit of a very shallow pillbox, the side surface does not contribute to the integrals on the left in (1.13) and (1.14). Only the top and bottom contribute. If the top and bottom are parallel, tangent to the surface, and of area Aa, then the left-hand integral in (1.13) is (j> D-nda = (D2 -Di)-nAa and similarly for (1.14). If the charge density p is singular at the interface so as to produce an idealized surface charge density cr, then the integral on the right in (1.13) is 47r| pd3 x = 47rcrAa D Thus the normal components of and B on either side of the boundary surface are related according to (02-00-0 = 4770- (1.17) (B2 -Bi)-n = (1.18) In words, we say that the normal component of B is continuous and the D discontinuity of the normal component of at any point is equal to 477 times the surface charge density at that point. In an analogous manner the infinitesimal Stokesian loop can be used to determine the discontinuities of the tangential components of E and H. If the C short arms of the contour in Fig. 1.4 are of negligible length and the long arms are each parallel to the surface and of length A/, then the left-hand integral of (1.16) is E-dI=(tXn)-(E2 -Ei)AJ and similarly for the left-hand side of (1.15). The right-hand side of (1.16) vanishes because dB/dt is finite at the surface and the area of the loop is zero as the length of the short sides goes to zero. The right-hand side of (1.15) does not K vanish, however, if there is an idealized surface current density flowing exactly on the boundary surface. In such circumstances the integral on the right of (1.15) im. ^ r \^ s+ tda= K . tAl Js lC C dt J C The second term in the integral vanishes by the same argument that was just H given. The tangential components of E and on either side of the boundary are 20 Classical Electrodynamics \ \ Sect. 1.5 Fig. 1.5 Moving boundary between two media. The pillbox and loop are as in Fig. 1.4 and are stationary in the laboratory. The dashed lines show the interface a moment before and after the instant shown. therefore related by nx(E2 -E!) = (1.19) nx(H2 -Hi) = (1.20) K In Eq. (1.20) it is understood that the surface current has only components parallel to the surface at every point. The tangential component of E across an H interface is continuous, while the tangential component of is discontinuous by an amount whose magnitude is equal to 47r/c times the magnitude of the surface current density and whose direction is parallel to Kxn. The discontinuity equations (I.17)-(1.20) are useful in solving the Maxwell equations in different regions and then connecting the solutions to obtain the fields throughout all space. The discontinuity formulas presented above hold in the common circumstance that the interface between the two media is fixed as a function of time. In some applications it may be useful to have the discontinuities for a moving boundary.* The results for a boundary surface moving with velocity v = cJJ can be obtained in essentially the same way as previously, provided a little care is taken. The moving boundary surface between the two media is shown schematically in Fig. 1.5, along with the infinitesimal Gaussian pillbox and Stokesian loop. The pillbox and loop are fixed in the laboratory. The boundary surface sweeps past them with velocity v. If we now consider the derivation of the discontinuity D formulas (1.17) and (1.18) for and B, we see that the same arguments starting from *P. D. Noerdlinger, Am. J. Physics 39, 191 (1971). Sect. 1.5 Introduction and Survey 21 (1.13) and (1.14) are valid without change, provided cr is interpreted as the surface charge density on the moving surface as observed in the laboratory. Therefore the discontinuity D formulas for and B, (1.17) and (1.18), hold without modification for a moving interface. H The discontinuity formulas (1.19) and (1.20) for E and are modified, however. This comes about because the time derivative terms on the right-hand sides of (1.15) and (1.16) C no longer vanish. The sweeping of the interface past the stationary loop gives a contribution. To determine its value, consider the surface integral of the time derivative of D/c over the open surface identical in shape to C, but moving with the interface at C velocity v and instantaneously coincident with in Fig. 1.5. The integral is I = \- ^Wt),t)-tda c We have indicated the implicit time dependence of the coordinate x to emphasize that the integration is over a moving surface. In the limit that the area of the open surface vanishes C as the short arms of the rectangular loop become vanishingly small, the integral I vanishes. (From the viewpoint of special relativity, an observer in an inertial frame moving with velocity v sees the interface at rest, and observes Lorentz-transformed fields that are not singular at the interface.) The integral I can, however, be related to the integral appearing in (1.15) through the convective derivative expansion: = I=J^(x(0, 0-tda = j^'tda+J[(p.V)D].tda Using a vector identity the second term can be transformed and the required integral becomes ±25 . t da = J[Vx(pxD)-pV • D] • t da J The first term on the right can be transformed by Stokes's theorem into a loop integral We and the second can be expressed in terms of the charge density p. therefore have as C the application of (1.15) to the loop in Fig. 1.5 the expression [H-pxD]-dI = ^j"[J-pv]-tda By the same steps as above (1.19) and (1.20), we obtain from this relation the discontinuity formula, -H -D ^ t • {nx[H2 -px(D 1 2 = 1 )]} 1 (K-crv) • t where all quantities are evaluated in the laboratory frame. Some vector manipulation and use of (1.17) leads to -H K t • [nx(H2 )+n x • P(D2 -D0]= •t (1.21) A completely similar derivation from (1.16) yields t • [nx(E2 -E0-n • -B P(B 2 1 )] = (1.22) as the discontinuity formula for the tangential components of E (and B). Equations (1.21) and (1.22) represent the generalizations of (1.19) and (1.20) to the circumstance of a moving interface between two media. 2.2 Classical Electrodynamics Sect. 1.6 D— H— In the simplified situation where E and B in both media (or these hold in one medium and the other medium is an excellent conductor with all fields essentially zero inside), the relation involving the surface current simplifies considerably. Equation (1.22) can be written (without approximation) as -E (E2 = 1 )tan -(n • P)nx(B2 -B,) D^E Then with H-^B and in (1.21), Eq. (1.23) can be substituted to give (1.23) [l-(n • p) 2]nx(B2 -B 1 )=^I K (1.24) The motion of the interface between the media introduces only an overall multiplicative factor into (1.20), a correction of relative order 22 v /c . 1.6 Some Remarks on Idealizations in Electromagnetism In the previous section we made use of the idea of surface distributions of charge and current. These are obviously mathematical idealizations that do not exist in the physical world. There are other abstractions that occur throughout elec- tromagnetism. In electrostatics, for example, we speak of holding objects at a fixed potential with respect to some zero of potential usually called "ground." The relation of such idealizations to the real world is perhaps worthy of a little discussion, even though to the experienced hand most will seem obvious. First we consider the question of maintaining some conducting object at a fixed electrostatic potential with respect to some reference value. Implicit is the idea that the means does not significantly disturb the desired configuration of charges and fields. To maintain an object at fixed potential it is necessary, at least from time to time, to have a conducting path or its equivalent from the object to a source of charge far away ("at infinity") so that as other charged or uncharged objects are brought in the vicinity charge can flow to or from the object, always maintaining its potential at the desired value. Although more sophisticated means are possible, metallic wires are commonly used to make the conducting path. Intuitively we expect small wires to be less perturbing than large ones. The reason is as follows. "Since the quantity of electricity on any given portion of a wire at a given potential diminishes indefinitely when the diameter of the wire is indefinitely diminished, the distribution of electricity on bodies of considerable dimensions will not be sensibly affected by the introduction of very fine metallic wires into the field, such as are used to form electrical connexions between these bodies and the earth, an electrical machine, or an electrometer."* The electric field in the immediate neighborhood of the thin wire is very large, of course. However, at distances away of the order of the size of the "bodies of considerable dimensions" the effects can be made small. An important historical A * J. C. Maxwell, Treatise on Electricity and Magnetism, Dover, New York, 1954 reprint of the 3rd edition (1891), Vol. 1, p. 96. Sect. 1.6 Introduction and Survey 23 illustration of Maxwell's words is given by the work of Henry Cavendish 200 years ago. By experiments done in a converted stable of his father's house, using Ley den jars as his sources of charge, thin wires as conductors, and suspending the objects in the room, Cavendish measured the amounts of charge on cylinders, discs, etc., held at fixed potential and compared them to the charge on a sphere (the same sphere shown in Fig. 1.1) at the same potential. His values of capacitance, so measured, are accurate to a few per cent. For example, he found the ratio of the capacitance of a sphere to that of a thin circular disc of the same radius was 1.57. The theoretical value is it/2. There is a practical limit to the use of finer and finer wires. The charge per unit length decreases only logarithmically (as the reciprocal of In (d/a), where a is the mean radius of the wire and d is a typical distance of the wire from some conducting surface). To minimize the perturbation of the system below some level, it is necessary to resort to other means to maintain potentials, comparison methods using beams of charged particles intermittently, for example. When a conducting object is said to be grounded, it is assumed to be connected by a very fine conducting filament to a remote reservoir of charge that serves as the common zero of potential. Objects held at fixed potentials are similarly connected to one side of a voltage source, such as a battery, the other side of which is connected to the common "ground." Then, when initially electrified objects are moved relative to one another in such a way that their distributions of electricity are altered, but their potentials remain fixed, the appropriate amounts of charge flow from or to the remote reservoir, assumed to have an inexhaustible supply. The idea of grounding something is a well-defined concept in electrostatics where time is not a factor, but for oscillating fields the finite speed of propagation blurs the concept. In other words, stray inductive and capacitive effects can enter significantly. Great care is then necessary to ensure a "good ground." Another idealization in macroscopic electromagnetism is the idea of a surface charge density or a surface current density. The physical reality is that the charge or current is confined to the immediate neighborhood of the surface. If this region has thickness small compared to the length scale of interest, we may approximate the reality by the idealization of a region of infinitesimal thickness and speak of a surface distribution. Two different limits need to be distinguished. One is the limit in which the "surface" distribution is confined to a region near An the surface that is macroscopically small, but microscopically large. example is the penetration of time-varying fields into a very good, but not perfect, conductor, described in Section 8.1. It is found that the fields are confined to a thickness 5, called the skin depth, and that for high enough frequencies and good enough conductivities 8 can be macroscopically very small. It is then appropriate to integrate the current density J over the direction perpendicular to the surface K to obtain an effective surface current density eff . The other limit is truly microscopic and is set by quantum-mechanical effects in 24 Classical Electrodynamics Sect. 1.6 Fig. 1.6 Distribution of excess charge at the surface of a conductor and of the normal component of the electric field. The ions of the solid are confined to x<0 and are approximated by a constant continuous charge distribution through which the electrons move. The bulk of the excess charge is confined to within ±2 angstroms of the "surface." the atomic structure of materials. Consider, for instance, the distribution of excess charge of a conducting body in electrostatics. It is well known that this We charge lies entirely on the surface of a conductor. then speak of a surface charge density cr. There is no electric field inside the conductor, but there is, in accord with (1.17), a normal component of electric field just outside the surface. At the microscopic level the charge is not exactly at the surface and the field does not change discontinuously. The most elementary considerations would indicate that the transition region is a few atomic diameters in extent. The ions in a metal can be thought of as relatively immobile and localized to 1 angstrom or better; the lighter electrons are less constrained. The results of model calculations* are shown in Fig. 1.6. They come from a solution of the quantum-mechanical many-electron problem in which the ions of the conductor are approximated by a continuous constant charge density for x<0. The electron density = (rs 5) is roughly appropriate to copper and the heavier alkali metals. The excess * N. D. Lang and W. Kohn, Phys. Rev. Bl, 4555 (1970); B3, 1215 (1971); V. E. Kenner, R. E. Allen, and W. M. Saslow, Phys. Letters 38A, 255 (1972). Refs. I Introduction and Survey 25 electronic charge is seen to be confined to a region within ±2 angstroms of the "surface" of the ionic distribution. The electric field rises smoothly over this region to its value of 4ircr "outside" the conductor. For macroscopic situations where 10~ 7 cm is a negligible distance, we can idealize the charge density and E electric field behavior as p(x) = cr8(x) and = n (x) 47rcr0(x), corresponding to a truly surface density and a step-function jump of the field. We see that the theoretical treatment of classical electromagnetism involves several idealizations, some of them technical and some physical. The subject of electrostatics, discussed in the first chapters of the book, developed as an experimental science of macroscopic electrical phenomena, as did virtually all other aspects of electromagnetism. The extension of these macroscopic laws, even for charges and currents in vacuum, to the microscopic domain was for the most part an unjustified extrapolation. Earlier in this introduction we have discussed some of the limits to this extrapolation. The point to be made here is the following. With hindsight we know that many aspects of the laws of classical electromagnetism apply well into the atomic domain provided the sources are treated quantum mechanically, that the averaging of electromagnetic quantities over volumes containing large numbers of molecules so smooths the rapid fluctuations that static applied fields induce static average responses in matter, that excess charge is on the surface of a conductor in a macroscopic sense. Thus Coulomb's and Ampere's macroscopic observations and our mathematical abstractions from them have a wider applicability than might be supposed by a supercautious physicist. The absence for air of significant electric or magnetic susceptibility certainly simplified matters! REFERENCES AND SUGGESTED READING The history of electricity and magnetism is in large measure the history of science itself. We have already cited Whittaker's two volumes, the first covering the period up to 1900, as well as the shorter account emphasizing optics in Born and Wolf. Another readable account, with perceptive discussion of the original experiments, is N. Feather, Electricity and Matter, University Press, Edinburgh (1968). The experimental tests of the inverse square nature of Coulomb's law or, in modern language, the mass of the photon, are reviewed by I. Yu. Kobzarev and L. B. Okun', Uspekhi Fiz. Nauk 95, 131 (1968) [transl., Sov. Phys. Uspekhi 11, 338 (1968).] and A. S. Goldhaber and M. M. Nieto, Rev. Mod. Phys. 43, 277 (1971). Suggested reading on the topic of the macroscopic Maxwell equations and their derivation from the microscopic equations can be found at the end of Chapter 6. The basic physics of dielectrics, ferroelectrics, and magnetic materials can be found in 26 Classical Electrodynamics Refs. I numerous books on solid state physics, for example, Beam, Kittel, Wert and Thomson, Wooten. The first of these is aimed at electrical engineers and stresses practical topics like semiconductors. The last one is mainly on optical properties. The need for spatial nonlocality in treating the surface impedance of metals (the anomalous skin effect) is discussed in several places by A. B. Pippard, Advances in Electronics and Electron Physics, Vol. VI, ed. L. Marton, Academic, New York (1954), pp. 1-45; Reports on Progress in Physics, Vol. XXIII, pp. 176-266 (1960); The Dynamics of Conduction Electrons, Gordon and Breach, New York (1965). The concept of a wave- vector and frequency-dependent dielectric constant e(k, co) is developed by Kittel, Advanced Topic D. D. Pines, Elementary Excitations in Solids, W. A. Benjamin, New York (1963), Chapters 3 and 4. F. Stern, Solid State Physics, Vol. 15, eds. F. Seitz and D. Turnbull, Academic, New York, pp. 299-408. The rapidly growing field of nonlinear optics is beginning to have a book literature of its own, but much of it is still in the research or review journals or in summer school proceedings. An introduction can be found in J. A. Giordmaine, Physics Today 22 (1) 38 (1969), N. Bloembergen, Am. J. Phys. 35, 989 (1967), G. C. Baldwin, Introduction to Nonlinear Optics, Plenum, New York (1969). Somewhat more advanced discussions arc available in S. A. Akhmanov and R. V. Khokhlov, Usp. Fiz. Nauk. 88, 439 (1966); 95, 231 (1968), [trans., Sov. Phys. Uspekhi, 9, 210 (1966); 11, 394 (1968)], N. Bloembergen, Nonlinear Optics, W. A. Benjamin, New York (1965), Quantum Optics, Proc. Int. School of Physics "Enrico Fermi," Varenna, Course XLII, 1967, ed. R. J. Glauber, Academic, New York (1969), articles by J. Ducuing, Y. R. Shen, J. A. Giordmaine, P. S. Pershan, Progress in Optics, Vol. V, ed. E. Wolf, North-Holland, Amsterdam (1966), pp. 83-144. 1 Introduction to Electrostatics We — begin our discussion of electrodynamics with the subject of electrostatics phenomena involving time-independent distributions of charge and fields. For most readers this material is in the nature of a review. In this chapter especially We we do not elaborate significantly. introduce concepts and definitions that are important for later discussion and present some essential mathematical ap- paratus. In subsequent chapters the mathematical techniques are developed and applied. One point of physics should be mentioned. Historically, electrostatics developed as a science of macroscopic phenomena. As indicated at the end of the Introduction, such idealizations as point charges or electric fields at a point must be viewed as mathematical constructs that permit a description of the phenomena at the macroscopic level, but that may fail to have meaning microscopically. 1.1 Coulomb's Law All of electrostatics stems from the quantitative statement of Coulomb's law concerning the force acting between charged bodies at rest with respect to each other. Coulomb, in an impressive series of experiments, showed experimentally that the force between two small charged bodies separated in air a distance large compared to their dimensions (1) varied directly as the magnitude of each charge, (2) varied inversely as the square of the distance between them, (3) was directed along the line joining the charges, (4) was attractive if the bodies were oppositely charged and repulsive if the bodies had the same type of charge. Furthermore it was shown experimentally that the total force produced on one small charged body by a number of the other small charged bodies placed 27 28 Classical Electrodynamics Sect. 1.2 around it was the vector sum of the individual two-body forces of Coulomb. Strictly speaking, Coulomb's conclusions apply to charges in vacuum or in media We of negligible susceptibility. defer consideration of charges in dielectrics to Chapter 4. 1.2 Electric Field Although the thing that eventually gets measured is a force, it is useful to introduce a concept one step removed from the forces, the concept of an electric field due to some array of charged bodies. At the moment, the electric field can be defined as the force per unit charge acting at a given point. It is a vector function of position, denoted by E. One must be careful in its definition, however. It is not necessarily the force that one would observe by placing one unit of charge on a pith ball and placing it in position. The reason is that one unit of charge may be so large that its presence alters appreciably the field configuration of the array. Consequently one must use a limiting process whereby the ratio of the force on the small test body to the charge on it is measured for smaller and smaller amounts of charge.* Experimentally, this ratio and the direction of the force will become constant as the amount of test charge is made smaller and smaller. These limiting values of magnitude and direction define the magnitude and direction of the electric field E at the point in question. In symbols we may write F=qE (1.1) E where F is the force, the electric field, and q the charge. In this equation it is assumed that the charge q is located at a point, and the force and the electric field are evaulated at that point. Coulomb's law can be written down similarly. If F is the force on a point charge qi, located at Xi, due to another point charge q2 , located at x2 , then Coulomb's law is F=kq!q2 (1.2) Note that qi and q2 are algebraic quantities which can be positive or negative. The constant of proportionality k depends on the system of units used. The electric field at the point x due to a point charge qi at the point Xi can be obtained directly: E(x) = kq! (1.3) * The discreteness of electric charge (see Section 1.1) means that this mathematical limit is impossible to realize physically. This is an example of a mathematical idealization in macroscopic electrostatics. Sect. 1.2 Introduction to Electrostatics 2S Fig. 1.1 as indicated in Fig. 1.1. The constant k is determined by the unit of charge chosen. In electrostatic units (esu), unit charge is chosen as that charge which exerts a force of one dyne on an equal charge located one centimeter away. Thus, with cgs units, k = 1 and the unit of charge is called the "stat-coulomb." In MKSA the system, k = (4ir€ y\ where e (= 8.854 x 10~ 12 farad/meter) is the We permittivity of free space. will use esu.* The experimentally observed linear superposition of forces due to many charges means that we may write the electric field at x due to a system of point charges qh located at x<, i= 1, 2, . . . , n, as the vector sum: If the charges are so small and so numerous that they can be described by a charge density p(x') [if Aq is the charge in a small volume Ax Ay Az at the point x', then Aq = p(x') Ax Ay Az], the sum is replaced by an integral: E(x) = Jp(x')^^ • n da=l^ 7TC* Js lO if q lies inside S if q lies outside S . , ^ '' This result is Gauss's law for a single point charge. For a discrete set of charges, it is immediately apparent that (j> E-nda = 47rXqi (1.10) where the sum is over only those charges inside the surface S. For a continuous charge density p(x), Gauss's law becomes: E = • n da J" 47r p(x) d 3 x (1.11) where V is the volume enclosed by S. Equation (1.11) is one of the basic equations of electrostatics. Note that it depends upon (1) the inverse square law for the force between charges, (2) the central nature of the force, (3) the linear superposition of the effects of different charges. Clearly, then, Gauss's law holds for Newtonian gravitational force fields, with matter density replacing charge density. It is interesting to note that, even before the experiments of Cavendish and Coulomb, Priestley, taking up an observation of Franklin that charge seemed to reside on the outside, but not the inside, of a metal cup, reasoned by analogy with Newton's law of universal gravitation that the electrostatic force must obey an inverse square law with distance. The present status of the inverse square law is discussed in Section 1.2. 1.4 Differential Form of Gauss's Law Gauss's law can be thought of as being an integral formulation of the law of We electrostatics. can obtain a differential form (i.e., a differential equation) by using the divergence theorem. The divergence theorem states that for any V well-behaved vector field A(x) defined within a volume surrounded by the closed surface S the relation A-nda^J A V • d3x A holds between the volume integral of the divergence of and the surface integral of the outwardly directed normal component of A. The equation in fact can be used as the definition of the divergence (see Stratton, p. 4). Sect. 1.5 Introduction to Electrostatics 33 To apply the divergence theorem we consider the integral relation expressed in Gauss's theorem: £ E • n da = 47rj p(x) d3 x Now the divergence theorem allows us to write this as: (V-E-47rp)d3 x = J (1.12) We for an arbitrary volume V. can, in the usual way, put the integrand equal to zero to obtain V-E=4ttp (1.13) which is the differential form of Gauss's law of electrostatics. This equation can itself be used to solve problems in electrostatics. However, it is often simpler to deal with scalar rather than vector functions of position, and then to derive the vector quantities at the end if necessary (see below). 1.5 Another Equation of Electrostatics and the Scalar Potential The single equation (1.13) is not enough to specify completely the three components of the electric field E(x). Perhaps some readers know that a vector field can be specified almost* completely if its divergence and curl are given everywhere in space. Thus we look for an equation specifying curl E as a function of position. Such an equation, namely, VxE = (1.14) follows directly from our generalized Coulomb's law (1.5): E(x) = Jp(x')j^dV The vector factor in the integrand, viewed as a function of x, is the negative gradient of the scalar l/|x-x'|: Since the gradient operation involves x, but not the integration variable x', it can be taken outside the integral sign. Then the field can be written E(x)=-v[j£^jdV (1.15) Up * to the gradient of a scalar function that satisfies the Laplace equation. See Section 1.9 on uniqueness. 34 Classical Electrodynamics Sect. 1.5 Since the curl of the gradient of any well-behaved scalar function of position vanishes (VxVi// = 0, for all (1.14) follows immediately from (1.15). VxE Note that = depends on the central nature of the force between charges, and on the fact that the force is a function of relative distances only, but does not depend on the inverse square nature. In (1.15) the electric field (a vector) is derived from a scalar by the gradient operation. Since one function of position is easier to deal with than three, it is worth while concentrating on the scalar function and giving it a name. Conse- quently we define the scalar potential <£(x) by the equation: E = -VcJ> (1.16) Then (1.15) shows that the scalar potential is given in terms of the charge density by *(x) = lbS| dV (L17) where the integration is over all charges in the universe, and is arbitrary only to the extent that a constant can be added to the right side of (1.17). The scalar potential has a physical interpretation when we consider the work done on a test charge q in transporting it from one point (A) to another point (B) in the presence of an electric field E(x), as shown in Fig. 1.3. The force acting on the charge at any point is F=qE A so that the work done in moving the charge from B to is B W=-j F-dl=-qj" E-dl (1.18) The minus sign appears because we are calculating the work done on the charge against the action of the field. With definition (1.16) the work can be written W= q^V® = = - * • d\ q d ) J" (1.19) which shows that q<& can be interpreted as the potential energy of the test charge in the electrostatic field. Fig. 1.3 Sect. 1.6 Introduction to Electrostatics 35 From (1.18) and (1.19) it can be seen that the line integral of the electric field between two points is independent of the path and is the negative of the potential difference between the points: B £ E-dl=-(4>B -4>A) (1.20) This follows directly, of course, from definition (1.16). If the path is closed, the line integral is zero, E-dl=0 (1.21) a result that can also be obtained directly from Coulomb's law. Then application of Stokes's theorem [if A(x) is a well-behaved vector field, S is an arbitrary open C surface, and is the closed curve bounding S, A-dl=J (VxA)-nda C where d\ is a line element of C, n is the normal to S, and the path is traversed Vx in a right-hand screw sense relative to n] leads immediately back to E = 0. 1.6 Surface Distributions of Charges and Dipoles and Discontinuities in the Electric Field and Potential One of the common problems in electrostatics is the determination of electric field or potential due to a given surface distribution of charges. Gauss's law (1.11) allows us to write down a partial result directly. If a surface S, with a unit normal n directed from side 1 to side 2 of the surface, has a surface-charge density of o-(x) (measured in statcoulombs per square centimeter) and electric fields Ei and E2 on either side of the surface, as shown in Fig. 1.4, then Gauss's Fig. 1.4 Discontinuity in the normal component of electric field across a surface layer of charge. 36 Classical Electrodynamics Sect. 1.6 law tells us immediately that (E2 -Ei) -n = 47ro- (1.22) This does not determine Ei and E 2 unless there are no other sources of field and the geometry and form a are especially simple. All that (1.22) says is that there is a discontinuity of Attct in the normal component of electric field in crossing a surface with a surface-charge density o\ the crossing being made in the direction of n. The tangential component of electric field can be shown to be continuous across a boundary surface by using (1.21) for the line integral of E around a closed path. It is only necessary to take a rectangular path with negligible ends and one side on either side of the boundary. An expression for the potential (and hence the field, by differentiation) at any point in space (not just at the surface) can be obtained from (1.17) by replacing p d3 x by a da : (1.23) For volume or surface distributions of charge the potential is everywhere continuous, even within the charge distribution. This can be shown from (1.23) or from the fact that E is bounded, even though discontinuous across a surface distribution of charge. With point or line charges, or dipole layers, the potential is no longer continuous, as will be seen immediately. Another problem of interest is the potential due to a dipole-layer distribution A on a surface S. dipole layer can be imagined as being formed by letting the surface S have a surface-charge density o-(x) on it, and another surface S', lying close to S, have an equal and opposite surface-charge density on it at neighboring points, as shown in Fig. 1.5. The dipole-layer distribution of strength D(x) is formed by letting S' approach infinitesimally close to S while the surface- charge density cr(x) becomes infinite in such a manner that the product of cr(x) and the local separation d(x) of S and S' approaches the limit D(x): lim o-(x) d(x) = D(x) d(x)->-0 S s S' Fig. 1.5 Limiting process involved in creating a dipole layer. Sect. 1.6 Introduction to Electrostatics 37 Fig. 1.6 Dipole- layer geometry. The direction of the dipole moment of the layer is normal to the surface S and in the direction going from negative to positive charge. To find the potential due to a dipole layer we can consider a single dipole and then superpose a surface density of them, or we can obtain the same result by performing mathematically the limiting process described in words above on the surface-density expression (1.23). The first way is perhaps simpler, but the second gives useful practice in vector calculus. Consequently we proceed with the limiting process. With n, the unit normal to the surface S, directed away from S', as shown in Fig. 1.6, the potential due to the two close surfaces is 4>(x)=[ Js j^rda'-f x-x' JS ' °$2 ,x-xx''++nndd| For small d we can expand _1 |x-x'+nd| . Consider the general expression -1 |x+a| , where |a|«|x|. We write a Taylor series expansion in three dimensions: 1 |x+a| x d^O In this way we find that as the potential becomes (1.24) In passing we note that the integrand in Eq. (1.24) is the potential of a point dipole with dipole moment p=n D da' . The potential at x caused by a dipole pat x' is 2-4>i = 4ttD (1.27) This result is analogous to (1.22) for the discontinuity of electric field in crossing a surface-charge density. Equation (1.27) can be interpreted "physically" as a potential drop occurring "inside" the dipole layer, and can be calculated as the product of the field between the two layers of surface charge times the separation before the limit is taken. 1.7 Poisson and Laplace Equations In Sections 1.4 and 1.5 it was shown that the behavior of an electrostatic field can be described by the two differential equations: V • E = 4irp (1.13) Sect. 1.7 Introduction to Electrostatics 39 and VxE = (1.14) the latter equation being equivalent to the statement that E is the gradient of a scalar function, the scalar potential 4>: E = -V4) (1.16) Equations (1.13) and (1.16) can be combined into one partial differential equation for the single function 4>(x): V2 4> = -4ttp (1.28) This equation is called the Poisson equation. In regions of space where there is no charge density, the scalar potential satisfies the Laplace equation: V2 a(x) by J V(x-x') 2 +a +<2 2: The actual potential (1.17) is then the limit of the "a-potential" as0. Taking the Laplacian of the "^-potential" gives V^(x)=}p(x^( =L=)^' 7 =-M(^] dV (l30) where r= x-x' . The square-bracketed expression is the negative Laplacian of \ \ l/Vr 2 + a 2 . It is well-behaved everywhere for nonvanishing a, but as a tends to zero it becomes infinite at r=0 and vanishes for r^O. It has a volume integral equal to 47r for arbitrary a. For the purposes of integration divide space into two regions by a sphere of fixed radius R centered on x. Choose R such thatp(x') changes little over the interior of the sphere, and imagine a much smaller than R and tending towards zero. If p(x') is such that (1.17) exists, the contribution to the integral from the exterior of the sphere will vanish like a 2 as**—^-0. We thus need consider only the contribution from inside the sphere. With a Taylor series expansion of the well-behaved p(x') around x'=x, one finds f V^.OO = -4n (x)-^p 3fl2 rp + • •• lr2 dr+ 0(a>) +a 2 Jo (r )L o J 40 Classical Electrodynamics Direct integration yields Sect. 1.8 V2 4> fl (x) = -4ttp(x) (l + 0(a 2 lR 2 )) + 0(a\ 2 \og a) V 2p + ... a^O, In the limit we obtain the Poisson equation (1.28). The singular nature of the Laplacian of 1/r can be exhibited formally in terms of a Dirac delta function. Since V = 2 (l/r) for r^O and its volume integral is -4tt, we can write the formal equation, V2 (l/r) = -4ir 8(x) or, more generally, (1.31) 1.8 Green's Theorem If electrostatic problems always involved localized discrete or continuous distributions of charge with no boundary surfaces, the general solution (1.17) would be the most convenient and straightforward solution to any problem. There would be no need of the Poisson or Laplace equation. In actual fact, of course, many, if not most, of the problems of electrostatics involve finite regions of space, with or without charge inside, and with prescribed boundary conditions on the bounding surfaces. These boundary conditions may be simulated by an appropriate distribution of charges outside the region of interest (perhaps at infinity), but (1.17) becomes inconvenient as a means of calculating the potential, except in simple cases (e.g., method of images). To handle the boundary conditions it is necessary to develop some new mathematical tools, namely, the identities or theorems due to George Green (1824). These follow as simple applications of the divergence theorem. The divergence theorem: A V applies to any well-behaved vector field defined in the volume bounded by the closed surface S. Let A= Vi//, where and ijj are arbitrary scalar fields. Now and V = V • ( Vifr) 2 i//+ V (1.32) dip (1.33) dn where d/dn is the normal derivative at the surface S (directed outwards from inside the volume V). When (1.32) and (1.33) are substituted into the divergence Sect. 1.8 Introduction to Electrostatics 41 theorem, there results Green's first identity: f = 2 3 ((/>V i//+V4>- Vi//)d x ^da Jv Js dn (1.34) If we write down (1.34) again with <#> and i// interchanged, and then subtract it from (1.34), the V • Vi// terms cancel, and we obtain Green's second identity or Green's theorem: (*V*-*^)d'x = j[[*|*-*U]da fv (1.35) The Poisson differential equation for the potential can be converted into an = integral equation if we choose a particular \p, namely l/R l/|x— x'|, where x is the observation point and x' is the integration variable. Further, we put = the scalar potential, and make use of V2 = -47rp. From (1.31) we know that V2(1/R) = -4tt8(x-x'), so that (1.35) becomes L *<-{ [*£(*Hi?] If the point x lies within the volume V, we obtain: If x lies outside the surface S, the left-hand side of (1.36) is zero.* [Note that this is consistent with the interpretation of the surface integral as being the potential D due to a surface-charge density cr= (l/47r)(d/dn') and a dipole layer = -(1/4tt)<&. The discontinuities in electric field and potential (1.22) and (1.27) across the surface then lead to zero field and zero potential outside the volume v.] Two remarks are in order about result (1.36). First, if the surface S goes to infinity and the electric field on S falls off faster than R~\ then the surface integral vanishes and (1.36) reduces to the familiar result (1.17). Second, for a charge-free volume the potential anywhere inside the volume (a solution of the Laplace equation) is expressed in (1.36) in terms of the potential and its normal derivative only on the surface of the volume. This rather surprising result is not a solution to a boundary-value problem, but only an integral statement, since the arbitrary specification of both 4> and d<&/dn (Cauchy boundary conditions) is an overspecification of the problem. This will be discussed in detail in the next sections, where techniques yielding solutions for appropriate boundary conditions will be developed using Green's theorem (1.35). *The reader may complain that (1.36) has been obtained in an illegal fashion since l/|x-x'| is not well-behaved inside the volume V. Rigor can be restored by using a limiting process, as in the previous section, or by excluding a small sphere around the offending point, x=x'. The result is still (1.36). 42 Classical Electrodynamics 1.9 Uniqueness of the Solution with Dirichlet or Neumann Boundary Conditions Sect. 1.9 The question arises as to what are the boundary conditions appropriate for the Poission (or Laplace) equation in order that a unique and well-behaved (i.e., physically reasonable) solution exist inside the bounded region. Physical experi- ence leads us to believe that specification of the potential on a closed surface (e.g., a system of conductors held at different potentials) defines a unique potential problem. This is called a Dirichlet problem, or Dirichlet boundary conditions. Similarly it is plausible that specification of the electric field (normal derivative of the potential) everywhere on the surface (corresponding to a given surface-charge density) also defines a unique problem. Specification of the normal derivative is known as the Neumann boundary condition. We now proceed to prove these expectations by means of Green's first identity (1.34). We want to show the uniqueness of the solution of the Poisson equation, V V 2 <£ = — 477p, inside a volume subject to either Dirichlet or Neumann We boundary conditions on the closed bounding surface S. suppose, to the contrary, that there exist two solutions i and 2 satisfying the same boundary conditions. Let U = 2-i (1.37) U Then V2 = inside V, and 17=0 or dU/dn = on S for Dirichlet and Neumann boundary conditions, respectively. From Green's first identity (1.34), with 4>= ifj=U, we find (1.38) With the specified properties of 17, this reduces (for both types of boundary conditions) to: VU U which implies = 0. Consequently, inside V, is constant. For Dirichlet U boundary conditions, = on S so that, inside V, 4>i=2 and the solution is unique. Similarly, for Neumann boundary conditions, the solution is unique, apart from an unimportant arbitrary additive constant. From the right-hand side of (1.38) it is evident that there is also a unique solution to a problem with mixed boundary conditions (i.e., Dirichlet over part of the surface S, and Neumann over the remaining part). It should be clear that a solution to the Poisson equation with both and d/dn specified arbitrarily on a closed boundary (Cauchy boundary conditions) does not exist, since there are unique solutions for Dirichlet and Neumann conditions separately and these will in general not be consistent. This can be verified with (1.36). With arbitrary values of 3> and d/dn inserted on the Sect. 1.10 Introduction to Electrostatics 43 right-hand side, it can be shown that the values of 4>(x) and VO(x) as x approaches the surface are in general inconsistent with the assumed boundary values. The question of whether Cauchy boundary conditions on an open surface define a unique electrostatic problem requires more discussion than is warranted here. The reader may refer to Morse and Feshbach, Section 6.2, pp. 692-706, or to Sommerfeld, Partial Differential Equations in Physics, Chapter II, for a detailed discussion of these questions. The conclusion is that electrostatic problems are specified only by Dirichlet or Neumann boundary conditions on a closed surface (part or all of which may be at infinity, of course). 1.10 Formal Solution of Electrostatic Boundary-Value Problem with Green Function V The solution of the Poisson or Laplace equation in a finite volume with either Dirichlet or Neumann boundary conditions on the bounding surface S can be obtained by means of Green's theorem (1.35) and so-called "Green functions." — — In obtaining result (1.36) not a solution we chose the function i// to be l/|x-x'|, it being the potential of a unit point charge, satisfying the equation: (^) 2 V' = -4tt8(x-x') (1.31) The function l/|x-x'| is only one of a class of functions depending on the variables x and x', and called Green functions, which satisfy (1.31). In general, where V' 2 G(x, x') = -4tt8(x-x') G(x,x') = j^+F(x,x') (1.39) (1.40) with the function F satisfying the Laplace equation inside the volume V: 2 V' F(x,x') = (1.41) In facing the problem of satisfying the prescribed boundary conditions on or d<£/dn, we can find the key by considering result (1.36). As has been pointed out already, this is not a solution satisfying the correct type of boundary conditions because both and d/dn appear in the surface integral. It is at best an integral relation for <£. With the generalized concept of a Green function and its additional freedom [via the function F(x, x')], there arises the possibility that we can use Green's theorem with i//= G(x, x') and choose F(x, x') to eliminate one or the other of the two surface integrals, obtaining a result which involves only Dirichlet or Neumann boundary conditions. Of course, if the necessary G(x, x') depended in detail on the exact form of the boundary conditions, the method would have little generality. As will be seen immediately, this is not required, and G(x, x') satisfies rather simple boundary conditions on S. 44 Classical Electrodynamics Sect. 1.10 With Green's theorem (1.35), = i(r= G(x, x'), and the specified properties G of (1.39), it is simple to obtain the generalization of (1.36): d>(x) = p(x')G(x,x')dV+^^ [G(x,x')g- Jv 477 Js ^on7 N da' (1.46) where ()S is the average value of the potential over the whole surface. The customary Neumann problem is the so-called "exterior problem" in which the V volume is bounded by two surfaces, one closed and finite, the other at infinity. Then the surface area S is infinite; the boundary condition (1.45) becomes homogeneous; the average value ()S vanishes. We note that the Green functions satisfy simple boundary conditions (1.43) or (1.45) which do not depend on the detailed form of the Dirichlet (or Neumann) boundary values. Even so, it is often rather involved (if not impossible) to We determine G(x, x') because of its dependence on the shape of the surface S. will encounter such problems in Chapter 2 and 3. The mathematical symmetry property G(x, = x') G(x', x) can be proved for the Sect. 1.11 Introduction to Electrostatics 45 Green functions satisfying the Dirichlet boundary condition (1.43) by means of Green's theorem with =G(x, y) and i//=G(x', y), where y is the integration variable. Since the Green function, as a function of one of its variables, is a potential due to a unit point charge, the symmetry merely represents the physical interchangeability of the source and the observation points. For Neumann boundary conditions the symmetry is not automatic, but can be imposed as a separate requirement. As a final, important remark we note the physical meaning of F(x, x'). It is a V solution of the Laplace equation inside and so represents the potential of a system of charges external to the volume V. It can be thought of as the potential due to an external distribution of charges so chosen as to satisfy the homogeneous boundary conditions of zero potential (or zero normal derivative) on the surface S when combined with the potential of a point charge at the source point x'. Since the potential at a point x on the surface due to the point charge depends on the position of the source point, the external distribution of charge F(x, x') must also depend on the "parameter" x\ From this point of view, we see that the method of images (to be discussed in Chapter 2) is a physical equivalent of the determination of the appropriate F(x, x') to satisfy the boundary conditions (1.43) or (1.45). For the Dirichlet problem with conductors, F(x, x') can also be interpreted as the potential due to the surface-charge distribution induced on the conductors by the presence of a point charge at the source point x'. 1.11 Electrostatic Potential Energy and Energy Density, Capacitance In Section 1.5 it was shown that the product of the scalar potential and the charge of a point object could be interpreted as potential energy. More precisely, if a point charge q{ is brought from infinity to a point x< in a region of localized electric fields described by the scalar potential (which vanishes at infinity), the work done on the charge (and hence its potential energy) is given by W^qM*) (1.47) The potential can be viewed as produced by an array of (n-1) charges q,(j= 1,2,..., n— 1) at positions x,. Then * (Xi)= "^i^i j=l |Xj Xj| (L48) so that the potential energy of the charge q; is Wi = qi ZrjLi /-i |xi— x,| (1-49) The total potential energy of all the charges due to all the forces acting between 46 Classical Electrodynamics them is: Sect. 1.11 = i l j(x)-3), has a total charge Q. Use Gauss's theorem to obtain the electric fields both inside and outside each sphere. Sketch the behavior of the fields as a function of radius for the first two spheres, and for the third with n = -2, +2. 1.5 The time-average potential of a neutral hydrogen atom is given by where q is the magnitude of the electronic charge, and a' 1 = a /2, cio being the Bohr radius. Find the distribution of charge (both continuous and discrete) which will give this potential and interpret your result physically. A 1.6 simple capacitor is a device formed by two insulated conductors adjacent to each other. If equal and opposite charges are placed on the conductors, there will be a certain difference of potential between them. The ratio of the magnitude of the charge on one conductor to the magnitude of the potential difference is called the capacitance (in electrostatic units it is measured in centimeters). Using Gauss's law, calculate the capacitance of (a) two large, flat, conducting sheets of area A, separated by a small distance d; (b) two concentric conducting spheres with radii a, b (b>a); (c) two concentric conducting cylinders of length L, large compared to their radii a, b (b>a). (d) What is the inner diameter of the outer conductor in an air-filled coaxial cable Prob. 1 Introduction to Electrostatics 51 mm whose center conductor is a cylindrical wire of diameter 1 and whose capacitance is 0.5 micromicrofarad/cm? 0.05 micromicrofarad/cm? 1.7 Two long, cylindrical conductors of radii a, and a2 are parallel and separated by a distance d which is large compared with either radius. Show that the capacitance per unit length is given approximately by where a is the geometrical mean of the two radii. Approximately what gauge wire (state diameter in millimeters) would be necessary to make a two- wire transmission line with a capacitance of 0.1 fi/xf/cm if the separation of the wires was 0.5 cm? 1.5 cm? 5.0 cm? 1.8 (a) For the three capacitor geometries in Problem 1.6 calculate the total electro- Q static energy and express it alternatively in terms of the equal and opposite charges -Q and placed on the conductors and the potential difference between them. (b) Sketch the energy density of the electrostatic field in each case as a function of the appropriate linear coordinate. 1.9 Calculate the attractive force between conductors in the parallel plate capacitor (Problem 1.6a) and the parallel cylinder capacitor (Problem 1.7) for (a) fixed charges on each conductor; (b) fixed potential difference between conductors. 1.10 Prove the mean value theorem: For change-free space the value of the electrostatic potential at any point is equal to the average of the potential over the surface of any sphere centered on that point. 1.11 Use Gauss's theorem to prove that at the surface of a curved charged conductor the normal derivative of the electric field is given by R where Ri and 2 are the principal radii of curvature of the surface. 1.12 Prove Green's reciprocation theorem: If 3> is the potential due to a volume-charge V density p within a volume and a surface-charge density cr on the conducting surface S bounding the volume V, while <£' is the potential due to another charge distribution p' and a', then A 1.13 Two infinite grounded parallel conducting planes are separated by a distance d. point charge q is placed between the planes. Use the reciprocation theorem of Green to prove that the total induced charge on one of the planes is equal to (-q) times the fractional perpendicular distance of the point charge from the other plane. (Hint: Choose as your comparison electrostatic problem with the same surfaces one whose charge densities and potential are known and simple.) A 1.14 volume V is bounded by a surface S consisting of several separate surfaces ^ (conductors) Si, one perhaps at infinity, each held at potential V . Let (x) be a ( well-behaved function in V and on 5, with a value equal to V, on each surface Si, but otherwise arbitrary for the present. Define the energylike quantity, otherwise arbitr- 52 Classical Electrodynamics ary for the present. Define the energylike quantity, Prob. 1 Prove the following theorem: W[^], which is nonnegative by definition, is stationary and an absolute minimum if ^ V and only if satisfies the Laplace equation inside and takes on the specified values V; on the surfaces S . ( 1.15 Prove Thomson's theorem: If a number of surfaces are fixed in position and a given total charge is placed on each surface, then the electrostatic energy in the region bounded by the surfaces is an absolute minimum when the charges are placed so that every surface is an equipotential, as happens when they are conductors. 1.16 Prove the following theorem: If a number of conducting surfaces are fixed in position with a given total charge on each, the introduction of an uncharged, insulated conductor into the region bounded by the surfaces lowers the electrostatic energy. 1.17 Consider a configuration of conductors as in problem 1.14 with one conductor held at unit potential and all the other conductors at zero potential. (a) Show that the capacitance of the one conductor is given by where (x) is the solution for the potential. C (b) Use the theorem of Problem 1 . 14 to show that the true capacitance is always less than or equal to the quantity ^ where is any trial function satisfying the boundary conditions on the conductors. This is a variational principle for the capacitance that yields an upper bound. 1.18 Consider the configuration of conductors of Problem 1.17, with all conductors except Si held at zero potential. V (a) Show that the potential 4>(x) anywhere in the volume and on any of the surfaces S, can be written where o-i(x') is the surface charge density on Si and G(x, x') is the Green function potential for a point charge in the presence of all the surfaces that are held at zero potential (but with Si absent). Show also that the electrostatic energy is where the integrals are only over the surface Si. (b) Show that the variational expression Prob. 1 Introduction to Electrostatics 53 with an arbitrary integrable function cr(x) defined on Si, is stationary for small variations of cr away from cr,. Use Thomson's theorem to prove that the reciprocal of C_1 [cr] gives a lower bound to the true capacitance of the conductor S,. 1.19 For the cylindrical capacitor of Problem 1.6(c), evaluate the variational upper ^ bound of Problem 1.17(b) with the naive trial function, ,(p) = (b- p)/(b- a) . Compare the variational result with the exact result for b/a= 1.5, 2, 3. Explain the trend of your results in terms of the functional form of An improved trial function is treated by Collin, pp. 151-152. 1.20 In estimating the capacitance of a given configuration of conductors, comparison with known capacitances is often helpful. Consider two configurations of n conductors in which the (n-1) conductors held at zero potential are the same, but the one conductor whose capacitance we wish to know is different. In particular, let the conductor in one configuration have a closed surface Si and in the other configuration have surface S[, with S[ totally inside Si. (a) Use the theorem of Problem 1.14 and the variational principle of Problem 1.17 to C prove that the capacitance of the conductor with surface S[ is less than or equal to C the capacitance of the conductor with surface Si that encloses SJ. (b) Set upper and lower limits for the capacitance of a conducting cube of side a. C— Compare your limits and also their average with the numerical value, 0.655a. 2 Boundary-Value Problems in Electrostatics: I Many problems in electrostatics involve boundary surfaces on which either the potential or the surface-charge density is specified. The formal solution of such problems was presented in Section 1.10, using the method of Green functions. In practical situations (or even rather idealized approximations to practical situations) the discovery of the correct Green function is sometimes easy and sometimes not. Consequently a number of approaches to electrostatic boundaryvalue problems have been developed, some of which are only remotely connected to the Green function method. In this chapter we will examine two of these special techniques: (1) the method of images, which is closely related to the use of Green functions; (2) expansion in orthogonal functions, an approach directly through the differential equation and rather remote from the direct A construction of a Green function. major omission is the use of complex- variable techniques, including conformal mapping, for the treatment of two- dimensional problems. The topic is important, but lack of space and the existence of self-contained discussions elsewhere accounts for its absence. The interested reader may consult the references cited at the end of the chapter. 2.1 Method of Images The method of images concerns itself with the problem of one or more point charges in the presence of boundary surfaces, for example, conductors either grounded or held at fixed potentials. Under favorable conditions it is possible to infer from the geometry of the situation that a small number of suitably placed charges of appropriate magnitudes, external to the region of interest, can simulate the required boundary conditions. These charges are called image charges, and the replacement of the actual problem with boundaries by an enlarged region with image charges but not boundaries is called the method of images. The image charges must be external to the volume of interest, since their 54 Sect. 2.2 Boundary-Value Problems in Electrostatics: I 55 Fig. 2.1 Solution by method of images. The original potential problem is on the left, the equivalent-image problem on the right. potentials must be solutions of the Laplace equation inside the volume; the "particular integral" (i.e., solution of the Poisson equation) is provided by the sum of the potentials of the charges inside the volume. A simple example is a point charge located in front of an infinite plane conductor at zero potential, as shown in Fig. 2.1. It is clear that this is equivalent to the problem of the original charge and an equal and opposite charge located at the mirror-image point behind the plane defined by the position of the conductor. 2.2 Point Charge in the Presence of a Grounded Conducting Sphere As an illustration of the method of images we consider the problem illustrated in Fig. 2.2 of a point charge q located at y relative to the origin around which is We centered a grounded conducting sphere of radius a. seek the potential <$(x) such that = = 4>(|x| a) 0. By symmetry it is evident that the image charge q' Fig. 2.2 Conducting sphere of radius a, with charge q and image charge q'. 56 Classical Electrodynamics Sect. 2.2 (assuming that only one image is needed) will lie on the ray from the origin to the charge q. If we consider the charge q outside the sphere, the image position y' will lie inside the sphere. The potential due to the charges q and q[ is: r r ^ + ^(x) = fl - 1 fl (2.1) We now must try to choose q' and |y'| such that this potential vanishes at |x| = a. If n is a unit vector in the direction x, and n' a unit vector in the direction y, then —3 (x)=i \xn— yn\H-h,|xn—^Vy tnt| (2.2) If x is factored out of the first term and y' out of the second, the potential at x = a becomes: 3>(x=a)= q i .. + q — i n, a: . ;n y From the form of (2.3) it will be seen that the choices: (2.3) a y" ay' make <£(x = a) = 0, for all possible values of n«n'. Hence the magnitude and position of the image charge are q,'=-a-% y, =a-2 A\ (2.4) We note that, as the charge q is brought closer to the sphere, the image charge grows in magnitude and moves out from the center of the sphere. When q is just outside the surface of the sphere, the image charge is equal and opposite in magnitude and lies just beneath the surface. Now that the image charge has been found, we can return to the original problem of a charge q outside a grounded conducting sphere and consider various effects. The actual charge density induced on the surface of the sphere can be calculated from the normal derivative of at the surface: J_cKP I cr= 4tt dx x=a q /a\ \y Aira — 1H 2- 2 -cos 7 y y where 7 is the angle between x and y. This charge density in units of -q/4ira2 is shown plotted in Fig. 2.3 as a function of 7 for two values of y/a. The concentration of charge in the direction of the point charge q is evident, especially for y/a = 2. It is easy to show by direct integration that the total Sect. 2.2 Boundary-Value Problems in Electrostatics: I 57 Fig. 2.3 Surface-charge density cr induced on the grounded sphere of radius a due to the presence of a point charge q located a distance y away from the center of the sphere, cr is plotted in units of -q/4ira 2 as function of the angular position 7 away from the radius to the charge for y = 2a, 4a. induced charge on the sphere is equal to the magnitude of the image charge, as it must according to Gauss's law. The force acting on the charge q can be calculated in different ways. One (the easiest) way is to write down immediately the force between the charge q and the image charge q'. The distance between them is y - y' = y(l - a 2 /y 2). Hence the attractive force, according to Coulomb's law, is: For large separations the force is an inverse cube law, but close to the sphere it is proportional to the inverse square of the distance away from the surface of the sphere. The alternative method for obtaining the force is to calculate the total force acting on the surface of the sphere. The force on each element of area da is 2 27Tcr da, where cr is given by (2.5), as indicated in Fig. 2.4. But from symmetry it is clear that only the component parallel to the radius vector from the center of 58 Classical Electrodynamics dF = 27ra 2 da Sect. 2.3 Fig. 2.4 the sphere to q contributes to the total force. Hence the total force acting on the sphere (equal and opposite to the force acting on q) is given by the integral: (2.7) Integration immediately yields (2.6). The whole discussion has been based on the understanding that the point charge q is outside the sphere. Actually, the results apply equally for the charge q inside the sphere. The only change necessary is in the surface-charge density (2.5), where the normal derivative out of the conductor is now radially inwards, implying a change in sign. The reader may transcribe all the formulas, remem- < bering that now y a. The angular distributions of surface charge are similar to those of Fig. 2.3, but the total induced surface charge is evidently equal to -q, independent of y. 2.3 Point Charge in the Presence of a Charged, Insulated, Conducting Sphere In the previous section we considered the problem of a point charge q near a grounded sphere and saw that a surface-charge density was induced on the sphere. This charge was of total amount q' — —aq/y, and was distributed over the surface in such a way as to be in equilibrium under all forces acting. If we wish to consider the problem of an insulated conducting sphere with Q total charge in the presence of a point charge q, we can build up the solution for the potential by linear superposition. In an operational sense, we can imagine that we start with the grounded conducting sphere (with its charge q' distributed We over its surface). then disconnect the ground wire and add to the sphere an amount of charge (Q-q'). This brings the total charge on the sphere up to Q. To find the potential we merely note that the added charge (Q-q') will distribute itself uniformly over the surface, since the electrostatic forces due to the point charge q are already balanced by the charge q'. Hence the potential due to the added charge (Q— q') will be the same as if a point charge of that magnitude were at the origin, at least for points outside the sphere. Sect. 2.3 Boundary-Value Problems in Electrostatics: I 59 The potential is the superposition of (2.1) and the potential of a point charge (Q-q') at the origin: L /q/Q). Note that the asymptotic value of the force is attained as soon as the charge q is more than a few radii away from the sphere. This example exhibits a general property which explains why an excess of charge on the surface does not immediately leave the surface because of mutual repulsion of the individual charges. As soon as an element of charge is removed from the surface, the image force tends to attract it back. If sufficient work is done, of course, charge can be removed from the surface to infinity. The work function of a metal is in large part just the work done against the attractive image force in order to remove an electron from the surface. 2.4 Point Charge Near a Conducting Sphere at Fixed Potential Another problem which can be discussed easily is that of a point charge near a conducting sphere held at a fixed potential V. The potential is the same as for the charged sphere, except that the charge (Q-q') at the center is replaced by a charge (Va). This can be seen from (2.8), since at = |x| a the first two terms V cancel and the last term will be equal to as required. Thus the potential is The force on the charge q due to the sphere at fixed potential is For corresponding values of Va/q and Q/q this force is very similar to that of the charged sphere, shown in Fig. 2.5, although the approach to the asymptotic value (Vaq/y 2) is more gradual. For Va »q, the unstable equilibrium point has the equivalent location y — a(l+Wq/Va). 2.5 Conducting Sphere in a Uniform Electric Field by Method of Images As a final example of the method of images we consider a conducting sphere of E A radius a in a uniform electric field . uniform field can be thought of as being produced by appropriate positive and negative charges at infinity. For example, if there are two charges ±Q, located at positions z = =FR, as shown in Fig. 2.6a, Sect. 2.5 Boundary-Value Problems in Electrostatics: I 61 +Q z= -R S / aQ R ~ R JC \ V 2 R \ a\ -Q z=R (b) Fig. 2.6 Conducting sphere in a uniform electric field by the method of images. then in a region near the origin whose dimensions are very small compared to R E — there is an approximately constant electric field 2Q/R 2 parallel to the z axis. Q— In the limit as R, with Q/R 2 constant, this approximation becomes exact. If now a conducting sphere of radius a is placed at the origin, the potential will ±Q be that due to the charges at and their images =FQa/R at z = IFa 2/R: +R 2 (r 2 +2rRcos 1/2 6) Q +R 2 2 (r -2rRcos m 0) aQ aQ 1/2 (2.12) where 3> has been expressed in terms of the spherical coordinates of the R observation point. In the first two terms is much larger than r by assumption. R Hence we can expand the radicals after factoring out 2 . Similarly, in the third and fourth terms, we can factor out 2 r and then expand. The result is: = -E (r-^-) cose (2.14) 62 Classical Electrodynamics Sect. 2.6 E The first term (~E z) is, of course, just the potential of a uniform field which could have been written down directly instead of the first two terms in (2.12). The second is the potential due to the induced surface charge density or, equivalently, the image charges. Note that the image charges form a dipole of strength D=Qa/Rx2a2/R = E a3 . The induced surface-charge density is 1 a4> I = ,i Vti (216) In terms of spherical coordinates this can be written: ^ — ,2^, V G(x,x') = (x 2 +x'2 -2xx',c_o„s u7/) 12/2 - 7-2-72 (x 2 x'\ \-a 2 -2-xx , cos TT72 71 (2.17) where 7 is the angle between x and x\ The symmetry in the variables x and x' is G obvious in the form (2.17), as is the condition that = if either x or x' is on the surface of the sphere. For solution (1.44) of the Poisson equation we need not only G, but also dG/dri. Remembering that n' is the unit normal outwards from the volume of interest, i.e., inwards along x' toward the origin, we have dG I -a 2 2 (x ) dn'U~ a(x2 +a2 -2axcos 3/2 7) n1 ( } [Note that this is essentially the induced surface-charge density (2.5).] Hence the solution of the Laplace equation outside a sphere with the potential specified on its surface is, according to (1.44), *' fe« *> (^J-tfL y r dn ' (219) where dCl' is the element of solid angle at the point (a, 0', ') and cos 7 = cos cos 0'+sin sin 0' cos (-')• For the interior problem, the normal deriva- tive is radially outwards, so that the sign of dG/dri is opposite to (2.18). This is equivalent to replacing the factor -a 2 2 (x ) by -x 2 2 (a ) in (2.19). For a problem with a charge distribution, we must add to (2.19) the appropriate integral in (1.44), with the Green function (2.17). 2.7 Conducting Sphere with Hemispheres at Different Potentials As an example of the solution (2.19) for the potential outside a sphere with prescribed values of potential on its surface, we consider the conducting sphere of radius a made up of two hemispheres separated by a small insulating ring. The hemispheres are kept at different potentials. It will suffice to consider the potentials as ±V, since arbitrary potentials can be handled by superposition of the solution for a sphere at fixed potential over its whole surface. The insulating ring lies in the z = plane, as shown in Fig. 2.8, with the upper (lower) hemisphere at potential +V(-V). 64 Classical Electrodynamics z Sect. 2.7 y -v x Fig. 2.8 From (2.19) the solution for 4>(x, 0, ) is given by the integral: '—»<(>'+ 77), this can be cast in the form: "^ f'Wf = ) Va( * 2 ^cos 0')[(a 2 +x2 -2ax cos 7)" 3/2 477 Jo Jo -(a 2 +x 2 +2axcos7)- 3/2] (2.21) Because of the complicated dependence of cos 7 on the angles (0', <#>') and (0, ), equation (2.21) cannot in general be integrated in closed form. As a special case we consider the potential on the positive z axis. Then cos 7 = cos 0' since = 0. The integration is elementary, and the potential can be shown to be ( 2)=v[i-i^^l L zvz +a J (2.22) V At z = a, this reduces to = as required, while at large distances it goes — asymptotically as Va 2 2 3 /2z . In the absence of a closed expression for the integrals in (2.21), we can expand the denominator in power series and integrate term by term. Factoring out +x 2 2 (a ) from each denominator, we obtain & Zf/+aY F 0, = 2 y d d(C ° S ')[(1_2a cos T)"3/2 -(l + 2a cos y 3/2 ] jo (2.23) We where a = +x 2 2 ax/(a ). observe that in the expansion of the radicals only odd powers of a cos 7 will appear: [(l-2a cos 7)- 3/2 -(l + 2a cos = 7)" 3/2] 6a cos 7+35a 3 cos3 7+. . • (2.24) Sect. 2.8 Boundary-Value Problems in Electrostatics: I 65 It is now necessary to integrate odd powers of cos y over d' d(cos 0'): rvr d(cOS 0') COS 7 = 7T cos Jo Jo dp ^ d(cos 0') 3 cos 7 = cos 0(3 - cos2 0) J J (2.25) If (2.24) and (2.25) are inserted into (2.23), the potential becomes ^(R TO7 J ^^ aV ^(I/>(x,0,m*\) = 3VaVx3(^x2^-jac2) o\ s0[l1+x 35 „(3-cos2 ... 1 e)+-..J „ -~ (2.26) We note that only odd powers of cos appear, as required by the symmetry of the problem. If the expansion parameter is 22 (a /x ), rather than a2 , the series takes on the form: ^^[cos = ) + (§ 3 cos 0-1 cos 0) - • •] (2.27) For large values of x/a this expansion converges rapidly and so is a useful representation for the potential. Even for x/a =5, the second term in the series is only of the order of 2 per cent. It is easily verified that, for cos 0=1, expression (2.27) agrees with the expansion of (2.22) for the potential on the axis. [The particular choice of angular factors in (2.27) is dictated by the definitions of the Legendre polynomials. The two factors are, in fact, Pi (cos 0) and P3 (cos 0), and We the expansion of the potential is one in Legendre polynomials of odd order. shall establish this in a systematic fashion in Section 3.3.] 2.8 Orthogonal Functions and Expansions The representation of solutions of potential problems (or any mathematical physics problem) by expansions in orthogonal functions forms a powerful technique that can be used in a large class of problems. The particular orthogonal set chosen depends on the symmetries or near symmetries involved. To recall the general properties of orthogonal functions and expansions in terms of them, we consider an interval (a, b) in a variable £ with a set of real or complex functions l/n (£), n= 1, 2, . . . , square integrable and orthogonal on the interval (a, b). The orthogonality condition on the functions (/„(£) is expressed by Ut(t)Um (Z)dt = 0, J m*n (2.28) We If n = m, the integral is nonzero. assume that the functions are normalized so that the integral is unity. Then the functions are said to be orthonormal, and they satisfy fV^) 1/^)^=8™ (2.29) 66 Classical Electrodynamics Sect. 2.8 An arbitrary function /(£), square integrable on the interval (a, b), can be expanded in a series of the orthonormal functions U„(£). If the number of terms in the series is finite (say N), f(&**tN M number such that for the mean square error N can be made smaller than any arbitrarily small positive quantity. Then the series representation n= 1 with an given by (2.32) is said to converge in the mean to /(£). Physicists generally leave the difficult job of proving completeness of a given set of functions to the mathematicians. All orthonormal sets of functions normally occurring in mathematical physics have been proved to be complete. Series (2.33) can be rewritten with the explicit form (2.32) for the coefficients a„: «f)=f{i^(?)Un(&}m de (2.34) Since this represents any function /(£) on the interval (a, b), it is clear that the sum of bilinear terms Ut(ff)Un(& must exist only in the neighborhood of = £ In fact, it must be true that Iu!(?)U»(€) = 8(r-{) n=l (2.35) This is the so-called completeness or closure relation. It is analogous to the Sect. 2.8 Boundary-Value Problems in Electrostatics: I 67 orthonormality condition (2.29), except that the roles of the continuous variable £ and the discrete index n have been interchanged. The most famous orthogonal functions are the sines and cosines, an expansion in terms of them being a Fourier series. If the interval in x is (-a/2, a/2), the orthonormal functions are l^> [2 . (2irmx\ Va S,n [2 (2imxx\ Va COS l^-) m m where is an integer and for = the cosine function is 1/Va. The series equivalent to (2.33) is customarily written in the form: where /(x) = Uo+| [Aw cos (^P)+Bm sin (^p)] (2.36) _ 2 a/2 ( , . (2irmx\ . (2.37) If the interval spanned by the orthonormal set has more than one dimension, formulas (2.28)-(2.33) have obvious generalizations. Suppose that the space is two dimensional, and that the variable £ ranges over the interval (a, b) while the variable -n has the interval (c, d). The orthonormal functions in each dimension V are U„(£) and m(r)). Then the expansion of an arbitrary function /(£, -n) is L Z U = f(fc t|) anm n (£)Vm (r]) (2.38) where jNf ^ anm = dT,U?(€) (T,)/(& T]) (2 - 39) U If the interval (a, b) becomes infinite, the set of orthogonal functions n(& may become a continuum of functions, rather than a denumerable set. Then the Kronecker delta symbol in (2.29) becomes a Dirac delta function. An important example is the Fourier integral. Start with the orthonormal set of complex exponentials, U ™ = -^e m (x) i(2 x/a) va (2.40) m = 0, ±1, ±2, . . , . on the interval (-a/2, a/2), with the expansion: where t A ™ f(*)=4= i(2 me x/a) va m =-=c a/2 f(x') dx' (2.41) (2.42) 68 Classical Electrodynamics Sect. 2.9 Then let the interval become infinite (a-»o°), at the same time transforming 2irm [ dm = -— f dk > m J-oo Z7T J oc (2.43) A(k) The resulting expansion, equivalent to (2.41), is the Fourier integral, where /(x)= vfef Mk)eikxdk A(k) = 7W ik e" dx ^=J°° (2.44) (2.45) The orthogonality condition is P ^- i(k - k)x e dx = 8(k-k') Z7T J-oo while the completeness relation is (2.46) -M = dk ik(x~x) e 8(x-x') Z7T J-oo (2.47) We These last integrals serve as convenient representations of a delta function. note in (2.44)-(2.47) the complete equivalence of the two continuous variables x and k. 2.9 Separation of Variables, Laplace Equation in Rectangular Coordinates The partial differential equations of mathematical physics are often solved conveniently by a method called separation of variables. In the process, one often generates orthogonal sets of functions which are useful in their own right. Equations involving the three-dimensional Laplacian operator are known to be separable in eleven different coordinate systems (see Morse and Feshbach, pp. We — 509, 655). will discuss only three of these in any detail rectangular, — spherical, and cylindrical and will begin with the simplest, rectangular coordi- nates. The Laplace equation in rectangular coordinates is Sect. 2.9 Boundary-Value Problems in Electrostatics: I 69 A solution of this partial differential equation can be found in terms of three ordinary differential equations, all of the same form, by the assumption that the potential can be represented by a product of three functions, one for each coordinate: d>(x,y,z) = X(x)Y(y)Z(z) (2.49) _L c ,/=J * IIz (2.52) At this stage a and |3 are completely arbitrary. Consequently (2.52), by linear superposition, represents a very large class of solutions to the Laplace equation. To determine a and |3 it is necessary to impose specific boundary conditions on the potential. As an example, consider a rectangular box, located as shown in Fig. 2.9, with dimensions (a, b, c) in the (x, y, z) directions. All surfaces of the box are kept at zero potential, except the surface = z c, which is at a potential V(x, y). It is required to find the potential everywhere inside the box. Starting with the requirement that = for x = 0, y = 0, z = 0, it is easy to see that the required forms of X, Y, Z are X=sin ax Y=sin (3y Z = sinh (Va 2 +02 z) 70 Classical Electrodynamics f = V(x,y) $ = o- f= =6 Sect. 2.9 v# = Fig. 2.9 Hollow, rectangular box with five sides at zero potential, while the sixth (z = c) has the specified potential = V(x, y). In order that 4> = at x = a and y = b, it is necessary that aa = nir and |3b = mix. With the definitions, = M77 Oin T 0~ = (2.54) 2+ 2 b O we can write the partial potential nm , satisfying all the boundary conditions except one, 3> nm = sin (anx) sin (0m y) sinh (ynm z) (2.55) The potential can be expanded in terms of these <£> nm with initially arbitrary coefficients (to be chosen to satisfy the final boundary condition): £ A = <£(x, y, z) «m sin («**) sin (Pmy) sinh (7nmZ) n,m=l There remains only the boundary condition <$= V(x, y) at z = c: (2.56) X A V(x, y) = «m sin (a„x) sin (|3m y) sinh (y„m c) (2.57) This is just a double Fourier series for the function V(x, y). Consequently the A coefficients nm are given by: ab sinh (ynm c) j^dxj^dy V(x, y) sin (anx) sin (/^y) (2.58) Sect. 2.10 Boundary-Value Problems in Electrostatics: I 71 If the rectangular box has potentials different from zero on all six sides, the required solution for the potential inside the box can be obtained by a linear superposition of six solutions, one for each side, equivalent to (2.56) and (2.58). The problem of the solution of the Poisson equation, that is, the potential inside the box with a charge distribution inside, as well as prescribed boundary conditions on the surface, requires the construction of the appropriate Green function, according to (1.43) and (1.44). Discussion of this topic will be deferred until we have treated the Laplace equation in spherical and cylindrical coordinates. For the moment, we merely note that solution (2.56) and (2.58) is equivalent to the surface integral in the Green function solution (1.44). 2.10 A Two-Dimensional Potential Problem, Summation of a Fourier Series We now consider briefly the solution by separation of variables of the two- dimensional Laplace equation in Cartesian coordinates. By two-dimensional problems we mean those in which the potential can be assumed to be independent of one of the coordinates, say, z. This is usually only an approxima- tion, but may hold true to high accuracy, as in a long uniform transmission line. If the potential is independent of z, the basic solutions of the previous section reduce to the products e where a is any real or complex constant. The imposition of boundary conditions on the potential will determine what values of a are permitted and the form of the linear superposition of different solutions required. A simple problem that can be used to demonstrate the separation of variables technique and also establish connection with the use of complex variables is indicated in Fig. 2.10. The potential in the region, 0 = at x = and x = a, while = at y = 0for0 = for y = 0, 0 *= $ = o- Sect. 2.10 y/a = 0.5 = ;v/a 0.1 3. Fig. 2.10 Two-dimensional potential problem. With 4>(x, 0)= V, one finds A= 4Vfl 7rnl0 for n odd for n even The potential (x, y) is therefore determined to be — h ®(x>y) = 4V v —1 exp (-mry/a) sin (mrx/a) 77 noddH (2.61) For small values of y many terms in the series are necessary to give an accurate approximation, but for y>alir it is evident that only the first few terms are appreciable. The potential rapidly approaches its asymptotic form given by the first term, —4V <£(x, y)—> exp (-Try/a) sin (-rrx/a) (2.62) Paranthetically, we remark that this general behavior is characteristic of all boundary-value problems of this type, independently of whether (x, 0) is a constant or not, provided the first term in the series is nonvanishing. The