This book provides an understanding of the theoretical foundations for the calculation of electromagnetic processes. Photon production processes are particularly important in astrophysics, since almost all of our knowledge of distant astronomical objects comes from the detection of radiation from these sources. Further, the conditions therein are extremely varied and a wide variety of naturally occurring electromagnetic phenomena can be described by limiting forms of the basic theory.
The first chapter reviews some basic principles that are the underpinnings for a general description of electromagnetic phenomena, such as special relativity and, especially, relativistic covariance. Classical and quantum electrodynamics (QED) are then formulated in the next two chapters, followed by applications to three basic processes (Coulomb scattering, Compton scattering, and bremsstrahlung). These processes are related to other phenomena, such as pair production, and the comparisons are discussed.
A unique feature of the book is its thorough discussion of the nonrelativistic limit of QED, which is simpler than the relativistic theory in its formulation and applications. The methods of the relativistic theory are introduced and applied through the use of notions of covariance, to provide a shorter path to the more general theory. The book will be useful for graduate students working in astrophysics and in certain areas of particle physics.
Arvustused
"A remarkable intellectual achievement Few books make such a valiant and successful effort to explain the physics of these processes. This book fills an important gap in the literature."Malcolm Longair, Cambridge University "An excellent, well-written, and well-organized discourse that has a worthy place in the literature. It will provide a valuable graduate teaching and reference work for physicists and astrophysicists for years to come."Matthew Baring, Rice University "Solid and rich in physics. A very useful book for anyone interested in the physics of astrophysics."David Spergel, Princeton University "This is a clearly written and comprehensive book on electromagnetic processes by one of the leading experts in this area. The book covers both classical and quantum processes and discusses the relativistic and nonrelativistic limits. Both graduate students and researchers interested in the underlying processes by which radiation is produced will find Gould's book to be both easily understandable and extremely useful."George Blumenthal, University of California, Santa Cruz "Electromagnetic Processes is a lucid exposition of the physics that is fundamental for much of modern physics. Since our entire observational understanding of the universe thus far relies on such processes, this book is a timely addition to the lexicon for astronomy and astrophysics, for which its clear exposition of Compton scattering in the relativistic limit, for example, provides a welcome addition to the literature. Gould has wisely chosen to use cgs units, which makes its applications and familiarity to the astrophysicist that much more direct. Gould writes in a clear and complete style, with interesting historical notes to complement and accent the derivations. This book fills the gap between Jackson and Rybicki and Lightman and will serve both reference and textbook needs."Jonathan E. Grindlay, Robert Treat Paine Professor of Astronomy, Harvard University "Electromagnetic Processes fills an important niche in the spectrum of advanced texts on radiation processes for graduate students and professional astrophysicists. Gould provides a clear connection between classical and quantum treatments of basic processes like Compton scattering and bremsstrahlung, in both the non-relativistic and relativistic regimes. Standard texts generally provide a sketchy overview of the QED corrections, while books on QED itself are often difficult to weed through for the needed formulae. I highly recommend this book for those seeking a more complete overview of the basic physics of the interaction of radiation with charged particles."Steven M. Kahn, Stanford University "Electromagnetic Processes succeeds brilliantly in providing a unified treatment of the foundations of classical and quantum electrodynamics with clarity and scholarship and highlighting the intellectual beauty of the subject. This is the book to which students and researchers will turn as they struggle to solve problems in the countless applications of electrodynamics."Roger Blandford, Stanford University
Muu info
A remarkable intellectual achievement Few books make such a valiant and successful effort to explain the physics of these processes. This book fills an important gap in the literature. -- Malcolm Longair, Cambridge University An excellent, well-written, and well-organized discourse that has a worthy place in the literature. It will provide a valuable graduate teaching and reference work for physicists and astrophysicists for years to come. -- Matthew Baring, Rice University Solid and rich in physics. A very useful book for anyone interested in the physics of astrophysics. -- David Spergel, Princeton University This is a clearly written and comprehensive book on electromagnetic processes by one of the leading experts in this area. The book covers both classical and quantum processes and discusses the relativistic and nonrelativistic limits. Both graduate students and researchers interested in the underlying processes by which radiation is produced will find Gould's book to be both easily understandable and extremely useful. -- George Blumenthal, University of California, Santa Cruz Electromagnetic Processes is a lucid exposition of the physics that is fundamental for much of modern physics. Since our entire observational understanding of the universe thus far relies on such processes, this book is a timely addition to the lexicon for astronomy and astrophysics, for which its clear exposition of Compton scattering in the relativistic limit, for example, provides a welcome addition to the literature. Gould has wisely chosen to use cgs units, which makes its applications and familiarity to the astrophysicist that much more direct. Gould writes in a clear and complete style, with interesting historical notes to complement and accent the derivations. This book fills the gap between Jackson and Rybicki and Lightman and will serve both reference and textbook needs. -- Jonathan E. Grindlay, Robert Treat Paine Professor of Astronomy, Harvard University Electromagnetic Processes fills an important niche in the spectrum of advanced texts on radiation processes for graduate students and professional astrophysicists. Gould provides a clear connection between classical and quantum treatments of basic processes like Compton scattering and bremsstrahlung, in both the non-relativistic and relativistic regimes. Standard texts generally provide a sketchy overview of the QED corrections, while books on QED itself are often difficult to weed through for the needed formulae. I highly recommend this book for those seeking a more complete overview of the basic physics of the interaction of radiation with charged particles. -- Steven M. Kahn, Stanford University Electromagnetic Processes succeeds brilliantly in providing a unified treatment of the foundations of classical and quantum electrodynamics with clarity and scholarship and highlighting the intellectual beauty of the subject. This is the book to which students and researchers will turn as they struggle to solve problems in the countless applications of electrodynamics. -- Roger Blandford, Stanford University
Preface ix
Chapter
1. Some Fundamental Principles 1.1 Units and
Characteristic Lengths, Times, Energies, Etc. 1.2 Relativistic Covariance and
Relativistic Invariants 5 1.2.1 Spacetime Transformation 5 1.2.2 Other
Four-Vectors and Tensors-Covariance 8 1.2.3 Some Useful and Important
Invariants 10 1.2.4 Covariant Mechanics and Electrodynamics 13 1.3
Kinematic Effects 15 1.3.1 Threshold Energies in Non-Relativistic and
Relativistic Processes 15 1.3.2 Transformations of Angular Distributions 17
1.4 Binary Collision Rates 18 1.5 Phase-Space Factors 21 1.5.1 Introduction
21 1.5.2 Simple Examples 23 1.5.3 General Theorems-Formulation 26 1.5.4
General Formulas-Evaluation of Multiple Integrals 28 1.5.5 One-Particle
Distributions 32 1.5.6 Invariant Phase Space 34
Chapter
2. Classical
Electrodynamics 37 2.1 Retarded Potentials 37 2.1.1 Fields, Potentials, and
Gauges 37 2.1.2 Retarded Potentials in the Lorentz Gauge 39 2.2 Multipole
Expansion of the Radiation Field 41 2.2.1 Vector Potential and Retardation
Expansion 41 2.2.2 Multipole Radiated Power 43 2.3 Fourier Spectra 46 2.4
Fields of a Charge in Relativistic Motion 49 2.4.1 Lienard-Wiechert
Potentials 49 2.4.2 Charge in Uniform Motion 51 2.4.3 Fields of an
Accelerated Charge 53 2.5 Radiation from a Relativistic Charge 54 2.6
Radiation Reaction 57 2.6.1 Non-Relativistic Limit 57 2.6.2 Relativistic
Theory: Lorentz-Dirac Equation 60 2.7 Soft-Photon Emission 61 2.7.1
Multipole Formulation 61 2.7.2 Dipole Formula 62 2.7.3 Emission from
Relativistic Particles 63 2.8 Weizsacker-Williams Method 65 2.8.1 Fields of
a Moving Charge 66 2.8.2 Equivalent Photon Fluxes 68 2.9 Absorption and
Stimulated Emission 70 2.9.1 Relation to Spontaneous Emission 71 2.9.2
General Multiphoton Formula 72 2.9.3 Stimulated Scattering 73
Chapter
3. Quantum Electrodynamics 75 3.1 Brief Historical Sketch 76 3.2
Relationship with Classical Electrodynamics 78 3.3 Non-Relativistic
Formulation 80 3.3.1 Introductory Remarks 80 3.3.2 Classical Interaction
Hamiltonian 80 3.3.3 Quantum-Mechanical Interaction Hamiltonian 83 3.3.4
Perturbation Theory 84 3.3.5 Processes, Vertices, and Diagrams 88 3.4
Relativistic Theory 94 3.4.1 Modifications of the Non-Covariant Formulation
94 3.4.2 Photon Interactions with Charges without Spin 97 3.4.3 Spin- 1 2
Interactions 103 3.4.4 Invariant Transition Rate 107 3.5 Soft-Photon
Emission 109 3.5.1 Non-Relativistic Limit 109 3.5.2 Emission from Spin
Transitions 113 3.5.3 Relativistic Particles without Spin 116 3.5.4
Relativistic Spin- 1 2 Particles 119 3.6 Special Features of
Electromagnetic Processes 123 3.6.1 "Order" of a Process 123 3.6.2
Radiative Corrections and Renormalization 127 3.6.3 Kinematic Invariants 130
3.6.4 Crossing Symmetry 132
Chapter
4. Elastic Scattering of Charged
Particles 135 4.1 Classical Coulomb Scattering 135 4.1.1 Small-Angle
Scattering 135 4.1.2 General Case 138 4.1.3 Two-Body Problem-Relative
Motion 139 4.1.4 Validity of the Classical Limit 141 4.2 Non-Relativistic
Born Approximation and Exact Treatment 142 4.2.1 Perturbation-Theory
Formulation 142 4.2.2 Sketch of Exact Theory 145 4.2.3 Two-Body Problem 148
4.2.4 Scattering of Identical Particles 150 4.2.5 Validity of the Born
Approximation 154 4.3 Scattering of Relativistic Particles of Zero Spin 156
4.3.1 Coulomb Scattering 156 4.3.2 Scattering of Two Distinguishable Charges
158 4.3.3 Two Identical Charges 162 4.3.4 Scattering of Charged
Antiparticles 163 4.4 Scattering of Relativistic Spin- 1 2 Particles 166
4.4.1 Spin Sums, Projection Operators, and Trace Theorems 166 4.4.2 Coulomb
Scattering 170 4.4.3 Moller and Bhabha Scattering 171
Chapter
5.
Compton Scattering 177 5.1 Classical Limit 177 5.1.1 Kinematics of the
Scattering 177 5.1.2 Derivation of the Thomson Cross Section 178 5.1.3
Validity of the Classical Limit 181 5.2 Quantum-Mechanical Derivation:
Non-Relativistic Limit 182 5.2.1 Interactions and Diagrams 182 5.2.2
Calculation of the Cross Section 184 5.3 Scattering by a Magnetic Moment 186
5.4 Relativistic Spin-0 Case 188 5.5 Relativistic Spin- 1 2 Problem:
Klein-Nishina Formula 191 5.5.1 Formulation 191 5.5.2 Evaluation of the
Cross Section 193 5.5.3 Invariant Forms 194 5.5.4 Limiting Forms and
Comparisons 195 5.6 Relationship to Pair Annihilation and Production 197
5.7 Double Compton Scattering 199 5.7.1 Non-Relativistic Case. Soft-Photon
Limit 199 5.7.2 Non-Relativistic Case. Arbitrary Energy 202 5.7.3 Extreme
Relativistic Limit 207
Chapter
6. Bremsstrahlung 211 6.1 Classical
Limit 211 6.1.1 Soft-Photon Limit 211 6.1.2 General Case: Definition of the
Gaunt Factor 214 6.2 Non-Relativistic Born Limit 217 6.2.1 General
Formulation for Single-Particle Bremsstrahlung 217 6.2.2 Coulomb (and
Screened-Coulomb) Bremsstrahlung 222 6.2.3 Born Correction:
Sommerfeld-Elwert Factor 223 6.2.4 Electron-Positron Bremsstrahlung 226 6.3
Electron-Electron Bremsstrahlung. Non-Relativistic 228 6.3.1 Direct Born
Amplitude 228 6.3.2 Photon-Emission Probability (without Exchange) 232
6.3.3 Cross Section (with Exchange) 234 6.4 Intermediate Energies 236 6.4.1
General Result. Gaunt Factor 236 6.4.2 Soft-Photon Limit 239 6.5
Relativistic Coulomb Bremsstrahlung 240 6.5.1 Spin-0 Problem 241 6.5.2
Spin- 1 2 : Bethe-Heitler Formula 244 6.5.3 Relativistic Electron-Electron
Bremsstrahlung 248 6.5.4 Weizsacker-Williams Method 251 6.6 Electron-Atom
Bremsstrahlung 254 6.6.1 Low Energies 254 6.6.2 Born Limit-Non-Relativistic
256 6.6.3 Intermediate Energies-Non-Relativistic 257 6.6.4 Relativistic
Energies-Formulation 259 6.6.5 Relativistic Energies-Results and Discussion
264 Index 269
Robert J. Gould is Research Professor of Physics at the University of California, San Diego. His research focuses on atomic, nuclear, and particle processes; statistical mechanics; and applications of astrophysics.
