Volume 1 of this revised and updated edition provides an accessible and practical introduction to the first gauge theory included in the Standard Model of particle physics: quantum electrodynamics (QED).
The book includes self-contained presentations of electromagnetism as a gauge theory as well as relativistic quantum mechanics. It provides a unique elementary introduction to quantum field theory, establishing the essentials of the formal and conceptual framework upon which the subsequent development of the three gauge theories is based. The text also describes tree-level calculations of physical processes in QED and introduces ideas of renormalization in the context of one-loop radiative corrections for QED.
New to the Fourth Edition
- New chapter on Lorentz transformations and discrete symmetries in relativistic quantum mechanics, with physical applications
- Introduction of Majorana fermions at an early stage, making the material suitable for a first course in relativistic quantum mechanics
- Discrete symmetries in quantum field theory
- Updates on nucleon structure functions and the status of QED
The authors discuss the main conceptual points of the theory, detail many practical calculations of physical quantities from first principles, and compare these quantitative predictions with experimental results, helping readers improve both their calculation skills and physical insight.
|Publisher:||Taylor & Francis|
|Edition description:||New Edition|
|Product dimensions:||6.00(w) x 9.30(h) x 1.00(d)|
About the Author
Ian J.R. Aitchison is Emeritus Professor of Physics at the University of Oxford and a visiting scientist at SLAC National Accelerator Laboratory. He has previously held research positions at Brookhaven National Laboratory, Saclay, and the University of Cambridge. He was a visiting professor at the University of Rochester and the University of Washington, and a scientific associate at CERN. Dr. Aitchison has published over 90 scientific papers mainly on hadronic physics and quantum field theory. He is the author of Relativistic Quantum Mechanics, An Informal Introduction to Gauge Field Theories, and Supersymmetry in Particle Physics and joint editor of two other books.
Anthony J.G. Hey is Vice President of Microsoft Research Connections, where he is responsible for the worldwide external research and technical computing strategy across Microsoft Corporation. A fellow of the U.K. Royal Academy of Engineering, Dr. Hey was previously the director of the U.K. e-Science Initiative and the head of the School of Electronics and Computer Science and dean of Engineering and Applied Science at the University of Southampton. His research interests encompass parallel programming for parallel systems built from mainstream commodity components. With Jack Dongarra, Rolf Hempel, and David Walker, he wrote the first draft of a specification for a new message-passing standard called MPI. This initiated the process that led to the successful MPI standard of today.
Table of Contents
INTRODUCTORY SURVEY, ELECTROMAGNETISM AS A GAUGE THEORY, AND RELATIVISTIC QUANTUM MECHANICS
The Particles and Forces of in the Standard Model
Electromagnetism as a Gauge Theory
Relativistic Quantum Mechanics
Lorentz Transformations and Discrete Symmetries
INTRODUCTION TO QUANTUM FIELD THEORY
Quantum Field Theory I: The Free Scalar Field
Quantum Field Theory II: Interacting Scalar Fields
Quantum Field Theory III: Complex Scalar Fields, Dirac and Maxwell Fields; Introduction of Electromagnetic Interactions
TREE-LEVEL APPLICATIONS IN QED
Elementary Processes in Scalar and Spinor Electrodynamics
Deep Inelastic Electron-Nucleon Scattering and the Parton Model
LOOPS AND RENORMALIZATION
Loops and Renormalization I: The ABC Theory
Loops and Renormalization II: QED
APPENDIX A: Non-Relativistic Quantum Mechanics
APPENDIX B: Natural Units
APPENDIX C: Maxwell's Equations: Choice of Units
APPENDIX D: Special Relativity: Invariance and Covariance
APPENDIX E: Dirac Delta-Function
APPENDIX F: Contour Integration
APPENDIX G: Green Functions
APPENDIX H: Elements of Non-Relativistic Scattering Theory
APPENDIX I: The Schrödinger and Heisenberg Pictures
APPENDIX J: Dirac Algebra and Trace Identities
APPENDIX K: Example of a Cross Section Calculation
APPENDIX L: Feynman Rules for Tree Graphs in QED
Problems appear at the end of each chapter.