Overview

This book is a translation of the 8th edition of Prof. Kazuhiko Nishijima’s classical textbook on quantum field theory. It is based on the lectures the Author gave to students and researchers with diverse interests over several years in Japan. The book includes both the historical development of QFT and its practical use in theoretical and experimental particle physics, presented in a pedagogical and transparent way and, in several parts, in a unique and original manner. The Author, Academician Nishijima, is the inventor (independently from Murray Gell-Mann) of the third (besides the electric charge and isospin) quantum number in particle physics: strangeness. He is also most known for his works on several other theories describing particles such as electron and muon neutrinos, and his work on the so-called Gell-Mann–Nishijima formula. The present English translation from its 8th Japanese edition has been initiated and taken care of by theeditors Prof. M. Chaichian and Dr. A. Tureanu from the University of Helsinki, who were close collaborators of Prof. Nishijima. Dr. Yuki Sato, a researcher in particle physics at the University of Nagoya, most kindly accepted to undertake the heavy task of translation. The translation of the book can be regarded as a tribute to Prof. Nishijima's memory, for his fundamental contributions to particle physics and quantum field theory. The book presents with utmost clarity and originality the most important topics and applications of QFT which by now constitute the established core of the theory. It is intended for a wide circle of graduate and post-graduate students, as well as researchers in theoretical and particle physics. In addition, the book can be a useful source as a basic material or supplementary literature for lecturers giving a course on quantum field theory.

Full Product Details

Author:   Kazuhiko Nishijima ,  Masud Chaichian ,  Anca Tureanu ,  Yuki Sato
Publisher:   Springer
Imprint:   Springer
Edition:   1st ed. 2023
Weight:   1.039kg
ISBN:  

9789402421897

ISBN 10:   9402421890
Pages:   572
Publication Date:   13 November 2022
Audience:   Professional and scholarly ,  Professional & Vocational
Format:   Hardback
Publisher's Status:   Active
Availability:   Manufactured on demand  
We will order this item for you from a manufactured on demand supplier.
Language:   English

Table of Contents

1 Elementary Particle Theory and Field Theory 1.1 Classification of Interactions and Yukawa’s Theory 1.2 Muon as the First Member of the Second Generation 1.3 Quantum Electrodynamics 1.4 Road from Pions to Hadrons 1.5 Strange Particles as Members of the Second Generation 1.6 Non-conservation of Parity 1.7 Neutrino in the Second Generation 1.8 Democracy and Aristocratism of Hadrons—Quark Model 2 Canonical Formalism and Quantum Mechanics 2.1 Schr¨odinger’s Picture and Heisenberg’s Picture 2.2 Hamilton’s Principle 2.3 Equivalence between Canonical Equation and Lagrange’s Equation 2.4 Equal-Time Canonical Commutation Relations 3 Quantisation of Free Fields 3.1 Field Theory Based on Canonical Formalism 3.2 Relativistic Generalisation of Canonical Equation 3.3 Quantisation of Real Scalar Field 3.4 Quantisation of Complex Scalar Field 3.5 Dirac’s Equation 3.6 Relativistic Invertibilities of Dirac’s Wave Function 3.7 Solutions of Free Dirac’s Equation 3.8 Quantisation of the Dirac Field 3.9 Charge Conjugation 3.10 Quantisation of Complex Vector Field 4 Invariant Functions and Quantisation of Free Fields 4.1 Unequal-time Commutation Relations of Real Scalar Field 4.2 Various Sorts of Invariant Functions 4.3 Unequal-time Commutation Relations of Free Fields 4.4 Generality of Quantisation of Free Fields 5 Indefinite Metric and Electromagnetic Field 5.1 Indefinite Metric 5.2 Generalised Eigenstates 5.3 Free Electromagnetic Field—Fermi’s Gauge 5.4 Lorentz Condition and Physical State Space 5.5 Free Electromagnetic Field—Generalisation of Gauge Choices 6 Quantisation of Interacting Systems 6.1 Tomonaga-Schwinger Equation 6.2 Retarded Product Expansion of Heisenberg’s Operators 6.3 Yang-Feldman Expansion of Heisenberg’s Operators 6.4 Examples of Interactions 7 Symmetries and Conservation Laws 7.1 Noether’s Theorem for Point-Particle Systems 7.2 Noether’s Theorem in Field Theory 7.3 Examples of Noether’s Theorem 7.4 Poincar´e Invariance 7.5 Representations of Lorentz Group 7.6 Spin of a Massless Particle 7.7 Pauli-G¨ursey Group 8 S-Matrix 8.1 Definition of S-Matrix 8.2 Dyson’s Formula for S-Matrix 8.3 Wick’s Theorem 8.4 Feynman Diagrams 8.5 Examples of S-Matrix Elements 8.6 Furry’s Theorem 8.7 Two-Photon Decays of Neutral Mesons 9 Cross Sections and Decay Widths 9.1 Møller’s Formula for Cross Sections and Formula of Decay Widths 9.2 Examples of Cross Sections and Decay Widths 9.3 Inclusive Reactions 9.4 Optical Theorem 9.5 Three-Body Decays 10 Discrete Symmetries 10.1 Symmetries and Unitary Transformations 10.2 Parity of Antiparticles 10.3 Isospin Parity and G-Conjugation 10.4 Anti-unitary Transformations 10.5 CPT Theorem 11 Green’s Functions 11.1 Gell-Mann-Low Relation 11.2 Green’s Functions and Their Generating Functionals 11.3 Time-Orderings in Lagrangian Formalism 11.4 Matthews’ Theorem 11.5An Example of Matthews’ Theorem with Modification 11.6 Reduction Formula in the Interaction Picture 11.7 Asymptotic Conditions 11.8 Unitarity Condition on Green’s Function 11.9 Retarded Green’s Functions 12 Renormalisation Theory 12.1 Lippmann-Schwinger Equation 12.2 Renormalised Interaction Picture 12.3 Renormalisation of Masses 12.4 Renormalisation of Field Operators 12.5 Renormalised Propagators 12.6 Renormalisation of Vertex Functions 12.7 Ward-Takahashi Identity 12.8 Integral Representation of Propagator 13 Classification of Hadrons and Models 13.1 Unitary Groups 13.2 SU(3) Group 13.3 Universality of p-Meson Decay Interactions 13.4 Beta-Decay 13.5 Universality of Fermi’s Interaction 13.6 Quark Model in Weak Interactions 13.7 Quark Model in Strong Interactions 13.8 Parton Model 14 What is Gauge Theory? 14.1Gauge Transformation of Electromagnetic Field 14.2 Non-Abelian Gauge Field 14.3 Gravitational Field as Gauge Field 15 Spontaneous Symmetry Breaking 15.1 Nambu-Goldstone Particles 15.2 Sigma Model 15.3 Mechanism of Spontaneous Symmetry Breaking 15.4 Higgs Mechanism 15.5 Higgs Mechanism under Covariant Gauge Condition 15.6 Kibble’s Theorem 16 Weinberg-Salam Model 16.1 Weinberg-Salam Model 16.2 Introducing Fermions 16.3 GIM Mechanism 16.4 Anomalous Terms and Generation of Fermions 16.5 Grand Unified Theory 17 Path-Integral Method 17.1 Quantisation of a Point-Particle System 17.2 Quantisation of Fields 18 Quantisation of Gauge Fields via Path Integral Method 18.1 Quantisation of Gauge Fields 18.2 Quantisation of Electromagnetic 18.3 Quantisation of Non-Abelian Gauge Fields 18.4 Axial Gauge 18.5 Feynman Rule in Axial Gauge 19 Becchi-Rouet-Stora Transformations 19.1 BRS Transformations 19.2 BRS Charge 19.3 Another BRS Transformation 19.4 BRS Identity and Slavnov-Taylor Identity 19.5 Representations of BRS Algebra 19.6 Unitarity of S-Matrix 19.7 Representations of Extended BRS Algebra 19.8 Representations of BRS Transformations for Auxiliary Fields 19.9 Representations of BRSNO Algebras 20 Renormalisation Group 20.1 Renormalisation Group for QED 20.2 Approximate Equations for Renormalisation Group 20.3 Ovsianikov’s Equation 20.4 Linear Equations for Renormalisation Group 20.5 Callan-Symanzik Equation 20.6Homogeneous Callan-Symanzik Equation 20.7 Renormalisation Group for Non-Abelian Gauge Theory 20.8 Asymptotic Freedom 20.9Gauge Dependence of Green’s Functions 21 Theory of Confinement 21.1Gauge Independence of Confinement Condition 21.2 Sufficient Condition for Colour Confinement 21.3 Colour Confinement and Asymptotic Freedom 22 Anomalous Terms and Dispersion 22.1 Examples of Indefiniteness and Anomalous 22.2 Dispersion Theory for Green’s 22.3 Subtractions in Dispersion Relation 22.4 Heisenberg’s 22.5 Subtraction 22.6 Anomalous Trace 22.7 Triangle-Anomaly Terms

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Author Information

Kazuhiko Nishijima (1926 – 2009) was a Japanese physicist who made significant contributions to particle physics. Until his death in 2009 he was Professor Emeritus at the University of Tokyo and Kyoto University. He is most well-known for his work on the Gell-Mann–Nishijima formula, and the concept of strangeness. He was nominated for the Nobel Prize in Physics in 1960 and 1961. Prof. Masud Chaichian and Dr. Anca Tureanu are physicists at University of Helsinki. They were close collaborators of Prof. Nishijima. Yuki Sato is Associate Professor at National Institute of Technology, Tokuyama College and visiting faculty member at Nagoya University.

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