Helping readers understand the complicated laws of nature, Advanced Particle Physics Volume I: Particles, Fields, and Quantum Electrodynamics explains the calculations, experimental procedures, and measuring methods of particle physics. It also describes modern physics devices, including accelerators, elementary particle detectors, and neutrino telescopes. The book first introduces the mathematical basis of modern quantum field theory. It presents the most pertinent information on group theory, proves Noether's theorem, and determines the major motion integrals connected with both space and internal symmetry. The second part on fundamental interactions and their unifications discusses the main theoretical preconditions and experiments that allow for matter structure to be established at the quark-lepton level. In the third part, the author investigates the secondary quantized theories of free fields with spin 0, 1/2, and 1, with particular emphasis on the neutrino field. The final part focuses on quantum electrodynamics, the first successfully operating quantum field theory. Along with different renormalization schemes of quantum field theory, the author covers the calculation methods for polarized and unpolarized particles, with and without inclusion of radiative corrections. Each part in this volume contains problems to help readers master the calculation techniques and generalize the results obtained. To improve understanding of the computation procedures in quantum field theory, the majority of the calculations have been performed without dropping complex intermediate steps.

Providing a complete foundation to comprehend the physics of the microworld, Advanced Particle Physics, Two-Volume Set develops the models, theoretical framework, and mathematical tools to understand current experiments and make predictions for future experiments. The set brings together a vast array of topics in modern particle physics and distills the material in a rigorous yet accessible manner. All intermediate mathematical steps are derived and numerous application examples help readers gain a thorough, working knowledge of the subject. The first volume on particles, fields, and quantum electrodynamics covers: * The mathematical foundation of quantum field theory * The interactions and particles of the Standard Model * How accelerators, detectors, and neutrino telescopes are used in particle physics experiments * The technique of renormalization in quantum electrodynamics The second volume on the Standard Model and beyond discusses: * The technique of renormalization in quantum chromodynamics (QCD) * The status of current QCD experiments * Physics beyond the Standard Model, including composite models and a left-right model * How solar and atmospheric neutrinos are detected and analyzed The books in this two-volume set enable readers not only to perform complicated and skilled calculations, but also to propose and elaborate new theories. Each book contains extensive references that offer a comprehensive perspective on the literature and historical development of particle physics.

Helping readers understand the complicated laws of nature, Advanced Particle Physics Volume II: The Standard Model and Beyond explains the calculations, experimental procedures, and measuring methods of particle physics, particularly quantum chromodynamics (QCD). It also discusses extensions to the Standard Model and the physics of massive neutrinos. Divided into three parts, this volume begins with QCD. It explains the quantization scheme using functional integrals and investigates renormalization problems. The book also calculates cross sections of basic hard processes and covers nonperturbative methods, such as the lattice approach and QCD vacuum. The next part focuses on electroweak interactions, in which the author describes the Glashow-Weinberg-Salam theory and presents composite models and a left-right symmetric model as extensions to the Standard Model. The book concludes with chapters on massive neutrino physics that cover neutrino properties, neutrino oscillation in vacuum and matter, and solar and atmospheric neutrinos.

Helping readers understand the complicated laws of nature, Advanced Particle Physics Volume II: The Standard Model and Beyond explains the calculations, experimental procedures, and measuring methods of particle physics, particularly quantum chromodynamics (QCD). It also discusses extensions to the Standard Model and the physics of massive neutrinos. Divided into three parts, this volume begins with QCD. It explains the quantization scheme using functional integrals and investigates renormalization problems. The book also calculates cross sections of basic hard processes and covers nonperturbative methods, such as the lattice approach and QCD vacuum. The next part focuses on electroweak interactions, in which the author describes the Glashow-Weinberg-Salam theory and presents composite models and a left-right symmetric model as extensions to the Standard Model. The book concludes with chapters on massive neutrino physics that cover neutrino properties, neutrino oscillation in vacuum and matter, and solar and atmospheric neutrinos.

Helping readers understand the complicated laws of nature, Advanced Particle Physics Volume I: Particles, Fields, and Quantum Electrodynamics explains the calculations, experimental procedures, and measuring methods of particle physics. It also describes modern physics devices, including accelerators, elementary particle detectors, and neutrino telescopes. The book first introduces the mathematical basis of modern quantum field theory. It presents the most pertinent information on group theory, proves Noether's theorem, and determines the major motion integrals connected with both space and internal symmetry. The second part on fundamental interactions and their unifications discusses the main theoretical preconditions and experiments that allow for matter structure to be established at the quark-lepton level. In the third part, the author investigates the secondary quantized theories of free fields with spin 0, 1/2, and 1, with particular emphasis on the neutrino field. The final part focuses on quantum electrodynamics, the first successfully operating quantum field theory. Along with different renormalization schemes of quantum field theory, the author covers the calculation methods for polarized and unpolarized particles, with and without inclusion of radiative corrections. Each part in this volume contains problems to help readers master the calculation techniques and generalize the results obtained. To improve understanding of the computation procedures in quantum field theory, the majority of the calculations have been performed without dropping complex intermediate steps.

Providing a complete foundation to comprehend the physics of the microworld, Advanced Particle Physics, Two-Volume Set develops the models, theoretical framework, and mathematical tools to understand current experiments and make predictions for future experiments. The set brings together a vast array of topics in modern particle physics and distills the material in a rigorous yet accessible manner. All intermediate mathematical steps are derived and numerous application examples help readers gain a thorough, working knowledge of the subject. The first volume on particles, fields, and quantum electrodynamics covers: The mathematical foundation of quantum field theory The interactions and particles of the Standard Model How accelerators, detectors, and neutrino telescopes are used in particle physics experiments The technique of renormalization in quantum electrodynamics The second volume on the Standard Model and beyond discusses: The technique of renormalization in quantum chromodynamics (QCD) The status of current QCD experiments Physics beyond the Standard Model, including composite models and a left-right model How solar and atmospheric neutrinos are detected and analyzed The books in this two-volume set enable readers not only to perform complicated and skilled calculations, but also to propose and elaborate new theories. Each book contains extensive references that offer a comprehensive perspective on the literature and historical development of particle physics.