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Relativistic quantum field theory.

"Version: 20191101"--Title page verso."A Morgan & Claypool publication as part of IOP Concise Physics"--Title page verso.Includes bibliographical references.1. QCD phenomenology -- 1.1. Electron-muon scattering -- 1.2. Form factors -- 1.3. Elastic electron-proton scattering and the proton form factors -- 1.4. Inelastic electron-proton scattering -- 1.5. The parton model and Bjorken scaling -- 1.6. Valence partons and sea partons -- 1.7. Beyond the naive parton model -- 1.8. DGLAP evolution -- 1.9. Hadron production in e+e- collisions -- 1.10. Fragmentation functions -- 1.11. Solution of the DGLAP equations using Mellin moments -- 1.12. Drell-Yan scattering2. Weak interactions -- 2.1. Early models of the weak interaction -- 2.2. Muon decay -- 2.3. Charged pion decay -- 2.4. Electron-neutrino and electron-antineutrino scattering -- 2.5. Neutrino-quark scattering -- 2.6. Weak neutral currents -- 2.7. The Cabibbo angle and the CKM matrix3. Electroweak unification and the Higgs mechanism -- 3.1. Electroweak Feynman rules -- 3.2. Massive gauge fields with local gauge symmetry -- 3.3. Gauge boson masses in SU(2)L x U(1)Y -- 3.4. The discovery of the Higgs boson4. Basics of finite temperature quantum field theory -- 4.1. Partition function for a quantum harmonic oscillator -- 4.2. The partition function for a free scalar field theory -- 4.3. Free scalar thermodynamics -- 4.4. The need for resummation -- 4.5. Perturbative expansion of thermodynamics for a scalar field theory -- 4.6. Screened perturbation theory5. Hard-thermal-loops for QED and QCD -- 5.1. Photon polarization tensor -- 5.2. Fermionic self-energy -- 5.3. Collective modes -- 5.4. Hard-thermal-loop effective action -- 5.5. Hard-thermal-loop resummed thermodynamics.Volume 3 of this three-part series presents more advanced topics and applications of relativistic quantum field theory. The application of quantum chromodynamics to high-energy particle scattering is discussed with concrete examples for how to compute QCD scattering cross sections. Experimental evidence for the existence of quarks and gluons is then presented both within the context of the naive quark model and beyond. Dr. Strickland then reviews our current understanding of the weak interaction, the unified electroweak theory, and the Brout-Higgs-Englert mechanism for the generation of gauge boson masses. The last two chapters contain a self-contained introduction to finite temperature quantum field theory with concrete examples focusing on the high-temperature thermodynamics of scalar field theories, QED, and QCD.Also available in print.Mode of access: World Wide Web.System requirements: Adobe Acrobat Reader, EPUB reader, or Kindle reader.Dr. Strickland is a professor of physics at Kent State University. His primary interest is the physics of the quark-gluon plasma (QGP) and high-temperature quantum field theory (QFT). The QGP is predicted by quantum chromodynamics (QCD) to have existed until approximately 10-5 seconds after the big bang. Dr. Strickland has published research papers on various topics related to the QGP, quantum field theory, relativistic hydrodynamics, and many other topics. In addition, he has co-written a classic text on the physics of neural networks.Title from PDF title page (viewed on December 9, 2019).

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Series Title
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Call Number
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Publisher
: .,
Collation
1 online resource (various pagings) :illustrations (some color).
Language
English
ISBN/ISSN
9781643277622
Classification
530.12
Content Type
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Media Type
-
Carrier Type
-
Edition
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Subject(s)
SCIENCE / Physics / Quantum Theory.
Quantum field theory.
Relativistic quantum theory.
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