Scattering amplitudes in gauge theories / Johannes M. Henn, Jan C. Plefka.

By: Henn, Johannes M [author.]
Contributor(s): Plefka, Jan C [author.]
Material type: TextTextSeries: Lecture notes in physics: v. 883.Publisher: Heidelberg : Springer, 2014Description: 1 online resource (xv, 195 pages) : illustrationsContent type: text Media type: computer Carrier type: online resourceISBN: 9783642540226; 3642540228; 364254021X; 9783642540219Subject(s): Gauge fields (Physics) | Scattering (Physics) | Quantum field theory | Physique | Astronomie | Gauge fields (Physics) | Quantum field theory | Scattering (Physics)Genre/Form: Electronic books. Additional physical formats: Print version:: Scattering amplitudes in gauge theoriesDDC classification: 530.14/35 LOC classification: QC793.3.G38Online resources: Click here to access online
Contents:
Introduction and Basics -- Tree-Level Techniques -- Loop-Level Structure.-?Advanced Topics -- Renormalization Properties of Wilson Loops -- Conventions and Useful Formulae -- Solutions to the Exercises.
Summary: At the fundamental level, the interactions of elementary particles are described by quantum gauge field theory. The quantitative implications of these interactions are captured by scattering amplitudes, traditionally computed using Feynman diagrams. In the past decade tremendous progress has been made in our understanding of and computational abilities with regard to scattering amplitudes in gauge theories, going beyond the traditional textbook approach. These advances build upon on-shell methods that focus on the analytic structure of the amplitudes, as well as on their recently discovered hidden symmetries. In fact, when expressed in suitable variables the amplitudes are much simpler than anticipated and hidden patterns emerge. These modern methods are of increasing importance in phenomenological applications arising from the need for high-precision predictions for the experiments carried out at the Large Hadron Collider, as well as in foundational mathematical physics studies on the S-matrix in quantum field theory. Bridging the gap between introductory courses on quantum field theory and state-of-the-art research, these concise yet self-contained and course-tested lecture notes are well-suited for a one-semester graduate level course or as a self-study guide for anyone interested in fundamental aspects of quantum field theory and its applications. The numerous exercises and solutions included will help readers to embrace and apply the material presented in the main text.
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Introduction and Basics -- Tree-Level Techniques -- Loop-Level Structure.-?Advanced Topics -- Renormalization Properties of Wilson Loops -- Conventions and Useful Formulae -- Solutions to the Exercises.

Includes bibliographical references.

At the fundamental level, the interactions of elementary particles are described by quantum gauge field theory. The quantitative implications of these interactions are captured by scattering amplitudes, traditionally computed using Feynman diagrams. In the past decade tremendous progress has been made in our understanding of and computational abilities with regard to scattering amplitudes in gauge theories, going beyond the traditional textbook approach. These advances build upon on-shell methods that focus on the analytic structure of the amplitudes, as well as on their recently discovered hidden symmetries. In fact, when expressed in suitable variables the amplitudes are much simpler than anticipated and hidden patterns emerge. These modern methods are of increasing importance in phenomenological applications arising from the need for high-precision predictions for the experiments carried out at the Large Hadron Collider, as well as in foundational mathematical physics studies on the S-matrix in quantum field theory. Bridging the gap between introductory courses on quantum field theory and state-of-the-art research, these concise yet self-contained and course-tested lecture notes are well-suited for a one-semester graduate level course or as a self-study guide for anyone interested in fundamental aspects of quantum field theory and its applications. The numerous exercises and solutions included will help readers to embrace and apply the material presented in the main text.

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