Resummation and Renormalization in Effective Theories of Particle Physics / by Antal Jakovác, András Patkós.

Format:

Book

Author/Creator:

Jakovác, Antal., Author.

Patkós, András., Author.

Series:

Lecture Notes in Physics, 0075-8450 ; 912

Language:

English

Subjects (All):

Particles (Nuclear physics).

Quantum field theory.

String models.

Mathematical physics.

Elementary Particles, Quantum Field Theory.

Quantum Field Theories, String Theory.

Mathematical Applications in the Physical Sciences.

Mathematical Physics.

Local Subjects:

Elementary Particles, Quantum Field Theory.

Quantum Field Theories, String Theory.

Mathematical Applications in the Physical Sciences.

Mathematical Physics.

Physical Description:

1 online resource (XI, 223 p. 29 illus., 13 illus. in color.)

Edition:

1st ed. 2016.

Place of Publication:

Cham : Springer International Publishing : Imprint: Springer, 2016.

Language Note:

English

Summary:

Effective models of strong and electroweak interactions are extensively applied in particle physics phenomenology, and in many instances can compete with large-scale numerical simulations of Standard Model physics. These contexts include but are not limited to providing indications for phase transitions and the nature of elementary excitations of strong and electroweak matter. A precondition for obtaining high-precision predictions is the application of some advanced functional techniques to the effective models, where the sensitivity of the results to the accurate choice of the input parameters is under control and the insensitivity to the actual choice of ultraviolet regulators is ensured. The credibility of such attempts ultimately requires a clean renormalization procedure and an error estimation due to a necessary truncation in the resummation procedure. In this concise primer we discuss systematically and in sufficient technical depth the features of a number of approximate methods, as applied to various effective models of chiral symmetry breaking in strong interactions and the BEH-mechanism of symmetry breaking in the electroweak theory. After introducing the basics of the functional integral formulation of quantum field theories and the derivation of different variants of the equations which determine the n-point functions, the text elaborates on the formulation of the optimized perturbation theory and the large-N expansion, as applied to the solution of these underlying equations in vacuum. The optimisation aspects of the 2PI approximation is discussed. Each of them is presented as a specific reorganisation of the weak coupling perturbation theory. The dimensional reduction of high temperature field theories is discussed from the same viewpoint. The renormalization program is described for each approach in detail and particular attention is paid to the appropriate interpretation of the notion of renormalization in the presence of the Landau singularity. Finally, results which emerge from the application of these techniques to the thermodynamics of strong and electroweak interactions are reviewed in detail.

Contents:

Effective Theories From Nuclear to Particle Physics

Finite Temperature Field Theories: Review

Divergences in the Perturbation Theory

Optimized Perturbation Theory

The Large-N Expansion

Dimensional Reduction and Infrared Improved Treatment of Finite Temperature Transitions

Thermodynamics of Strong Matter

Finite Temperature Restoration of the Brout-Englert-Higgs Effect

The Spectral Function

Computation of the Basic Diagrams

Integrals Relevant for Dimensional Reduction.

Notes:

Bibliographic Level Mode of Issuance: Monograph

Includes bibliographical references.

ISBN:

3-319-22620-7