Classical and Quantum Dynamics : From Classical Paths to Path Integrals / by Walter Dittrich, Martin Reuter.

Format:

Book

Author/Creator:

Dittrich, Walter., Author.

Reuter, Martin., Author.

Language:

English

Subjects (All):

Quantum theory.

Field theory (Physics).

Mathematical physics.

Nuclear physics.

Quantum Physics.

Classical and Continuum Physics.

Mathematical Applications in the Physical Sciences.

Particle and Nuclear Physics.

Local Subjects:

Quantum Physics.

Classical and Continuum Physics.

Mathematical Applications in the Physical Sciences.

Particle and Nuclear Physics.

Physical Description:

1 online resource (XVI, 489 p. 18 illus.)

Edition:

5th ed. 2017.

Place of Publication:

Cham : Springer International Publishing : Imprint: Springer, 2017.

Summary:

Graduate students who wish to become familiar with advanced computational strategies in classical and quantum dynamics will find in this book both the fundamentals of a standard course and a detailed treatment of the time-dependent oscillator, Chern-Simons mechanics, the Maslov anomaly and the Berry phase, to name just a few topics. Well-chosen and detailed examples illustrate perturbation theory, canonical transformations and the action principle, and demonstrate the usage of path integrals. The fifth edition has been revised and enlarged to include chapters on quantum electrodynamics, in particular, Schwinger’s proper time method and the treatment of classical and quantum mechanics with Lie brackets and pseudocanonical transformations. It is shown that operator quantum electrodynamics can be equivalently described with c-numbers, as demonstrated by calculating the propagation function for an electron in a prescribed classical electromagnetic field.

Contents:

Introduction

The Action Principles in Mechanics

The Action Principle in Classical Electrodynamics

Application of the Action Principles

Jacobi Fields, Conjugate Points.-Canonical Transformations

The Hamilton–Jacobi Equation

Action-Angle Variables

The Adiabatic Invariance of the Action Variables

Time-Independent Canonical Perturbation Theory

Canonical Perturbation Theory with Several Degrees of Freedom

Canonical Adiabatic Theory

Removal of Resonances

Superconvergent Perturbation Theory, KAM Theorem

Poincaré Surface of Sections, Mappings

The KAM Theorem

Fundamental Principles of Quantum Mechanics

Functional Derivative Approach

Examples for Calculating Path Integrals

Direct Evaluation of Path Integrals

Linear Oscillator with Time-Dependent Frequency

Propagators for Particles in an External Magnetic Field

Simple Applications of Propagator Functions

The WKB Approximation

Computing the trace

Partition Function for the Harmonic Oscillator

Introduction to Homotopy Theory

Classical Chern–Simons Mechanics

Semiclassical Quantization

The “Maslov Anomaly” for the Harmonic Oscillator.-Maslov Anomaly and the Morse Index Theorem

Berry’s Phase

Classical Geometric Phases: Foucault and Euler

Berry Phase and Parametric Harmonic Oscillator

Topological Phases in Planar Electrodynamics

Path Integral Formulation of Quantum Electrodynamics

Particle in Harmonic E-Field E(t) = Esinw0t; Schwinger-Fock Proper-Time Method

The Usefulness of Lie Brackets: From Classical and Quantum Mechanics to Quantum Electrodynamics

Appendix

Solutions

Index.

Notes:

Includes bibliographical references & index.

Description based on publisher supplied metadata and other sources.

ISBN:

3-319-58298-4

OCLC:

987794656