Nonequilibrium many-body theory of quantum systems : a modern introduction / Gianluca Stefanucci and Robert van Leeuwen.Material type: TextLanguage: English Copyright date: United Kingdom : Cambridge , 2013Edition: First EditionDescription: xvii, 600 pages : illustrations ; 26 cmISBN: 9780521766173 (hardback)Subject(s): Green's functions | Funciones de Green | Many-body problem | Problema de los cuerpos múltiples | Quantum theory -- Mathematics | Teoría cuántica -- MatemáticasDDC classification: 530.15353 LOC classification: QC174.17.G68 | S74 2013
|Item type||Current library||Call number||Copy number||Status||Date due||Barcode||Item holds|
|Libro académico||Biblioteca del Campus||530.15353 S816n 2013 (Browse shelf (Opens below))||Ej. 1||Available||004366|
Includes alphabetical index.
Includes bibliographical references.
Machine generated contents note: Second quantization -- Getting familiar with second quantization: model Hamiltonians -- Time-dependent problems and equations of motion -- The contour idea -- Many-particle Green's functions -- One-particle Green's function -- Mean field approximations -- Conserving approximations: two-particle Green's function -- Conserving approximations: self-energy -- MBPT for the Green's function -- MBPT and variational principles for the grand potential -- MBPT for the two-particle Green's function -- Applications of MBPT to equilibrium problems -- Linear response theory: preliminaries -- Linear response theory: many-body formulation -- Applications of MBPT to nonequilibrium problems.
"The Green's function method is one of the most powerful and versatile formalisms in physics, and its nonequilibrium version has proved invaluable in many research fields. This book provides a unique, self-contained introduction to nonequilibrium many-body theory. Starting with basic quantum mechanics, the authors introduce the equilibrium and nonequilibrium Green's function formalisms within a unified framework called the contour formalism. The physical content of the contour Green's functions and the diagrammatic expansions are explained with a focus on the time-dependent aspect. Every result is derived step-by-step, critically discussed and then applied to different physical systems, ranging from molecules and nanostructures to metals and insulators. With an abundance of illustrative examples, this accessible book is ideal for graduate students and researchers who are interested in excited state properties of matter and nonequilibrium physics"--