Dynamical Mean-Field Theory

A Fujimori; A Georges; A Georges; A Georges; A Hofmann; A Hubener; A Isacsson; A Lanzara; A Micheli; A Polkovnikov; A Rapp; A Sekiyama; A Toschi; AI Lichtenstein; AI Lichtenstein; AI Lichtenstein; AN Rubtsov; AV Joura; B Moritz; B Velický; C Itzykson; C Raas; D Jaksch; D Vollhardt; D Vollhardt; DB McWhan; DB McWhan; DE Logan; E Lieb; E Müller-Hartmann; E Müller-Hartmann; E Pavarini; F Gebhard; F Kajzar; F Yonezawa; FX Bronold; G Bulk; G Kotliar; G Kotliar; G Treglia; H He; H Park; H Schweitzer; H Schweitzer; I Bloch; IA Nekrasov; IA Nekrasov; IH Inoue; J Dziarmaga; J Hubbard; J Hubbard; J Hwang; J Joo; J Kanamori; J Kuneš; JE Hirsch; JH Boer de; JK Freericks; JK Freericks; JK Freericks; JK Freericks; JK Freericks; JM Luttinger; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Byczuk; K Haule; K Held; K Held; K Held; K Held; L Chen; L Perfetti; M Caffarel; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Eckstein; M Greiner; M Greiner; M Imada; M Jarrell; M Jarrell; M Karski; M Lewenstein; M Moeckel; M Moeckel; M Potthoff; M Potthoff; M Potthoff; M Potthoff; M Rigol; M Snoek; M Takizawa; M Ulmke; MC Gutzwiller; MCO Aguiar; MI Katsnelson; MJ Rozenberg; MJ Rozenberg; MJ Rozenberg; MPA Fisher; MT Tran; N Blümer; N Eurich; N Tsuji; N Tsuji; N Tsuji; N.F. Mott; NE Bickers; NF Mott; NF Mott; NF Mott; P Anders; P Hohenberg; P Lombardo; PA Lee; PGJ Dongen van; PW Anderson; Q Si; R Bulla; R Bulla; R Bulla; R Vlaming; RJ Anglin; RJ Baxter; RJ Elliot; RO Jones; RW Helmes; S Wall; SD Huber; SK Mo; T Maier; T Pruschke; T Pruschke; TM Rice; U Brandt; U Schneider; U Wolff; U Yu; V Anisimov; V Dobrosavljević; V Dobrosavljević; V Dobrosavljević; V Drchal; V Janiš; V Janiš; V Janiš; V Janiš; V Janiš; V Janiš; V Turkowski; V.I. Anisimov; VI Anisimov; VI Anisimov; W Kohn; W Metzner; W Metzner; WF Brinkman; WJ Hu; XY Zhang; ZX Shen

research

Dynamical Mean-Field Theory

Authors: A Fujimori
A Georges
A Georges
A Georges
A Hofmann
A Hubener
A Isacsson
A Lanzara
A Micheli
A Polkovnikov
A Rapp
A Sekiyama
A Toschi
AI Lichtenstein
AI Lichtenstein
AI Lichtenstein
AN Rubtsov
AV Joura
B Moritz
B Velický
C Itzykson
C Raas
D Jaksch
D Vollhardt
D Vollhardt
DB McWhan
DB McWhan
DE Logan
E Lieb
E Müller-Hartmann
E Müller-Hartmann
E Pavarini
F Gebhard
F Kajzar
F Yonezawa
FX Bronold
G Bulk
G Kotliar
G Kotliar
G Treglia
H He
H Park
H Schweitzer
H Schweitzer
I Bloch
IA Nekrasov
IA Nekrasov
IH Inoue
J Dziarmaga
J Hubbard
J Hubbard
J Hwang
J Joo
J Kanamori
J Kuneš
JE Hirsch
JH Boer de
JK Freericks
JK Freericks
JK Freericks
JK Freericks
JK Freericks
JM Luttinger
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Byczuk
K Haule
K Held
K Held
K Held
K Held
L Chen
L Perfetti
M Caffarel
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Eckstein
M Greiner
M Greiner
M Imada
M Jarrell
M Jarrell
M Karski
M Lewenstein
M Moeckel
M Moeckel
M Potthoff
M Potthoff
M Potthoff
M Potthoff
M Rigol
M Snoek
M Takizawa
M Ulmke
MC Gutzwiller
MCO Aguiar
MI Katsnelson
MJ Rozenberg
MJ Rozenberg
MJ Rozenberg
MPA Fisher
MT Tran
N Blümer
N Eurich
N Tsuji
N Tsuji
N Tsuji
N.F. Mott
NE Bickers
NF Mott
NF Mott
NF Mott
P Anders
P Hohenberg
P Lombardo
PA Lee
PGJ Dongen van
PW Anderson
Q Si
R Bulla
R Bulla
R Bulla
R Vlaming
RJ Anglin
RJ Baxter
RJ Elliot
RO Jones
RW Helmes
S Wall
SD Huber
SK Mo
T Maier
T Pruschke
T Pruschke
TM Rice
U Brandt
U Schneider
U Wolff
U Yu
V Anisimov
V Dobrosavljević
V Dobrosavljević
V Dobrosavljević
V Drchal
V Janiš
V Janiš
V Janiš
V Janiš
V Janiš
V Janiš
V Turkowski
V.I. Anisimov
VI Anisimov
VI Anisimov
W Kohn
W Metzner
W Metzner
WF Brinkman
WJ Hu
XY Zhang
ZX Shen
Publication date: 1 January 2011
Publisher: 'Springer Science and Business Media LLC'
Doi

Abstract

The dynamical mean-field theory (DMFT) is a widely applicable approximation scheme for the investigation of correlated quantum many-particle systems on a lattice, e.g., electrons in solids and cold atoms in optical lattices. In particular, the combination of the DMFT with conventional methods for the calculation of electronic band structures has led to a powerful numerical approach which allows one to explore the properties of correlated materials. In this introductory article we discuss the foundations of the DMFT, derive the underlying self-consistency equations, and present several applications which have provided important insights into the properties of correlated matter.Comment: Chapter in "Theoretical Methods for Strongly Correlated Systems", edited by A. Avella and F. Mancini, Springer (2011), 31 pages, 5 figure