Metal-insulator transition in correlated systems: A new numerical approach

We study the Mott transition in the Hubbard model within the dynamical mean field theory approach where the density matrix renormalization group method is used to solve its self-consistent equations. The DMRG technique solves the associated impurity problem. We obtain accurate estimates of the criti...

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Detalles Bibliográficos
Autor principal:	Rozenberg, Marcelo Javier
Publicado:	2007
Materias:	Density matrix renormalization group Dynamical mean field theory Mott transition Density matrix renormalization groups Mott transitions Self-consistent equations Degrees of freedom (mechanics) Matrix algebra Mean field theory Optical conductivity Semiconductor doping Spectrum analysis Metal insulator boundaries
Acceso en línea:	https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09214526_v398_n2_p407_Garcia http://hdl.handle.net/20.500.12110/paper_09214526_v398_n2_p407_Garcia
Aporte de:	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA) de Universidad de Buenos Aires

id	paper:paper_09214526_v398_n2_p407_Garcia
record_format	dspace
spelling	paper:paper_09214526_v398_n2_p407_Garcia2025-07-30T18:26:46Z Metal-insulator transition in correlated systems: A new numerical approach Rozenberg, Marcelo Javier Density matrix renormalization group Dynamical mean field theory Mott transition Density matrix renormalization groups Dynamical mean field theory Mott transitions Self-consistent equations Degrees of freedom (mechanics) Matrix algebra Mean field theory Optical conductivity Semiconductor doping Spectrum analysis Metal insulator boundaries We study the Mott transition in the Hubbard model within the dynamical mean field theory approach where the density matrix renormalization group method is used to solve its self-consistent equations. The DMRG technique solves the associated impurity problem. We obtain accurate estimates of the critical values of the metal-insulator transitions. For the Hubbard model away from the particle-hole symmetric case we focus our study on the region of strong interactions and finite doping where two solutions coexist. In this region we demonstrate the capabilities of this method by obtaining the frequency-dependent optical conductivity spectra. With this algorithm, more complex models having a larger number of degrees of freedom can be considered and finite-size effects can be minimized. © 2007 Elsevier B.V. All rights reserved. Fil:Rozenberg, M.J. Universidad de Buenos Aires. Facultad de Ciencias Exactas y Naturales; Argentina. 2007 https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09214526_v398_n2_p407_Garcia http://hdl.handle.net/20.500.12110/paper_09214526_v398_n2_p407_Garcia
institution	Universidad de Buenos Aires
institution_str	I-28
repository_str	R-134
collection	Biblioteca Digital - Facultad de Ciencias Exactas y Naturales (UBA)
topic	Density matrix renormalization group Dynamical mean field theory Mott transition Density matrix renormalization groups Dynamical mean field theory Mott transitions Self-consistent equations Degrees of freedom (mechanics) Matrix algebra Mean field theory Optical conductivity Semiconductor doping Spectrum analysis Metal insulator boundaries
spellingShingle	Density matrix renormalization group Dynamical mean field theory Mott transition Density matrix renormalization groups Dynamical mean field theory Mott transitions Self-consistent equations Degrees of freedom (mechanics) Matrix algebra Mean field theory Optical conductivity Semiconductor doping Spectrum analysis Metal insulator boundaries Rozenberg, Marcelo Javier Metal-insulator transition in correlated systems: A new numerical approach
topic_facet	Density matrix renormalization group Dynamical mean field theory Mott transition Density matrix renormalization groups Dynamical mean field theory Mott transitions Self-consistent equations Degrees of freedom (mechanics) Matrix algebra Mean field theory Optical conductivity Semiconductor doping Spectrum analysis Metal insulator boundaries
description	We study the Mott transition in the Hubbard model within the dynamical mean field theory approach where the density matrix renormalization group method is used to solve its self-consistent equations. The DMRG technique solves the associated impurity problem. We obtain accurate estimates of the critical values of the metal-insulator transitions. For the Hubbard model away from the particle-hole symmetric case we focus our study on the region of strong interactions and finite doping where two solutions coexist. In this region we demonstrate the capabilities of this method by obtaining the frequency-dependent optical conductivity spectra. With this algorithm, more complex models having a larger number of degrees of freedom can be considered and finite-size effects can be minimized. © 2007 Elsevier B.V. All rights reserved.
author	Rozenberg, Marcelo Javier
author_facet	Rozenberg, Marcelo Javier
author_sort	Rozenberg, Marcelo Javier
title	Metal-insulator transition in correlated systems: A new numerical approach
title_short	Metal-insulator transition in correlated systems: A new numerical approach
title_full	Metal-insulator transition in correlated systems: A new numerical approach
title_fullStr	Metal-insulator transition in correlated systems: A new numerical approach
title_full_unstemmed	Metal-insulator transition in correlated systems: A new numerical approach
title_sort	metal-insulator transition in correlated systems: a new numerical approach
publishDate	2007
url	https://bibliotecadigital.exactas.uba.ar/collection/paper/document/paper_09214526_v398_n2_p407_Garcia http://hdl.handle.net/20.500.12110/paper_09214526_v398_n2_p407_Garcia
work_keys_str_mv	AT rozenbergmarcelojavier metalinsulatortransitionincorrelatedsystemsanewnumericalapproach
_version_	1840323922529091584

Metal-insulator transition in correlated systems: A new numerical approach

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