Surface metal-insulator transition in the Hubbard model

A. Georges; A. Georges; A. Georges; C. J. Powell; D. Kalkstein; D. L. Mills; D. Vollhardt; F. Gebhard; G. Moeller; I. Tamm; J. Hubbard; J. M. Luttinger; L. Laloux; M. Caffarel; M. J. Rozenberg; M. Jarrell; M. Potthoff; M. Potthoff; M. Potthoff; M. Potthoff; M. Rozenberg; N. F. Mott; Qimiao Si; R. Bulla; R. Haydock; S. Kehrein; T. Herrmann; T. Obermeier; W. F. Brinkman; W. Metzner; W. Nolting; W. Shockley

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Surface metal-insulator transition in the Hubbard model

Authors: A. Georges
A. Georges
A. Georges
C. J. Powell
D. Kalkstein
D. L. Mills
D. Vollhardt
F. Gebhard
G. Moeller
I. Tamm
J. Hubbard
J. M. Luttinger
L. Laloux
M. Caffarel
M. J. Rozenberg
M. Jarrell
M. Potthoff
M. Potthoff
M. Potthoff
M. Potthoff
M. Rozenberg
N. F. Mott
Qimiao Si
R. Bulla
R. Haydock
S. Kehrein
T. Herrmann
T. Obermeier
W. F. Brinkman
W. Metzner
W. Nolting
W. Shockley
Publication date: 1 January 1998
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The correlation-driven metal-insulator (Mott) transition at a solid surface is studied within the Hubbard model for a semi-infinite lattice by means of the dynamical mean-field theory. The transition takes place at a unique critical strength of the interaction. Depending on the surface geometry, the interaction strength and the wave vector, we find one-electron excitations in the coherent part of the surface-projected metallic spectrum which are confined to two dimensions.Comment: LaTeX, 9 pages, 5 eps figures included, Phys. Rev. B (in press

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