Inhomogeneously doped two-leg ladder systems

Andreas Läuchli; C. Lanczos; C.A. Hayward; C.H. Ahn; C.H. Ahn; E. Dagotto; E. Dagotto; E. Dagotto; F.D.M. Haldane; G. Kotliar; H. Lin; H. Lin; I. Affleck; K. Le Hur; L. Balents; M. Azuma; M. Sigrist; M. Troyer; M. Uehara; M.U. Ubbens; Manfred Sigrist; Martin Indergand; P.W. Anderson; R. Coldea; S. Gariglio; Stefan Wessel; T. Timusk; T.M. Rice; T.M. Rice; U. Ledermann; Urs Ledermann; Z. Hiroi

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Inhomogeneously doped two-leg ladder systems

Authors: Andreas Läuchli
C. Lanczos
C.A. Hayward
C.H. Ahn
C.H. Ahn
E. Dagotto
E. Dagotto
E. Dagotto
F.D.M. Haldane
G. Kotliar
H. Lin
H. Lin
I. Affleck
K. Le Hur
L. Balents
M. Azuma
M. Sigrist
M. Troyer
M. Uehara
M.U. Ubbens
Manfred Sigrist
Martin Indergand
P.W. Anderson
R. Coldea
S. Gariglio
Stefan Wessel
T. Timusk
T.M. Rice
T.M. Rice
U. Ledermann
Urs Ledermann
Z. Hiroi
Publication date: 11 April 2003
Publisher: 'American Physical Society (APS)'
Doi

Abstract

A chemical potential difference between the legs of a two-leg ladder is found to be harmful for Cooper pairing. The instability of superconductivity in such systems is analyzed by compairing results of various analytical and numerical methods. Within a strong coupling approach for the t-J model, supplemented by exact numerical diagonalization, hole binding is found unstable beyond a finite, critical chemical potential difference. The spinon-holon mean field theory for the t-J model shows a clear reduction of the the BCS gaps upon increasing the chemical potential difference leading to a breakdown of superconductivity. Based on a renormalization group approach and Abelian bosonization, the doping dependent phase diagram for the weakly interacting Hubbard model with different chemical potentials was determined.Comment: Revtex4, 11 pages, 7 figure

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