Scaling of the conductance distribution near the Anderson transition

A. Cohen; A. Cohen; A. MacKinnon; A. MacKinnon; B. L. Altshuler; B. L. Altshuler; B. Shapiro; B. Shapiro; B. Shapiro; D. Braun; D. S. Fisher; E. Abrahams; E. N. Economou; F. Milde; J. B. Pendry; K. Slevin; K. Slevin; K. Slevin; K. Slevin; Keith Slevin; L. I. Deych; P. A. Lee; P. Markoš; P. Markoš; P. W. Anderson; Peter Markoš; S. L. A. de Queiroz; Tomi Ohtsuki

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Scaling of the conductance distribution near the Anderson transition

Authors: A. Cohen
A. Cohen
A. MacKinnon
A. MacKinnon
B. L. Altshuler
B. L. Altshuler
B. Shapiro
B. Shapiro
B. Shapiro
D. Braun
D. S. Fisher
E. Abrahams
E. N. Economou
F. Milde
J. B. Pendry
K. Slevin
K. Slevin
K. Slevin
K. Slevin
Keith Slevin
L. I. Deych
P. A. Lee
P. Markoš
P. Markoš
P. W. Anderson
Peter Markoš
S. L. A. de Queiroz
Tomi Ohtsuki
Publication date: 14 November 2002
Publisher: 'American Physical Society (APS)'
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Abstract

The single parameter scaling hypothesis is the foundation of our understanding of the Anderson transition. However, the conductance of a disordered system is a fluctuating quantity which does not obey a one parameter scaling law. It is essential to investigate the scaling of the full conductance distribution to establish the scaling hypothesis. We present a clear cut numerical demonstration that the conductance distribution indeed obeys one parameter scaling near the Anderson transition

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