The Anderson-Mott Transition as a Random-Field Problem

A. Aharony; A. Aharony; A.B. Harris; A.M. Finkel'stein; D. Belitz; D. Belitz; D.S. Fisher; D.S. Fisher; E. Abrahams; F. Wegner; F. Wegner; G. Grinstein; G. Parisi; J. Chayes; J. Villain; K.J. Wilson; P.A. Lee; P.W. Anderson; T. Nattermann; T. R. Kirkpatrick; T.R. Kirkpatrick; Y. Imry

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The Anderson-Mott Transition as a Random-Field Problem

Authors: A. Aharony
A. Aharony
A.B. Harris
A.M. Finkel'stein
D. Belitz
D. Belitz
D.S. Fisher
D.S. Fisher
E. Abrahams
F. Wegner
F. Wegner
G. Grinstein
G. Parisi
J. Chayes
J. Villain
K.J. Wilson
P.A. Lee
P.W. Anderson
T. Nattermann
T. R. Kirkpatrick
T.R. Kirkpatrick
Y. Imry
Publication date: 2 August 1994
Publisher: 'American Physical Society (APS)'
Doi

Abstract

The Anderson-Mott transition of disordered interacting electrons is shown to share many physical and technical features with classical random-field systems. A renormalization group study of an order parameter field theory for the Anderson-Mott transition shows that random-field terms appear at one-loop order. They lead to an upper critical dimension

d_{c}^{+}=6

for this model. For

d>6

the critical behavior is mean-field like. For

d<6

an

\epsilon

-expansion yields exponents that coincide with those for the random-field Ising model. Implications of these results are discussed.Comment: 8pp, REVTeX, db/94/

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