Physics – Condensed Matter – Disordered Systems and Neural Networks
Scientific paper
2001-11-21
J.Exp.Theor.Phys. 81 (1995) 925; Zh.Eksp.Teor.Fiz. 108 (1995) 1686
Physics
Condensed Matter
Disordered Systems and Neural Networks
43 pages, 6 figures included
Scientific paper
We prove the Vollhardt and Wolfle hypothesis that the irreducible vertex U_{kk'}(q) appearing in the Bethe--Salpeter equation contains a diffusion pole (with the observable diffusion coefficient D(\omega,q)) in the limit k+k'\to 0. The presence of a diffusion pole in U_{kk'}(q) makes it possible to represent the quantum "collision operator" L as a sum of a singular operator L_{sing}, which has an infinite number of zero modes, and a regular operator L_{reg} of a general form. Investigation of the response of the system to a change in L_{reg} leads to a self-consistency equation, which replaces the rough Vollhardt-Wolfle equation. Its solution shows that D(0,q) vanishes at the transition point simultaneously for all q. The spatial dispersion of D(\omega,q) at \omega \to 0 is found to be \sim 1 in relative units. It is determined by the atomic scale, and it has no manifestations on the scale q \sim \xi^{-1} associated with the correlation length \xi. The values obtained for the critical exponent s of the conductivity and the critical exponent \nu of the localization length in a d-dimensional space, s=1 (d>2) and \nu=1/(d-2) (2
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