Statistics of the two-point transmission at Anderson localization transitions

Abstract

At Anderson critical points, the statistics of the two-point transmission TL for disordered samples of linear size L is expected to be multifractal with the following properties [Janssen et al PRB 59, 15836 (1999)] : (i) the probability to have TL 1/L behaves as L(), where the multifractal spectrum () terminates at =0 as a consequence of the physical bound TL ≤ 1; (ii) the exponents X(q) that govern the moments TLq 1/LX(q) become frozen above some threshold: X(q ≥ qsat) = - (=0), i.e. all moments of order q ≥ qsat are governed by the measure of the rare samples having a finite transmission (=0). In the present paper, we test numerically these predictions for the ensemble of L × L power-law random banded matrices, where the random hopping Hi,j decays as a power-law (b/| i-j |)a. This model is known to present an Anderson transition at a=1 between localized (a>1) and extended (a<1) states, with critical properties that depend continuously on the parameter b. Our numerical results for the multifractal spectra b() for various b are in agreement with the relation ( ≥ 0) = 2 [ f(α= d+ 2) -d ] in terms of the singularity spectrum f(α) of individual critical eigenfunctions, in particular the typical exponents are related via the relation typ(b)= 2 (αtyp(b)-d). We also discuss the statistics of the two-point transmission in the delocalized phase and in the localized phase.