Statistics of renormalized on-site energies and renormalized hoppings for Anderson localization models in dimensions d=2 and d=3

Abstract

For Anderson localization models, there exists an exact real-space renormalization procedure at fixed energy which preserves the Green functions of the remaining sites [H. Aoki, J. Phys. C13, 3369 (1980)]. Using this procedure for the Anderson tight-binding model in dimensions d=2,3, we study numerically the statistical properties of the renormalized on-site energies ε and of the renormalized hoppings V as a function of the linear size L. We find that the renormalized on-site energies ε remain finite in the localized phase in d=2,3 and at criticality (d=3), with a finite density at ε=0 and a power-law decay 1/ε2 at large | ε |. For the renormalized hoppings in the localized phase, we find: ln VL -Lloc+Lωu, where loc is the localization length and u a random variable of order one. The exponent ω is the droplet exponent characterizing the strong disorder phase of the directed polymer in a random medium of dimension 1+(d-1), with ω(d=2)=1/3 and ω(d=3) 0.24. At criticality (d=3), the statistics of renormalized hoppings V is multifractal, in direct correspondence with the multifractality of individual eigenstates and of two-point transmissions. In particular, we measure typ 1 for the exponent governing the typical decay ln VL -typ lnL, in agreement with previous numerical measures of αtyp =d+typ 4 for the singularity spectrum f(α) of individual eigenfunctions. We also present numerical results concerning critical surface properties.