Anderson localization transition with long-ranged hoppings : analysis of the strong multifractality regime in terms of weighted Levy sums

Abstract

For Anderson tight-binding models in dimension d with random on-site energies ε r and critical long-ranged hoppings decaying typically as Vtyp(r) V/rd, we show that the strong multifractality regime corresponding to small V can be studied via the standard perturbation theory for eigenvectors in quantum mechanics. The Inverse Participation Ratios Yq(L), which are the order parameters of Anderson transitions, can be written in terms of weighted L\'evy sums of broadly distributed variables (as a consequence of the presence of on-site random energies in the denominators of the perturbation theory). We compute at leading order the typical and disorder-averaged multifractal spectra τtyp(q) and τav(q) as a function of q. For q<1/2, we obtain the non-vanishing limiting spectrum τtyp(q)=τav(q)=d(2q-1) as V 0+. For q>1/2, this method yields the same disorder-averaged spectrum τav(q) of order O(V) as obtained previously via the Levitov renormalization method by Mirlin and Evers [Phys. Rev. B 62, 7920 (2000)]. In addition, it allows to compute explicitly the typical spectrum, also of order O(V), but with a different q-dependence τtyp(q) τav(q) for all q>qc=1/2. As a consequence, we find that the corresponding singularity spectra ftyp(α) and fav(α) differ even in the positive region f>0, and vanish at different values α+typ > α+av, in contrast to the standard picture. We also obtain that the saddle value αtyp(q) of the Legendre transform reaches the termination point α+typ where ftyp(α+typ)=0 only in the limit q +∞.