Anderson localization of phonons in dimension d=1,2,3 : finite-size properties of the Inverse Participation Ratios of eigenstates

Abstract

We study by exact diagonalization the localization properties of phonons in mass-disordered harmonic crystals of dimension d=1,2,3. We focus on the behavior of the typical Inverse Participation Ratio Y2(ω,L) as a function of the frequency ω and of the linear length L of the disordered samples. In dimensions d=1 and d=2, we find that the low-frequency part ω 0 of the spectrum satisfies the following finite-size scaling L Y2(ω,L)=Fd=1(L1/2 ω) in dimension d=1 and L2 Y2(ω,L)=Fd=2(( L)1/2 ω) in dimension d=2, with the following conclusions (i) an eigenstate of any fixed frequency ω becomes localized in the limit L +∞ (ii) a given disordered sample of size Ld contains a number Ndeloc(L) of delocalized states growing as Ndeloc(L) L1/2 in d=1 and as Ndeloc(L) L2/( L) in d=2. In dimension d=3, we find a localization-delocalization transition at some finite critical frequency ωc(W)>0 (that depends on the disorder strength W). Our data are compatible with the finite-size scaling LD(2) Y2(ω,L)=Fd=3(L1/ (ω-ωc)) with the values D(2) 1.3 and 1.57 corresponding to the universality class of the localization transition for the Anderson tight-binding electronic model in dimension d=3.