Lifshitz tail for continuous Anderson models driven by L\'evy operators

Abstract

We investigate the behavior near zero of the integrated density of states for random Schr\"odinger operators (-) + Vω in L2( Rd), d ≥ 1, where is a complete Bernstein function such that for some α ∈ (0,2], one has (λ) λα/2, λ 0, and Vω(x) = Σ i∈ Zd qi(ω) W(x-i) is a random nonnegative alloy-type potential with compactly supported single site potential W. We prove that there are constants C, C,D, D>0 such that -C ≤λ 0 λd/α| Fq(D λ)| (λ) and λ 0 λd/α| Fq( D λ)| (λ) ≤ - C, where Fq is the common cumulative distribution function of the lattice random variables q i. In particular, we identify how the behavior of at zero depends on the lattice configuration. For typical examples of Fq the constants D and D can be eliminated from the statement above. We combine probabilistic and analytic methods which allow to treat, in a unified manner, both local and non-local kinetic terms such as the Laplace operator, its fractional powers and the quasi-relativistic Hamiltonians.