The continuous Anderson hamiltonian in dimension two

Abstract

We define the Anderson hamiltonian on the two dimensional torus R2/ Z2. This operator is formally defined as H:= - + where is the Laplacian operator and where belongs to a general class of singular potential which includes the Gaussian white noise distribution. We use the notion of paracontrolled distribution as introduced by Gubinelli, Imkeller and Perkowski in [14]. We are able to define the Schr\"odinger operator H as an unbounded self-adjoint operator on L2( T2) and we prove that its real spectrum is discrete with no accumulation points for a general class of singular potential . We also establish that the spectrum is a continuous function of a sort of enhancement () of the potential . As an application, we prove that a correctly renormalized smooth approximations H:= - + +c (where is a smooth mollification of the Gaussian white noise and c an explicit diverging renormalization constant) converge in the sense of the resolvent towards the singular operator H. In the case of a Gaussian white noise , we obtain exponential tail bounds for the minimal eigenvalue (sometimes called ground state) of the operator H as well as its order of magnitude L when the operator is considered on a large box TL:= R2/(L Z)2 with L ∞.