Ground state energy of noninteracting fermions with a random energy spectrum

Abstract

We derive analytically the full distribution of the ground-state energy of K non-interacting fermions in a disordered environment, modelled by a Hamiltonian whose spectrum consists of N i.i.d.~random energy levels with distribution p() (with ≥ 0), in the same spirit as the `Random Energy Model'. We show that for each fixed K, the distribution PK,N(E0) of the ground-state energy E0 has a universal scaling form in the limit of large N. We compute this universal scaling function and show that it depends only on K and the exponent α characterizing the small behaviour of p() α. We compared the analytical predictions with results from numerical simulations. For this purpose we employed a sophisticated importance-sampling algorithm that allowed us to obtain the distributions over a large range of the support down to probabilities as small as 10-160. We found asymptotically a very good agreement between analytical predictions and numerical results.