The asymptotics of an eigenfunction-correlation determinant for Dirac-δ perturbations (Anderson's Orthogonality Catastrophe for Dirac-δ)

Abstract

We give a proof of the exact asymptotic behaviour in Anderson's Orthogonality Catastrophe for Dirac-δ perturbations. We prove the exact asymptotics of the scalar product of the ground states of two non-interacting Fermi gases confined to a 3-dimensional ball BL of radius L in the thermodynamic limit, where the underlying one-particle operators differ by a Dirac-δ perturbation. More precisely, we show the algebraic decay of the correlation determinant |(jL, kL)j,k=1,...,N|2= L-ζ(E)+ o(1), as N,L∞ and N/|BL|~ >0, where jL and kL denote the lowest-energy eigenfunctions of the finite-volume one-particle Schr\"odinger operators. The decay exponent is given in terms of the s-wave scattering phase shift ζ(E):=δ2( E)/π2. For an attractive Dirac-δ perturbation we conclude that the decay exponent 1 π2 |T(E)/2|2HS found in [GKMO14] does not provide a sharp upper bound on the decay of the correlation determinant.