A non-degeneracy theorem for interacting fermions in one dimension
Abstract
In this paper, we show that the ground-state of many-body Schr\"odinger operators for electrons in one dimension is non-degenerate. More precisely, we consider Schr\"odinger operators of the form HN(v,w) = - + Σi≠ jN w(xi,xj) + Σj=1N v(xi) acting on N L2([0,1]), where the external and interaction potentials v and w belong to a large class of distributions. In this setting, we show that the ground-state of the system with Fermi statistics and local boundary conditions is non-degenerate and does not vanish on a set of positive measure. In the case of periodic and anti-periodic (or more general non-local) boundary conditions, we show that the same result holds whenever the number of particles is odd and even, respectively. This non-degeneracy result seems to be new even for regular potentials v and w. As an immediate application of this result, we prove eigenvalue inequalities and the strong unique continuation property for eigenfunctions of the single-particle one-dimensional operators h(v) = - +v. In addition, we prove strict inequalities between the lowest eigenvalues of different self-adjoint realizations of HN(v,w).
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