On norm resolvent convergence of Schrödinger operators with \(\delta'\)-like potentials

We address the problem on the right definition of the Schroedinger operator with potential \(\delta'\), where \(\delta\) is the Dirac delta-function. Namely, we prove the uniform resolvent convergence of a family of Schroedinger operators with regularized short-range potentials \(\epsilon^{-2}V(x/\epsilon)\) tending to \(\delta'\) in the distributional sense as \(\epsilon\to 0\). In 1986, P. Seba claimed that the limit coincides with the direct sum of free Schroedinger operators on the semi-axes with the Dirichlet boundary condition at the origin, which implies that in dimension one there is no non-trivial Hamiltonians with potential \(\delta'\). Our results demonstrate that, although the above statement is true for many V, for the so-called resonant V the limit operator is defined by the non-trivial interface condition at the origin determined by some spectral characteristics of V. In this resonant case, we show that there is a partial transmission of the wave package for the limiting Hamiltonian.