Controlling a resonant transmission across the δ'-potential: the inverse problem

Abstract

Recently, the non-zero transmission of a quantum particle through the one-dimensional singular potential given in the form of the derivative of Dirac's delta function, λ δ'(x) , with λ ∈ , being a potential strength constant, has been discussed by several authors. The transmission occurs at certain discrete values of λ forming a resonance set λnn=1∞. For λ λnn=1∞ this potential has been shown to be a perfectly reflecting wall. However, this resonant transmission takes place only in the case when the regularization of the distribution δ'(x) is constructed in a specific way. Otherwise, the δ'-potential is fully non-transparent. Moreover, when the transmission is non-zero, the structure of a resonant set depends on a regularizing sequence '(x) that tends to δ'(x) in the sense of distributions as 0. Therefore, from a practical point of view, it would be interesting to have an inverse solution, i.e. for a given λ ∈ to construct such a regularizing sequence '(x) that the δ'-potential at this value is transparent. If such a procedure is possible, then this value λ has to belong to a corresponding resonance set. The present paper is devoted to solving this problem and, as a result, the family of regularizing sequences is constructed by tuning adjustable parameters in the equations that provide a resonance transmission across the δ'-potential.