English

Resonances - lost and found

Mathematical Physics 2017-10-11 v2 math.MP

Abstract

We consider the large LL limit of one dimensional Schr\"odinger operators HL=d2/dx2+V1(x)+V2,L(x)H_L=-d^2/dx^2 + V_1(x) + V_{2,L}(x) in two cases: when V2,L(x)=V2(xL)V_{2,L}(x)=V_2(x-L) and when V2,L(x)=ecLδ(xL)V_{2,L}(x)=e^{-cL}\delta(x-L). This is motivated by some recent work of Herbst and Mavi where V2,LV_{2,L} is replaced by a Dirichlet boundary condition at LL. The Hamiltonian HLH_L converges to H=d2/dx2+V1(x)H = -d^2/dx^2 + V_1(x) as LL\to \infty in the strong resolvent sense (and even in the norm resolvent sense for our second case). However, most of the resonances of HLH_L do not converge to those of HH. Instead, they crowd together and converge onto a horizontal line: the real axis in our first case and the line (k)=c/2\Im(k)=-c/2 in our second case. In the region below the horizontal line resonances of HLH_L converge to the reflectionless points of HH and to those of d2/dx2+V2(x)-d^2/dx^2 + V_2(x). It is only in the region between the real axis and the horizontal line (empty in our first case) that resonances of HLH_L converge to resonances of HH. Although the resonances of HH may not be close to any resonance of HLH_L we show that they still influence the time evolution under HLH_L for a long time when LL is large.

Keywords

Cite

@article{arxiv.1703.03172,
  title  = {Resonances - lost and found},
  author = {Richard Froese and Ira Herbst},
  journal= {arXiv preprint arXiv:1703.03172},
  year   = {2017}
}

Comments

29 pages, 3 figures, 2 movies

R2 v1 2026-06-22T18:40:41.071Z