English

Bound States for Nano-Tubes with a Dislocation

Mathematical Physics 2015-08-11 v2 math.MP Spectral Theory

Abstract

As a model for an interface in solid state physics, we consider two real-valued potentials V(1)V^{(1)} and V(2)V^{(2)} on the cylinder or tube S=R×(R/Z)S=\mathbb R \times (\mathbb R/\mathbb Z) where we assume that there exists an interval (a0,b0)(a_0,b_0) which is free of spectrum of Δ+V(k)-\Delta+V^{(k)} for k=1,2k=1,2. We are then interested in the spectrum of Ht=Δ+VtH_t = -\Delta + V_t, for tRt \in \mathbb R, where Vt(x,y)=V(1)(x,y)V_t(x,y) = V^{(1)}(x,y), for x>0x > 0, and Vt(x,y)=V(2)(x+t,y)V_t(x,y) = V^{(2)}(x+t,y), for x<0x < 0. While the essential spectrum of HtH_t is independent of tt, we show that discrete spectrum, related to the interface at x=0x = 0, is created in the interval (a0,b0)(a_0, b_0) at suitable values of the parameter tt, provided Δ+V(2)-\Delta + V^{(2)} has some essential spectrum in (,a0](-\infty, a_0]. We do not require V(1)V^{(1)} or V(2)V^{(2)} to be periodic. We furthermore show that the discrete eigenvalues of HtH_t are Lipschitz continuous functions of tt if the potential V(2)V^{(2)} is locally of bounded variation.

Keywords

Cite

@article{arxiv.1412.6420,
  title  = {Bound States for Nano-Tubes with a Dislocation},
  author = {Rainer Hempel and Martin Kohlmann and Marko Stautz and Jürgen Voigt},
  journal= {arXiv preprint arXiv:1412.6420},
  year   = {2015}
}

Comments

29 pages

R2 v1 2026-06-22T07:38:21.687Z