English

Potential Scattering on a Spherical Surface

Quantum Gases 2018-05-25 v3

Abstract

The advances in cold atom experiments have allowed construction of confining traps in the form of curved surfaces. This opens up the possibility of studying quantum gases in curved manifolds. On closed surfaces, many fundamental processes are affected by the local and global properties, i.e. the curvature and the topology of the surface. In this paper, we study the problem of potential scattering on a spherical surface and discuss its difference with that on a 2D plane. For bound states with angular momentum mm, their energies (EmE_{m}) on a sphere are related to those on a 2D plane (Em,o-|E_{m,o}|) as Em=Em,o+ER[m213+O(ro2R2)]E_{m}= - |E_{m, o}| + E_{R}^{} \left[ \frac{m^2-1}{3} + O\left( \frac{r_o^2}{R^2} \right) \right] , where ER=2/(2MR2)E_{R}^{} = \hbar^2/(2M R^2), and RR is the radius of the sphere. Due to the finite extent of the manifold, the phase shifts on a sphere at energies EERE\sim E_{R}^{} differ significantly from those on a 2D plane. As energy EE approaches zero, the phase shift in the planar case approaches 00, whereas in the spherical case it reaches a constant that connects the microscopic length scale to the largest length scale RR.

Keywords

Cite

@article{arxiv.1707.09460,
  title  = {Potential Scattering on a Spherical Surface},
  author = {Jian Zhang and Tin-Lun Ho},
  journal= {arXiv preprint arXiv:1707.09460},
  year   = {2018}
}

Comments

5 pages, 2 figures

R2 v1 2026-06-22T21:01:01.167Z