English

Quantized superfluid vortex dynamics on cylindrical surfaces and planar annuli

Quantum Gases 2017-12-15 v2

Abstract

Superfluid vortex dynamics on an infinite cylinder differs significantly from that on a plane. The requirement that a condensate wave function be single valued upon once encircling the cylinder means that such a single vortex cannot remain stationary. Instead, it acquires one of a series of quantized translational velocities around the circumference, the simplest being ±/(2MR)\pm \hbar/(2MR), with MM the mass of the superfluid particles and RR the radius of the cylinder. A generalization to a finite cylinder automatically includes these quantum-mechanical effects through the pairing of the single vortex and its image in either the top or bottom end of the surface. The dynamics of a single vortex on this surface provides a hydrodynamic analog of Laughlin pumping. The interaction energy for two vortices on an infinite cylinder is proportional to the classical stream function χ(r12)\chi({\bf r}_{12}), and it crosses over from logarithmic to linear when the intervortex separation r12{\bf r}_{12} becomes larger than the cylinder radius. An Appendix summarizes the connection to an earlier study of Ho and Huang for one or more vortices on an infinite cylinder. A second Appendix reviews the topologically equivalent planar annulus, where such quantized vortex motion has no offset, but Laughlin pumping may be more accessible to experimental observation.

Keywords

Cite

@article{arxiv.1708.08903,
  title  = {Quantized superfluid vortex dynamics on cylindrical surfaces and planar annuli},
  author = {Nils-Eric Guenther and Pietro Massignan and Alexander L. Fetter},
  journal= {arXiv preprint arXiv:1708.08903},
  year   = {2017}
}

Comments

16 pages, 7 figures; published version, with thoroughly revised Appendices

R2 v1 2026-06-22T21:26:57.065Z