Origin and evolution of the multiply-quantised vortex instability
Abstract
We show that the dynamical instability of quantum vortices with more than a single quantum of angular momentum results from a superradiant bound state inside the vortex core. Our conclusion is supported by an analytic WKB calculation and numerical simulations of both linearised and fully non-linear equations of motion for a doubly-quantised vortex at the centre of a circular bucket trap. In the late stage of the instability, we reveal a striking novel behaviour of the system in the non-linear regime. Contrary to expectation, in the absence of dissipation the system never enters the regime of two well-separated phase defects described by Hamiltonian vortex dynamics. Instead, the separation between the two defects undergoes modulations which never exceed a few healing lengths, in which compressible kinetic energy and incompressible kinetic energy are exchanged. This suggests that, under the right conditions, pairs of vortices may be able to form meta-stable bound states.
Cite
@article{arxiv.2111.02567,
title = {Origin and evolution of the multiply-quantised vortex instability},
author = {Sam Patrick and August Geelmuyden and Sebastian Erne and Carlo F. Barenghi and Silke Weinfurtner},
journal= {arXiv preprint arXiv:2111.02567},
year = {2022}
}
Comments
9 pages, 5 figures