Knots and Coils in Superfluid Vortices

Dustin Kleckner; Davide Proment; Martin Scheeler; William T.M. Irvine

Knots and Coils in Superfluid Vortices

ORAL

Abstract

Recent work has demonstrated that linked and knotted vortices will spontaneously unknot or untie in both classical fluids and superfluids. This effect would appear to jeopardize any notion of conservation of fluid topology (helicity), but this need not be the case: vortices can transfer their knottedness to helical coils, preserving some measure of the original topology. By simulating superfluid vortices in the Gross-Pitaevskii equation, we find a geometric mechanism for efficiently transferring helicity in exactly this manner. Remarkably, the same transfer of topology to geometry also appears in viscous fluid vortices, suggesting it is a generic feature of non-ideal fluids.

^*This work was supported by the NSF MRSEC shared facilities at the University of Chicago (DMR-0820054) and an NSF CAREER award (DMR-1351506). W.T.M.I. further acknowledges support from the A.P. Sloan Foundation and the Packard Foundation.

Nov. 23, 2014, 5:24 PM – Nov. 23, 2014, 5:37 PM

Authors

Dustin Kleckner
- James Franck Institute, The University of Chicago
- University of Chicago, James Franck Institute
Davide Proment
- University of East Anglia
Martin Scheeler
- University of Chicago, James Franck Institute
William T.M. Irvine
- University of Chicago, James Franck Institute