Anomalous non-thermal fixed point in a quasi-two-dimensional dipolar Bose gas

TL;DR

This paper investigates the sub-diffusive scaling behavior near an anomalous non-thermal fixed point in a quasi-two-dimensional dipolar Bose gas, revealing universal dynamics driven by vortex-antivortex annihilation and distinct vortex patterns due to dipolar interactions.

Contribution

It demonstrates the universality of non-thermal fixed points in dipolar Bose gases and uncovers how dipolar interactions influence vortex configurations and scaling behavior.

Findings

Observed sub-diffusive scaling with $eta\,\approx0.2$

Transition to diffusion-type scaling with $eta\approx1/2$ at late times

Dipolar interactions alter vortex patterns, preventing clustering

Abstract

The emergence of distinctly sub-diffusive scaling in the vicinity of an anomalous non-thermal fixed point is discussed in a quasi-two-dimensional dipolar Bose gas in the superfluid phase, carrying ensembles of vortices and antivortices with zero net angular momentum. The observed scaling behavior reflects coarsening dynamics driven by the mutual annihilation of vortices and antivortices, with the mean inter-defect distance growing algebraically over time as $\ell_\text{v}(t)\sim t^{\,\beta}$. A sub-diffusive ($\beta<1/2$) exponent $\beta\approx0.2$ is extracted for various parameter regimes, initial conditions, and dipolar configurations from both scaling occupation-number spectra and the evolution of inter-defect distances as well as the corresponding total vortex densities. As vortex-antivortex annihilation progresses, excitations of the background condensate increase. This gives rise to a transition in the scaling behavior at late times, toward a non-thermal fixed point governed by diffusion-type scaling with $\beta\approx1/2$ as expected for the mutual annihilation of well-separated vortex-antivortex dipoles. While the temporal scaling with $\beta$ does not depend significantly on the strength and anisotropy of the dipolar interactions and thus underlines the universality of the anomalous as well as diffusion-type non-thermal fixed points, we find distinctly different vortex patterns resulting in the dipolar case. While in the superfluid with contact interactions only, same-sign vortices tend to cluster and form large-scale eddies, in the dipolar and tilted cases, roton excitations appear to prevent such motion, giving rather rise to a maximisation of distances between vortices of either sign.