Hydrodynamics of vortices in Bose-Einstein condensates: A defect-gauge field approach

TL;DR

This paper develops a refined hydrodynamic framework for Bose-Einstein condensates that accurately incorporates vortex dynamics, providing analytical insights into quantum vortex behavior and extending applicability beyond traditional models.

Contribution

It introduces a defect-gauge field approach that correctly accounts for the multivalued phase, improving the description of vortex dynamics in superfluids.

Findings

Provides exact analytical explanations for vortex reconnection behavior.

Expands results beyond Gross-Pitaevskii theory to other superfluid systems.

Clarifies the role of multivalued phase in quantum turbulence.

Abstract

This work rectifies the hydrodynamic equations commonly used to describe the superfluid velocity field in such a way that vortex dynamics are also taken into account. In the field of quantum turbulence, it is of fundamental importance to know the correct form of the equations which play similar roles to the Navier-Stokes equation in classical turbulence. Here, such equations are obtained by carefully taking into account the frequently overlooked multivalued nature of the $U(1)$ phase field. Such an approach provides exact analytical explanations to some numerically observed features involving the dynamics of quantum vortices in Bose-Einstein condensates, such as the universal $t^{1/2}$ behavior of reconnecting vortex lines. It also expands these results beyond the Gross-Pitaevskii theory so that some features can be generalized to other systems such as superfluid $^{4}$He, dipolar condensates, and mixtures of different superfluid systems.