Stochastic Dynamics of a Vortex Loop. Thermal Equilibrium

Sergey K. Nemirovskii, Luiza P. Kondaurova, Makoto Tsubota

Published 2000-11-10Version 1

We study stochastic behavior of a single vortex loop appeared in imperfect Bose gas. Dynamics of Bose-condensate is supposed to obey Gross-Pitaevskii equation with additional noise satisfying fluctuation-dissipation relation. The corresponding Fokker-Planck equation for probability functional has a solution $\mathcal{P}(\{{\psi}(\mathbf{r})\})=\mathcal{N}\exp (-H{\psi}(\mathbf{r)} /T),$ where $H\psi(\mathbf{r})$ is a Ginzburg-Landau free energy. Considering a vortex filaments as a topological defects of the field ${\psi}(\mathbf{r})$ we derive a Langevin-type equation of motion of the line with correspondingly transformed stirring force. The respective Fokker-Planck equation for probability functional $\mathcal{P}(\{\mathbf{s}(\xi)\})$ in vortex loop configuration space is shown to have a solution of the form $\mathcal{P}(\{\mathbf{s}(\xi)\})=\mathcal{N}\exp (-H{\mathbf{s}} /T),$ where $\mathcal{N}$ is a normalizing factor and $H{\mathbf{s}}$ is energy of vortex line configurations. In other words a thermal equilibrium of Bose-condensate results in a thermal equilibrium of vortex loops appeared in Bose-condensate. Some consequences of that fact and possible violations are discussed.