Non-stationary vortex ring in a Bose-Einstein condensate with Gaussian density

Abstract

The local induction equation, approximately describing dynamics of a quantized vortex filament in a trapped Bose-Einstein condensate in the Thomas-Fermi regime on a spatially nonuniform density background ( r) and taking dimensionless form Rt= b+[∇( R)× τ] (where is a local curvature of the filament, b is the unit binormal vector, and τ is the unit tangent vector), is shown to admit a finite-dimensional reduction if the density profile is an isotropic Gaussian, (-| r|2/2). The reduction corresponds to a geometrically perfect vortex ring centered at position A(t), with orientation and size both determined by a vector B(t). Parameters A and B exhibit the same dynamics as velocity and position of a Newtonian particle do in 3D: A= B/| B|2- B, and B= A.