Some exact solutions of the local induction equation for motion of a vortex in a Bose-Einstein condensate with Gaussian density profile

Abstract

The dynamics of a vortex filament in a trapped Bose-Einstein condensate is considered when the equilibrium density of the condensate, in rotating with angular velocity coordinate system, is Gaussian with a quadratic form r· D r. It is shown that equation of motion of the filament in the local induction approximation admits a class of exact solutions in the form of a straight moving vortex, R(β,t)=β M(t) + N(t), where β is a longitudinal parameter, and t is the time. The vortex is in touch with an ellipsoid, as it follows from the conservation laws N· D N=C1 and M· D N=C0=0. Equation of motion for the tangent vector M(t) turns out to be closed, and it has the integrals M· D M=C2, (| M| - M· G )=C, where the matrix G=2( I Tr\, D - D)-1. Intersection of the corresponding level surfaces determines trajectories in the phase space.