Vortex shedding from a microsphere oscillating in superfluid 4He at mK temperatures and from a laser beam moving in a Bose-Einstein condensate

Abstract

Turbulent drag of an oscillating microsphere, that is levitating in superfluid 4He at mK temperatures, is unstable slightly above a critical velocity amplitude vc. The lifetime τ of the turbulent state is determined by the number n of vortices shed per half-period. It is found that this number is identical to the superfluid Reynolds number. The possibility of moving a levitating sphere through superfluid 3He at microkelvin temperatures is considered. A laser beam moving through a Bose-Einstein condensate (BEC) (as observed by other authors) also produces vortices in the BEC. In particular, in either case a linear dependence of the shedding frequency fv on v = v - vc is observed, where v is the velocity amplitude of the sphere or the constant velocity of the laser beam above vc for the onset of turbulent flow: fv = a v, where the coefficient a is proportional to the oscillation frequency ω above some characteristic frequency ωk and assumes a finite value for steady motion ω → 0. A relation between the superfluid Reynolds number and the superfluid Strouhal number is presented that is different from classical turbulence.