Rotation-induced three-dimensional vorticity in {sup 4}He superfluid films adsorbed on a porous glass

A detailed study of torsional oscillator experiments under steady rotation up to 6.28 rad/sec is reported for a {sup 4}He superfluid monolayer film formed in 1-{mu}m-pore-diameter porous glass. We discovered a new dissipation peak, whose height changes in proportion to the angular speed. The new peak appears at a temperature lower than the vortex pair unbinding peak observed in the static state. A model of three-dimensional (3D) coreless vortices ('pore vortices') is proposed to explain this additional peak in terms of 2D vortex pair dynamics in the presence of a flow field caused by 3D vortices. The new peak originates from dissipation close to the pore vortex lines, where a large superfluid velocity shifts the vortex pair unbinding dissipation to lower temperature. This explanation is consistent with the observation of nonlinear effects at high oscillation amplitudes.