Dynamics of Superflow by Mesoscopic Condensate

Abstract

The shear viscosity η of a quantum liquid in the vicinity of Tλ is examined. In liquid helium 4 above Tλ (Tλ<T<3.7K), under a strong effect of Bose statistics, the coherent many-body wave function grows to an intermediate size between a macroscopic level and a microscopic one. These wave functions are qualitatively different from thermal fluctuation, and manifest themselves in the gradual decrease in shear viscosity above Tλ. To formulate this phenomenon, we combine the correlation function with fluid dynamics. Applying the Kramers-Kronig relation to the generalized Poiseuille's formula for capillary flow, we perform a perturbation calculation of the reciprocal 1/η with respect to the particle interaction, and examine how the growth of coherent wave functions gradually decreases shear viscosity. Comparing with the experimentally determined η (T), ·s(T)/· of such a mesoscopic condensate is estimated to reach 10-5 just above Tλ. We examine the effect of condensate size on the stability of such a superflow, and touch upon the superflow in porous media.