Dynamics of Supersolid state: normal fluid, superfluid, and supersolid velocities

Abstract

Landau's excitation-based argument for superfluids -- that at temperature T=0 the normal fluid density n is zero -- should also apply to supersolids. Further, for a total mass density , Leggett argues that the superfluid fraction s/<1. These arguments imply that there is a missing mass. We attribute this to a supersolid density L, with L -s-n, and a momentum-bearing supersolid velocity vLi. Using Onsager's irreversible thermodynamics we derive the macroscopic dynamical equations for this system. We find that vLi is subject to the force of elasticity, to the negative gradient of the chemical potential per mass μ (as for the superfluid velocity vsi), and to drag against the normal fluid (leading to the interpretation of L as lattice). Thus both the superfluid and supersolid components are associated with the ground state. The normal modes for such a system have a crossover in frequency, above which the normal fluid velocity vni is an independent variable and below which it is locked to vLi. For an isotropic lattice we study both the transverse response and longitudinal response. The ring geometry for atomic gas supersolid states may provide a geometry for testing these predictions.