Theory for superfluidity in a Bose system

Abstract

We present a microscopic theory for superfluidity in an interacting many-particle Bose system (such as liquid 4He). We show that, similar to superconductivity in superconductors, superfluidity in a Bose system arises from pairing of particles of opposite momenta. We show the existence of an energy gap in single-particle excitation spectrum in the superfluid state and the existence of a specific heat jump at the superfluid transition. We derive an expression for superfluid particle density ns as a function of temperature T and superfluid velocity vs. We show that superfluid-state free energy density F is an increasing function of vs (i.e., ∂ F/∂ vs > 0), which indicates that a superfluid has a tendency to remain motionless (this result qualitatively explains the Hess-Fairbank effect, which is analogous to the Meissner effect in superconductors). We further speculate the existence of the equation j=-∇× ω, where j = ns vs is the superfluid current density, ω=∇× vs the superfluid vorticity, and a positive constant (with the help of this equation, the Hess-Fairbank effect can be quantitatively described).