Phonon number relaxation in a 3D superfluid with a concave acoustic branch

Abstract

We consider the collisional evolution towards equilibrium of a spatially homogeneous and isotropic phonon gas of a three-dimensional superfluid with a concave acoustic excitation branch, at a non-zero but arbitrarily low temperature T. Three-phonon collisions 1φ 2φ are forbidden by conservation of energy-momentum. Four-phonon collisions 2φ 2φ of Landau and Khalatnikov lead, after a time T-7, only to a partial thermal equilibrium, a Bose law of non-zero chemical potential for the phonons, because they conserve the total number of phonons. Relaxation towards complete thermochemical equilibrium is therefore ensured by the much slower five-phonon collisions 2φ 3φ of Khalatnikov, in a time T-9. Using kinetic equations on the occupation numbers of the phonon modes and explicitly calculating the 2φ 3φ collisional amplitude with quantum hydrodynamics at low temperature, we determine the corresponding evolution of the fugacity zφ of the phonon gas from the non-degenerate regime zφ=0+ to complete equilibrium zφ=1-. Using the conservation of total energy, we find that the fugacity varies with a non-integer power law t4/5 at short times and an exponential law at long times; the speed of change of entropy, always positive, is asymptotically proportional to the square of the speed of change of fugacity, (d/dt)Sφ[(d/dt)zφ]2, as Landau predicted for an arbitrarily slow adiabatic transformation. Our results bring to a close the study initiated by Khalatnikov in 1950 and could be experimentally verified in a gas of cold fermionic atoms on the BCS side of the BEC-BCS crossover, or in superfluid liquid helium-4 at sufficiently high pressure.