Cold Strongly Coupled Atoms Make a Near-perfect Liquid

Abstract

Feshbach resonances of trapped ultracold alkali atoms allow to vary the atomic scattering length a. At very large values of a the system enters an universal strongly coupled regime in which its properties--the ground state energy, pressure {\it etc.}--become independent of a. We discuss transport properties of such systems. In particular, the universality arguments imply that the shear viscosity of ultracold Fermi atoms at the Feschbach resonance is proportional to the particle number density n, and the Plank constant \hbar η=\hbar n α_η, where α_ηis a universal constant. Using Heisenberg uncertainty principle and Einstein's relation between diffusion and viscosity we argue that the viscosity has the lower bound given by α_η \leq (6π)^{-1}. We relate the damping of low-frequency density oscillations of ultracold optically trapped ^{6}Li atoms to viscosity and find that the value of the coefficient α_ηis about 0.3. We also show that such a small viscosity can not be explained by kinetic theory based on binary scattering. We conclude that the system of ultracold atoms near the Feshbach resonance is a near-ideal liquid.