Viscosity of strongly interacting quantum fluids: spectral functions and sum rules
arXiv:1002.0869 · doi:10.1103/PhysRevA.81.053610
Abstract
The viscosity of strongly interacting systems is a topic of great interest in diverse fields. We focus here on the bulk and shear viscosities of \emph{non-relativistic} quantum fluids, with particular emphasis on strongly interacting ultracold Fermi gases. We use Kubo formulas for the bulk and shear viscosity spectral functions, $ζ(Ï)$ and $η(Ï)$ respectively, to derive exact, non-perturbative results. Our results include: a microscopic connection between the shear viscosity $η$ and the normal fluid density $Ï_n$; sum rules for $ζ(Ï)$ and $η(Ï)$ and their evolution through the BCS-BEC crossover; universal high-frequency tails for $η(Ï)$ and the dynamic structure factor $S({\bf q}, Ï)$. We use our sum rules to show that, at unitarity, $ζ(Ï)$ is identically zero and thus relate $η(Ï)$ to density-density correlations. We predict that frequency-dependent shear viscosity $η(Ï)$ of the unitary Fermi gas can be experimentally measured using Bragg spectroscopy.
Published version