Exact perturbative expansion of the transport coefficients of a normal low-temperature Fermi gas with contact interactions
Abstract
We compute the shear viscosity, thermal conductivity and spin diffusivity of a Fermi gas with short-range interactions in the Fermi liquid regime of the normal phase, that is at temperatures T much lower than the Fermi temperature T F and much larger than the superfluid critical temperature Tc. Given recent advances in the precision of cold atom experiments, we provide exact results up to second-order in the interaction strength. We extend the Landau-Salpeter equation to compute the collision amplitude beyond the forward-scattering limit, covering all collisions on the Fermi surface. We treat the collision kernel exactly, leading to significant corrections beyond relaxation-time or variational approximations. The transport coefficients, as functions of the s-wave scattering length a and Fermi wavenumber k F, follow (1+γ k Fa)/a2 up to corrections of order O(a0), with a positive coefficient γ for the viscosity and negative one for the thermal conductivity and spin diffusivity.
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