Quantum mechanical limitations to spin diffusion in the unitary Fermi gas
arXiv:1207.3103 · doi:10.1103/PhysRevLett.109.195303
Abstract
We compute spin transport in the unitary Fermi gas using the strong-coupling Luttinger-Ward theory. In the quantum degenerate regime the spin diffusivity attains a minimum value of $D_s \simeq 1.3 \hbar/m$ approaching the quantum limit of diffusion for a particle of mass $m$. Conversely, the spin drag rate reaches a maximum value of $Î_\sd \simeq 1.2 k_B T_F/\hbar$ in terms of the Fermi temperature $T_F$. The frequency-dependent spin conductivity $Ï_s(Ï)$ exhibits a broad Drude peak, with spectral weight transferred to a universal high-frequency tail $Ï_s(Ï\to\infty) = \hbar^{1/2}C/3Ï(mÏ)^{3/2}$ proportional to the Tan contact density $C$. For the spin susceptibility $Ï_s(T)$ we find no downturn in the normal phase.
5 pages, 4 figures; published version