The Hierarchy of Excitation Lifetimes in Two-Dimensional Fermi Gases

Momentum-conserving quasiparticle collisions in two-dimensional Fermi gases give rise to a large family of exceptionally long-lived excitation modes. The lifetimes of these modes exceed by a factor $(T_F/T)^2gg 1$ the conventional Landau Fermi-liquid lifetimes $tausim T_F/T^2$. The long-lived modes have a distinct angular structure, taking the form of $cos mtheta$ and $sin mtheta$ with odd $m$ values for a circular Fermi surface, with relaxation rate dependence on $m$ of the form $m^4log m$, valid at not-too-large $m$. In contrast, the even-$m$ harmonics feature conventional lifetimes with a weak $m$ dependence. The long-time dynamics, governed by the long-lived modes, takes the form of angular (super)diffusion over the Fermi surface. Altogether, this leads to unusual long-time memory effects, defining an intriguing transport regime that lies between the conventional ballistic and hydrodynamic regimes.