Perpetual motion and driven dynamics of a mobile impurity in a quantum fluid

Abstract: We study the dynamics of a mobile impurity in a quantum fluid at zero temperature. Two related settings are considered. In the first setting the impurity is injected in the fluid with some initial velocity ${\mathbf v}0$, and we are interested in its velocity at infinite time, ${\mathbf v}\infty$. We derive a rigorous upper bound on $|{\mathbf v}0-{\mathbf v}\infty|$ for initial velocities smaller than the generalized critical velocity. In the limit of vanishing impurity-fluid coupling this bound amounts to ${\mathbf v}\infty={\mathbf v}_0$ which can be regarded as a rigorous proof of the Landau criterion of superfluidity. In the case of a finite coupling the velocity of the impurity can drop, but not to zero; the bound quantifies the maximal possible drop. In the second setting a small constant force is exerted upon the impurity. We argue that two distinct dynamical regimes exist -- backscattering oscillations of the impurity velocity and saturation of the velocity without oscillations. For fluids with $v{c {\rm L}}=v_s$ (where $v_{c {\rm L}}$ and $v_s$ are the Landau critical velocity and sound velocity, respectively) the latter regime is realized. For fluids with $v_{c {\rm L}} < v_s$ both regimes are possible. Which regime is realized in this case depends on the mass of the impurity, a nonequilibrium quantum phase transition occurring at some critical mass. Our results are equally valid in one, two and three dimensions.