Spin drag and fast response in a quantum mixture of atomic gases

By applying a sudden perturbation to one of the components of a mixture of two quantum fluids, we explore the effect on the motion of the second component on a short timescale. By implementing perturbation theory, we prove that for short times the response of the second component is fixed by the energy weighted moment of the crossed dynamic structure factor (crossed f-sum rule). We also show that by properly monitoring the time duration of the perturbation it is possible to identify peculiar fast spin drag regimes, which are sensitive to the interaction effects in the Hamiltonian. Special focus is given to the case of coherently coupled Bose-Einstein condensates, interacting Bose mixtures exhibiting the Andreev-Bashkin effect, normal Fermi liquids, and the polaron problem. The relevant excitations of the system contributing to the spin drag effect are identified and the contribution of the low-frequency gapless excitations to the f-sum rule in the density and spin channels is explicitly calculated employing the proper macroscopic dynamic theories. Both spatially periodic and Galilean boost perturbations are considered.

Automated summary

In this study, the effect of applying a sudden perturbation to one component of a mixture of two quantum fluids on the motion of the second component on a short timescale is explored using perturbation theory. It is shown that the response of the second component is governed by the energy weighted moment of the crossed dynamic structure factor for short times. The identification of peculiar fast spin drag regimes sensitive to interaction effects in the Hamiltonian is possible by properly monitoring the time duration of the perturbation.