Microscopic origin of quantum supersonic phenomenon in one dimension

Abstract

Using the Bethe ansatz (BA), we rigorously obtain non-equilibrium dynamics of an impurity with a large initial momentum Q in the one-dimensional (1D) interacting bosonic medium. We show that magnon and exciton-like states obtained from the BA equations drastically determine the oscillation nature of the quantum flutter with the periodicity given by τ QF = 2π/(| c(0)|- | s(0)|). Where the charge and spin dressed energies c,s(0) are precisely given by the thermodynamical BA equations. While we further find a persistent revival dynamics of the impurity with a larger periodicity τL = L/(v c(Q-k*)-v s(k*)) than τ QF, manifesting a quantum reflection induced by the periodic boundary conditions of a finite length L, here v c,s are the sound velocities of charge and spin excitations, respectively, and k* is a characteristic momentum of the impurity to the Fermi point. Finally, we study the application of such a magnon impurity as a quantum resource for measuring the gravitational force.