Tunneling in a uniform one-dimensional superfluid: emergence of a complex instanton
Abstract
In a uniform ring-shaped one-dimensional superfluid, quantum fluctuations that unwind the order parameter need to transfer momentum to quasiparticles (phonons). We present a detailed calculation of the leading exponential factor governing the rate of such phonon-assisted tunneling in a weakly-coupled Bose gas at a low temperature T. We also estimate the preexponent. We find that for small superfluid velocities the T-dependence of the rate is given mainly by (-cs P/ 2T), where P is the momentum transfer, and cs is the phonon speed. At low T, this represents a strong suppression of the rate, compared to the non-uniform case. As a part of our calculation, we identify a complex instanton, whose analytical continuation to suitable real-time segments is real and describes formation and decay of coherent quasiparticle states with nonzero total momenta.
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