SciPost Phys. Core 6, 003 (2023) ·
published 23 January 2023
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We consider the propagation of quasiparticle excitations in a dipolar Bose-Einstein condensate,
and derive a nonlocal field theory of quasiparticle scattering
at a stepwise inhomogeneity of the sound speed, obtained by tuning the contact coupling part of the interaction on one side of the barrier.
To solve this problem ab initio, i.e., without prior assumptions on the form of the solutions, we reformulate the dipolar Bogoliubov-de Gennes equation as a singular integral equation. The latter is of a novel hypersingular type, in having a kernel which is hypersingular at only two isolated points.
Deriving its solution, we show that the integral equation reveals
a continuum of evanescent channels at the sound barrier which is absent for a purely contact-interaction condensate. We furthermore demonstrate that by performing a discrete approximation for the
kernel, one achieves an excellent solution accuracy for already a moderate number of discretization steps.
Finally, we show that the non-monotonic
nature of the system dispersion, corresponding to the emergence of a roton minimum in the excitation spectrum,
results in peculiar features of the transmission and reflection at the sound barrier
which are nonexistent for contact interactions.
Prof. Fischer: "We thank the Referee for the c..."
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