Geometry Dynamics in Chiral Superfluids
Abstract
We investigate the geometric response of chiral superfluids when coupled to a dynamic background geometry. We find that geometry fluctuations, represented by the flexural mode, interact with the superfluid phase fluctuations (the Goldstone mode). Starting from a minimally coupled theory, we derive the equilibrium conditions for a static background defined by supercurrent, curvature, and tension, and then obtain linearized equations for the propagation of the Goldstone and flexural modes. The equations reveal distinctive chirality-dependent effects in the propagation of the flexural mode. Specifically, a background supercurrent induces a chiral drag effect, localizing flexural waves at the superfluid boundary, while background curvature introduces anisotropic corrections to the superfluid phase and group velocities, as well as a tension in the flexural mode dispersion. Furthermore, curvature couples flexural and phase modes into dressed excitations, with tilted Dirac cones along the principal curvature directions. These effects provide dynamical signatures of the formation of a chiral condensate, and can be tuned by manipulating the background geometry.
Keywords
Cite
@article{arxiv.2410.23375,
title = {Geometry Dynamics in Chiral Superfluids},
author = {Yuting Bai and Gabriel Cardoso and Rajae Malek and Qing-Dong Jiang},
journal= {arXiv preprint arXiv:2410.23375},
year = {2024}
}
Comments
12 pages, 9 figures