Helical superfluid in a frustrated honeycomb Bose-Hubbard model
- URL: http://arxiv.org/abs/2206.00013v2
- Date: Mon, 29 Aug 2022 16:15:02 GMT
- Title: Helical superfluid in a frustrated honeycomb Bose-Hubbard model
- Authors: Tzu-Chi Hsieh, Han Ma, and Leo Radzihovsky
- Abstract summary: We study a "helical" superfluid, a nonzero-momentum condensate in a frustrated bosonic model.
At mean-field Bogoliubov level, such a novel state exhibits "smectic" fluctuation that are qualitatively stronger than that of a conventional superfluid.
- Score: 1.5197843979051469
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: We study a "helical" superfluid, a nonzero-momentum condensate in a
frustrated bosonic model. At mean-field Bogoliubov level, such a novel state
exhibits "smectic" fluctuation that are qualitatively stronger than that of a
conventional superfluid. We develop a phase diagram and compute a variety of
its physical properties, including the spectrum, structure factor, condensate
depletion, momentum distribution, all of which are qualitatively distinct from
that of a conventional superfluid. Interplay of fluctuations, interaction and
lattice effects gives rise to the phenomenon of order-by-disorder, leading to a
crossover from the smectic superfluid regime to the anisotropic XY superfluid
phase. We complement the microscopic lattice analysis with a field theoretic
description for such a helical superfluid, which we derive from microscopics
and justify on general symmetry grounds, reassuringly finding full consistency.
Possible experimental realizations are discussed.
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