Larkin-Ovchinikov superfluidity in time-reversal symmetric bilayer Fermi gases

Larkin-Ovchinnikov (LO) state which combines the superfluidity and spatial periodicity of pairing order parameter and exhibits the supersolid properties has been attracting intense attention in both condensed matter physics and ultracold atoms. Conventionally, realization of LO state from an intrins...

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Bibliographic Details
Published in:arXiv.org 2019-02
Main Authors: Sun, Qing, Liang-Liang, Wang, Xiong-Jun, Liu, Juzeliūnas, G, An-Chun, Ji
Format: Article
Language:English
Subjects:
Atomic interactions
Atomic properties
Condensed matter physics
Fermi gases
Fluids
Interlayers
Lasers
Order parameters
Periodic variations
Predictions
Spin-orbit interactions
Superfluidity
Wave interaction
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Summary:Larkin-Ovchinnikov (LO) state which combines the superfluidity and spatial periodicity of pairing order parameter and exhibits the supersolid properties has been attracting intense attention in both condensed matter physics and ultracold atoms. Conventionally, realization of LO state from an intrinsic s-wave interacting system necessitates to break the time-reversal (TR) and sometimes spatial-inversion (SI) symmetries. Here we report a novel prediction that the LO state can be realized in a TR and SI symmetric system representing a bilayer Fermi gas subjected to a laserassisted interlayer tunneling. We show that the intralayer s-wave atomic interaction acts effectively like a p-wave interaction in the pseudospin space. This provides distinctive pairing effects in the present system with pseudspin spin-orbit coupling, and leads to a spontaneous density-modulation of the pairing order predicted in a very broad parameter regime. Unlike the conventional schemes, our results do not rely on the spin imbalance or external Zeeman fields, showing a highly feasible way to observe the long-sought-after LO superfluid phase using the laser-assisted bilayer Fermi gases.
ISSN:2331-8422
DOI:10.48550/arxiv.1801.02639