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Auteurs principaux: Liao, Yunxiang, Grankin, Andrey, Panigrahi, Archisman, Galitski, Victor, Levitov, Leonid
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2604.10759
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author Liao, Yunxiang
Grankin, Andrey
Panigrahi, Archisman
Galitski, Victor
Levitov, Leonid
author_facet Liao, Yunxiang
Grankin, Andrey
Panigrahi, Archisman
Galitski, Victor
Levitov, Leonid
contents Tunable interactions make ultracold quantum gases a unique platform for exploring hydrodynamic properties in the strongly correlated regime. Of particular interest are turbulent flows possible in the regime of high Reynolds numbers. Since the system size and flow velocity are limited in experimentally realistic systems, we propose an alternative approach to enhance the Reynolds numbers in an ultracold Fermi gas by minimizing the shear viscosity in the vicinity of the Feshbach resonance. By employing the Keldysh formulation of the linear response theory, we theoretically demonstrate that the shear viscosity can vary by several orders of magnitude in the vicinity of the BCS-BEC crossover. It is also shown that while Drude-like contributions generally dominate at large Feshbach detunings, higher-order vertex corrections, including the Maki-Thompson contribution, become significant and suppress singular behavior in the near-resonant regime. Our results provide a roadmap for achieving tunable Reynolds numbers in ultracold quantum fluids, which can serve as table-top turbulence simulators.
format Preprint
id arxiv_https___arxiv_org_abs_2604_10759
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Tunable viscosity across the BCS-BEC crossover
Liao, Yunxiang
Grankin, Andrey
Panigrahi, Archisman
Galitski, Victor
Levitov, Leonid
Quantum Gases
Tunable interactions make ultracold quantum gases a unique platform for exploring hydrodynamic properties in the strongly correlated regime. Of particular interest are turbulent flows possible in the regime of high Reynolds numbers. Since the system size and flow velocity are limited in experimentally realistic systems, we propose an alternative approach to enhance the Reynolds numbers in an ultracold Fermi gas by minimizing the shear viscosity in the vicinity of the Feshbach resonance. By employing the Keldysh formulation of the linear response theory, we theoretically demonstrate that the shear viscosity can vary by several orders of magnitude in the vicinity of the BCS-BEC crossover. It is also shown that while Drude-like contributions generally dominate at large Feshbach detunings, higher-order vertex corrections, including the Maki-Thompson contribution, become significant and suppress singular behavior in the near-resonant regime. Our results provide a roadmap for achieving tunable Reynolds numbers in ultracold quantum fluids, which can serve as table-top turbulence simulators.
title Tunable viscosity across the BCS-BEC crossover
topic Quantum Gases
url https://arxiv.org/abs/2604.10759