Non-equilibrium BCS-BEC crossover and unconventional FFLO superfluid in a strongly interacting driven-dissipative Fermi gas

Taira Kawamura, Yoji Ohashi
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Abstract

We present a theoretical review of the recent progress in non-equilibrium BCS (Bardeen-Cooper-Schrieffer)-BEC (Bose-Einstein condensation) crossover physics. As a paradigmatic example, we consider a strongly interacting driven-dissipative two-component Fermi gas where the non-equilibrium steady state is tuned by adjusting the chemical potential difference between two reservoirs that are coupled with the system. As a powerful theoretical tool to deal with this system, we employ the Schwinger-Keldysh Green’s function technique. We systematically evaluate the superfluid transition, as well as the single-particle properties, in the non-equilibrium BCS-BEC crossover region, by adjusting the chemical potential difference between the reservoirs and the strength of an s-wave pairing interaction associated with a Feshbach resonance. In the weak-coupling BCS side, the chemical potential difference is shown to imprint a two-step structure on the particle momentum distribution, leading to an anomalous enhancement of pseudogap, as well as the emergence of exotic Fulde-Ferrell-Larkin-Ovchinnikov-type superfluid instability. Since various non-equilibrium situations have recently been realized in ultracold Fermi gases, the theoretical understanding of non-equilibrium BCS-BEC crossover physics would become increasingly important in this research field.

强相互作用驱动耗散费米气体中的非平衡 BCS-BEC 交叉和非常规 FFLO 超流体
我们从理论上回顾了非平衡 BCS(巴丁-库珀-施里弗)-BEC(玻色-爱因斯坦凝聚)交叉物理学的最新进展。作为一个典型的例子,我们考虑了强相互作用的驱动-耗散双组分费米气体,通过调整与系统耦合的两个储层之间的化学势差来调整非平衡稳态。作为处理该系统的强大理论工具,我们采用了施文格-凯尔迪什格林函数技术。通过调整储层之间的化学势差以及与费什巴赫共振相关的s波配对相互作用的强度,我们系统地评估了非平衡BCS-BEC交叉区域的超流体转变以及单粒子特性。在弱耦合BCS侧,化学势差被证明在粒子动量分布上印刻了一个两步结构,导致了伪间隙的异常增强,以及奇异的富尔德-费雷尔-拉金-奥夫钦尼科夫型超流体不稳定性的出现。由于最近在超冷费米气体中实现了各种非平衡态,对非平衡态BCS-BEC交叉物理的理论理解将在这一研究领域变得越来越重要。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
8.20
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