Detecting chiral pairing and topological superfluidity using circular dichroism

arXiv: Quantum Gases Pub Date : 2020-03-25 DOI:10.1103/PHYSREVRESEARCH.2.033385

J. M. Midtgaard, Zhigang Wu, N. Goldman, G. Bruun

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引用次数: 2

Abstract

Realising and probing topological superfluids is a key goal for fundamental science, with exciting technological promises. Here, we show that chiral $p_x+ip_y$ pairing in a two-dimensional topological superfluid can be detected through circular dichroism, namely, as a difference in the excitation rates induced by a clockwise and counter-clockwise circular drive. For weak pairing, this difference is to a very good approximation determined by the Chern number of the superfluid, whereas there is a non-topological contribution scaling as the superfluid gap squared that becomes signifiant for stronger pairing. This gives rise to a competition between the experimentally driven goal to maximise the critical temperature of the superfluid, and observing a signal given by the underlying topology. Using a combination of strong coupling Eliashberg and Berezinskii-Kosterlitz-Thouless theory, we analyse this tension for an atomic Bose-Fermi gas, which represents a promising platform for realising a chiral superfluid. We identify a wide range of system parameters where both the critical temperature is high and the topological contribution to the dichroic signal is dominant.

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利用圆二色性检测手性对和拓扑超流动性

实现和探测拓扑超流体是基础科学的一个关键目标，具有令人兴奋的技术前景。在这里，我们证明了二维拓扑超流体中的手性$p_x+ip_y$配对可以通过圆二色性来检测，即通过顺时针和逆时针圆形驱动引起的激励率差异来检测。对于弱配对，这种差异是由超流体的陈氏数决定的非常好的近似值，而对于强配对，超流体间隙平方的非拓扑贡献缩放变得重要。这就引起了实验驱动目标之间的竞争，即最大化超流体的临界温度，以及观察底层拓扑给出的信号。利用强耦合Eliashberg和Berezinskii-Kosterlitz-Thouless理论的组合，我们分析了原子玻色-费米气体的这种张力，它代表了实现手性超流体的一个有前途的平台。我们确定了一个范围广泛的系统参数，其中临界温度很高，拓扑对二向色信号的贡献占主导地位。

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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arXiv: Quantum Gases

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