Topological superconductivity from repulsive interactions in twisted WSe$_2$

Daniele Guerci, Daniel Kaplan, Julian Ingham, J. H. Pixley, Andrew J. Millis
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Abstract

The recent observation of superconductivity in twisted bilayer WSe$_2$ raises intriguing questions concerning the origin and the properties of superconducting states realized in bands with non-trivial topological properties and repulsive electron-electron interactions. Using a continuum band structure model, we analyze a mechanism for Coulomb interaction-driven superconductivity in twisted bilayers of WSe$_2$. We discuss the symmetries and the phenomenological properties of the resulting superconducting phases and their evolution with interlayer potential difference, tunable via an out of plane electric field. The pairing strength is a non-monotonic function of interlayer potential, being larger at intermediate values due to mixing of singlet and triplet pairing. In contrast, at larger interlayer potential, the pairing tendency is suppressed due to enhanced Coulomb repulsion. The superconducting state is chiral in a large regime of parameters and undergoes a transition to a nodal nematic superconductor at a critical potential difference. The chiral state, characterized by an intervalley-symmetric superposition of triplet and singlet pairs, is classified as a topological superconductor within the Altland-Zirnbauer class C. At zero interlayer potential difference, the superconducting state is instead of class D, which hosts Majorana zero modes, making it a promising candidate for applications in quantum computation.
扭曲 WSe$_2$ 中排斥相互作用产生的拓扑超导性
最近在扭曲双层 WSe$_2$ 中观察到的超导现象,提出了有关在具有非三维拓扑特性和排斥性电子-电子相互作用的带中实现的超导态的起源和性质的引人深思的问题。利用连续带结构模型,我们分析了 WSe$_2$ 扭曲双层中库仑相互作用驱动的超导机制。我们讨论了由此产生的超导相的对称性和现象学特性,以及它们随层间电位差的演变。配对强度是层间电势的非单调函数,在中间值时,由于小包和三重配对的混合,配对强度较大。相反,在层间电位较大时,由于库仑斥力增强,配对趋势受到抑制。超导态在很大的参数范围内是手性的,并在临界电位差时转变为结点向列超导体。这种手性态的特点是三重子和单重子对的间隔对称叠加,被归类为阿尔特兰-齐恩鲍尔 C 类拓扑超导体。在零层间电位差时,超导态转为 D 类,其中寄存着马约拉纳零模式,使其成为量子计算应用的理想候选者。
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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