Quantum double structure in cold atom superfluids

IF 4.2 Q2 QUANTUM SCIENCE & TECHNOLOGY AVS quantum science Pub Date : 2023-09-01 DOI:10.1116/5.0155096
Emil Génetay Johansen, Chris Vale, Tapio Simula
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Abstract

The theory of topological quantum computation is underpinned by two important classes of models. One is based on non-abelian Chern–Simons theory, which yields the so-called SU(2)k anyon models that often appear in the context of electrically charged quantum fluids. The physics of the other is captured by symmetry broken Yang–Mills theory in the absence of a Chern–Simons term and results in the so-called quantum double models. Extensive resources have been invested into the search for SU(2)k anyon quasi-particles, in particular, the so-called Ising anyons (k = 2) of which Majorana zero modes are believed to be an incarnation. In contrast to the SU(2)k models, quantum doubles have attracted little attention in experiments despite their pivotal role in the theory of error correction. Beyond topological error correcting codes, the appearance of quantum doubles has been limited to contexts primarily within mathematical physics, and as such, they are of seemingly little relevance for the study of experimentally tangible systems. However, recent works suggest that quantum double anyons may be found in spinor Bose–Einstein condensates. In light of this, the core purpose of this article is to provide a self-contained exposition of the quantum double structure, framed in the context of spinor condensates, by constructing explicitly the quantum doubles for various ground state symmetry groups and discuss their experimental realisability. We also derive analytically an equation for the quantum double Clebsch–Gordan coefficients from which the relevant braid matrices can be worked out. Finally, the existence of a particle-vortex duality is exposed and illuminated upon in this context.
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冷原子超流体中的量子双重结构
拓扑量子计算理论的基础是两类重要的模型。一种是基于非阿贝尔陈-西蒙斯理论,它产生了所谓的SU(2)k任意子模型,这种模型经常出现在带电量子流体的背景下。在没有陈-西蒙斯项的情况下,对称破缺的杨-米尔斯理论捕捉到了另一方的物理特性,并产生了所谓的量子双重模型。大量的资源已经投入到寻找SU(2)k任意子准粒子,特别是所谓的Ising任意子(k = 2),其中Majorana零模式被认为是其化身。与SU(2)k模型相比,量子双元在实验中很少受到关注,尽管它们在误差校正理论中起着关键作用。除了拓扑纠错码之外,量子双精度的出现主要局限于数学物理中的背景,因此,它们与实验有形系统的研究似乎没有什么关联。然而,最近的研究表明,量子双任意子可能在旋量玻色-爱因斯坦凝聚物中被发现。鉴于此,本文的核心目的是通过明确构建各种基态对称群的量子双元,并讨论其实验可行性,在旋量凝聚的背景下对量子双元结构进行独立的阐述。我们还解析地导出了量子双克莱布希-戈登系数的方程,由此可以计算出相应的编织矩阵。最后,在此背景下揭示并阐明了粒子-涡旋二象性的存在。
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CiteScore
9.90
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