单自旋非厄米系统的结拓扑观察

Yang Wu, Yunhan Wang, Xiangyu Ye, Wenquan Liu, Chang-Kui Duan, Ya Wang, Xing Rong, Jiangfeng Du
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引用次数: 1

摘要

系统的非厄密性产生了不同的结拓扑,没有厄密对应。本文报道了在$^{12}\mathrm{C}$同位素纯化金刚石中,基于长相干时间氮空位中心的普遍膨胀方法,对间隙非厄米系统的结拓扑结构进行了全面研究。揭示了能量带的编织模式和特征态拓扑结构。此外,我们还成功地观察到了与特征态拓扑相关的全局双正交Berry相位,从而识别了非厄米系统的拓扑不变性。我们的方法为进一步探索非厄米量子系统中带编织、本征态拓扑和对称性之间的相互作用铺平了道路。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Observation of the knot topology of non-Hermitian systems in a single spin
The non-Hermiticity of the system gives rise to distinct knot topology that has no Hermitian counterpart. Here, we report a comprehensive study of the knot topology in gapped non-Hermitian systems based on the universal dilation method with a long-coherence-time nitrogen-vacancy center in a $^{12}\mathrm{C}$ isotope purified diamond. Both the braiding patterns of energy bands and the eigenstate topology are revealed. Furthermore, the global biorthogonal Berry phase related to the eigenstate topology has been successfully observed, which identifies the topological invariance for the non-Hermitian system. Our method paves the way for further exploration of the interplay among band braiding, eigenstate topology, and symmetries in non-Hermitian quantum systems.
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