Physical Review Research (Nov 2024)

Mapping the topology-localization phase diagram with quasiperiodic disorder using a programmable superconducting simulator

  • Xuegang Li,
  • Huikai Xu,
  • Junhua Wang,
  • Ling-Zhi Tang,
  • Dan-Wei Zhang,
  • Chuhong Yang,
  • Tang Su,
  • Chenlu Wang,
  • Zhenyu Mi,
  • Weijie Sun,
  • Xuehui Liang,
  • Mo Chen,
  • Chengyao Li,
  • Yingshan Zhang,
  • Kehuan Linghu,
  • Jiaxiu Han,
  • Weiyang Liu,
  • Yulong Feng,
  • Pei Liu,
  • Guangming Xue,
  • Jingning Zhang,
  • Yirong Jin,
  • Shi-Liang Zhu,
  • Haifeng Yu,
  • S. P. Zhao,
  • Qi-Kun Xue

DOI
https://doi.org/10.1103/PhysRevResearch.6.L042038
Journal volume & issue
Vol. 6, no. 4
p. L042038

Abstract

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We explore a topology-localization phase diagram by simulating a one-dimensional Su-Schrieffer-Heeger model with quasiperiodic disorder using a programmable superconducting simulator. We experimentally map out and identify various trivial and topological phases with extended, critical, and localized bulk states. We find that with increasing disorder strength, some extended states can be first replaced by localized states and then by critical states before the system finally becomes fully localized. The critical states exhibit typical features such as multifractality and self-similarity, which lead to surprisingly rich phases with different types of mobility edges and scaling behaviors on the phase boundaries. Our results shed light on the investigation of the topological and localization phenomena in condensed-matter physics.