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Hyperbolic matter in electrical circuits with tunable complex phases

Author

Listed:
  • Anffany Chen

    (University of Alberta
    University of Alberta)

  • Hauke Brand

    (Universität Würzburg)

  • Tobias Helbig

    (Universität Würzburg)

  • Tobias Hofmann

    (Universität Würzburg)

  • Stefan Imhof

    (Universität Würzburg)

  • Alexander Fritzsche

    (Universität Würzburg
    Universität Rostock)

  • Tobias Kießling

    (Universität Würzburg)

  • Alexander Stegmaier

    (Universität Würzburg)

  • Lavi K. Upreti

    (Universität Würzburg)

  • Titus Neupert

    (University of Zurich)

  • Tomáš Bzdušek

    (University of Zurich
    Paul Scherrer Institute)

  • Martin Greiter

    (Universität Würzburg)

  • Ronny Thomale

    (Universität Würzburg)

  • Igor Boettcher

    (University of Alberta
    University of Alberta)

Abstract

Curved spaces play a fundamental role in many areas of modern physics, from cosmological length scales to subatomic structures related to quantum information and quantum gravity. In tabletop experiments, negatively curved spaces can be simulated with hyperbolic lattices. Here we introduce and experimentally realize hyperbolic matter as a paradigm for topological states through topolectrical circuit networks relying on a complex-phase circuit element. The experiment is based on hyperbolic band theory that we confirm here in an unprecedented numerical survey of finite hyperbolic lattices. We implement hyperbolic graphene as an example of topologically nontrivial hyperbolic matter. Our work sets the stage to realize more complex forms of hyperbolic matter to challenge our established theories of physics in curved space, while the tunable complex-phase element developed here can be a key ingredient for future experimental simulation of various Hamiltonians with topological ground states.

Suggested Citation

  • Anffany Chen & Hauke Brand & Tobias Helbig & Tobias Hofmann & Stefan Imhof & Alexander Fritzsche & Tobias Kießling & Alexander Stegmaier & Lavi K. Upreti & Titus Neupert & Tomáš Bzdušek & Martin Greit, 2023. "Hyperbolic matter in electrical circuits with tunable complex phases," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:14:y:2023:i:1:d:10.1038_s41467-023-36359-6
    DOI: 10.1038/s41467-023-36359-6
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    References listed on IDEAS

    as
    1. R. Gerritsma & G. Kirchmair & F. Zähringer & E. Solano & R. Blatt & C. F. Roos, 2010. "Quantum simulation of the Dirac equation," Nature, Nature, vol. 463(7277), pages 68-71, January.
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    3. Weixuan Zhang & Hao Yuan & Na Sun & Houjun Sun & Xiangdong Zhang, 2022. "Observation of novel topological states in hyperbolic lattices," Nature Communications, Nature, vol. 13(1), pages 1-10, December.
    4. Patrick M. Lenggenhager & Alexander Stegmaier & Lavi K. Upreti & Tobias Hofmann & Tobias Helbig & Achim Vollhardt & Martin Greiter & Ching Hua Lee & Stefan Imhof & Hauke Brand & Tobias Kießling & Igor, 2022. "Simulating hyperbolic space on a circuit board," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
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    Cited by:

    1. Qiaolu Chen & Zhe Zhang & Haoye Qin & Aleksi Bossart & Yihao Yang & Hongsheng Chen & Romain Fleury, 2024. "Anomalous and Chern topological waves in hyperbolic networks," Nature Communications, Nature, vol. 15(1), pages 1-7, December.
    2. Lei Huang & Lu He & Weixuan Zhang & Huizhen Zhang & Dongning Liu & Xue Feng & Fang Liu & Kaiyu Cui & Yidong Huang & Wei Zhang & Xiangdong Zhang, 2024. "Hyperbolic photonic topological insulators," Nature Communications, Nature, vol. 15(1), pages 1-9, December.
    3. Weixuan Zhang & Fengxiao Di & Xingen Zheng & Houjun Sun & Xiangdong Zhang, 2023. "Hyperbolic band topology with non-trivial second Chern numbers," Nature Communications, Nature, vol. 14(1), pages 1-9, December.

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