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Topological surface currents accessed through reversible hydrogenation of the three-dimensional bulk

Author

Listed:
  • Haiming Deng

    (The City College of New York - CUNY)

  • Lukas Zhao

    (The City College of New York - CUNY)

  • Kyungwha Park

    (Virginia Tech)

  • Jiaqiang Yan

    (Oak Ridge National Laboratory)

  • Kamil Sobczak

    (University of Warsaw)

  • Ayesha Lakra

    (The City College of New York - CUNY)

  • Entela Buzi

    (The City College of New York - CUNY)

  • Lia Krusin-Elbaum

    (The City College of New York - CUNY
    City University of New York Graduate Center)

Abstract

Hydrogen, the smallest and most abundant element in nature, can be efficiently incorporated within a solid and drastically modify its electronic and structural state. In most semiconductors interstitial hydrogen binds to defects and is known to be amphoteric, namely it can act either as a donor (H+) or an acceptor (H−) of charge, nearly always counteracting the prevailing conductivity type. Here we demonstrate that hydrogenation resolves an outstanding challenge in chalcogenide classes of three-dimensional (3D) topological insulators and magnets — the control of intrinsic bulk conduction that denies access to quantum surface transport, imposing severe thickness limits on the bulk. With electrons donated by a reversible binding of H+ ions to Te(Se) chalcogens, carrier densities are reduced by over 1020cm−3, allowing tuning the Fermi level into the bulk bandgap to enter surface/edge current channels without altering carrier mobility or the bandstructure. The hydrogen-tuned topological nanostructures are stable at room temperature and tunable disregarding bulk size, opening a breadth of device platforms for harnessing emergent topological states.

Suggested Citation

  • Haiming Deng & Lukas Zhao & Kyungwha Park & Jiaqiang Yan & Kamil Sobczak & Ayesha Lakra & Entela Buzi & Lia Krusin-Elbaum, 2022. "Topological surface currents accessed through reversible hydrogenation of the three-dimensional bulk," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
    • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-29957-3
    DOI: 10.1038/s41467-022-29957-3
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    References listed on IDEAS

    as
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