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Magnetically and optically active edges in phosphorene nanoribbons

Author

Listed:
  • Arjun Ashoka

    (University of Cambridge)

  • Adam J. Clancy

    (University College London)

  • Naitik A. Panjwani

    (Freie Universität Berlin)

  • Adam Cronin

    (Berkeley)

  • Loren Picco

    (University of Bristol)

  • Eva S. Y. Aw

    (University College London)

  • Nicholas J. M. Popiel

    (University of Cambridge)

  • Alexander G. Eaton

    (University of Cambridge)

  • Thomas G. Parton

    (University of Cambridge)

  • Rebecca R. C. Shutt

    (University College London)

  • Sascha Feldmann

    (École Polytechnique Fédérale de Lausanne)

  • Remington Carey

    (University of Cambridge)

  • Thomas J. Macdonald

    (Imperial College London
    University College London)

  • Cheng Liu

    (University of Cambridge)

  • Marion E. Severijnen

    (Radboud University)

  • Sandra Kleuskens

    (Radboud University)

  • Loreta A. Muscarella

    (AMOLF
    Vrije Universiteit Amsterdam)

  • Felix R. Fischer

    (Berkeley
    Kavli Energy NanoSciences Institute at the University of California Berkeley and the Lawrence Berkeley National Laboratory
    Lawrence Berkeley National Laboratory)

  • Hilton Barbosa de Aguiar

    (Collège de France)

  • Richard H. Friend

    (University of Cambridge)

  • Jan Behrends

    (Freie Universität Berlin)

  • Peter C. M. Christianen

    (Radboud University)

  • Christopher A. Howard

    (University College London)

  • Raj Pandya

    (University of Cambridge
    Collège de France
    University of Warwick)

Abstract

Nanoribbons, nanometre-wide strips of a two-dimensional material, are a unique system in condensed matter. They combine the exotic electronic structures of low-dimensional materials with an enhanced number of exposed edges, where phenomena including ultralong spin coherence times1,2, quantum confinement3 and topologically protected states4,5 can emerge. An exciting prospect for this material concept is the potential for both a tunable semiconducting electronic structure and magnetism along the nanoribbon edge, a key property for spin-based electronics such as (low-energy) non-volatile transistors6. Here we report the magnetic and semiconducting properties of phosphorene nanoribbons (PNRs). We demonstrate that at room temperature, films of PNRs show macroscopic magnetic properties arising from their edge, with internal fields of roughly 240 to 850 mT. In solution, a giant magnetic anisotropy enables the alignment of PNRs at sub-1-T fields. By leveraging this alignment effect, we discover that on photoexcitation, energy is rapidly funnelled to a state that is localized to the magnetic edge and coupled to a symmetry-forbidden edge phonon mode. Our results establish PNRs as a fascinating system for studying the interplay between magnetism and semiconducting ground states at room temperature and provide a stepping-stone towards using low-dimensional nanomaterials in quantum electronics.

Suggested Citation

  • Arjun Ashoka & Adam J. Clancy & Naitik A. Panjwani & Adam Cronin & Loren Picco & Eva S. Y. Aw & Nicholas J. M. Popiel & Alexander G. Eaton & Thomas G. Parton & Rebecca R. C. Shutt & Sascha Feldmann & , 2025. "Magnetically and optically active edges in phosphorene nanoribbons," Nature, Nature, vol. 639(8054), pages 348-353, March.
    • Handle: RePEc:nat:nature:v:639:y:2025:i:8054:d:10.1038_s41586-024-08563-x
    DOI: 10.1038/s41586-024-08563-x
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