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Iron pnictides and chalcogenides: a new paradigm for superconductivity

Author

Listed:
  • Rafael M. Fernandes

    (University of Minnesota)

  • Amalia I. Coldea

    (University of Oxford)

  • Hong Ding

    (Chinese Academy of Sciences
    University of Chinese Academy of Sciences)

  • Ian R. Fisher

    (Stanford University
    Stanford Institute for Materials and Energy Science, SLAC National Accelerator Laboratory)

  • P. J. Hirschfeld

    (University of Florida)

  • Gabriel Kotliar

    (Rutgers University
    Brookhaven National Laboratory)

Abstract

Superconductivity is a remarkably widespread phenomenon that is observed in most metals cooled to very low temperatures. The ubiquity of such conventional superconductors, and the wide range of associated critical temperatures, is readily understood in terms of the well-known Bardeen–Cooper–Schrieffer theory. Occasionally, however, unconventional superconductors are found, such as the iron-based materials, which extend and defy this understanding in unexpected ways. In the case of the iron-based superconductors, this includes the different ways in which the presence of multiple atomic orbitals can manifest in unconventional superconductivity, giving rise to a rich landscape of gap structures that share the same dominant pairing mechanism. In addition, these materials have also led to insights into the unusual metallic state governed by the Hund’s interaction, the control and mechanisms of electronic nematicity, the impact of magnetic fluctuations and quantum criticality, and the importance of topology in correlated states. Over the fourteen years since their discovery, iron-based superconductors have proven to be a testing ground for the development of novel experimental tools and theoretical approaches, both of which have extensively influenced the wider field of quantum materials.

Suggested Citation

  • Rafael M. Fernandes & Amalia I. Coldea & Hong Ding & Ian R. Fisher & P. J. Hirschfeld & Gabriel Kotliar, 2022. "Iron pnictides and chalcogenides: a new paradigm for superconductivity," Nature, Nature, vol. 601(7891), pages 35-44, January.
  • Handle: RePEc:nat:nature:v:601:y:2022:i:7891:d:10.1038_s41586-021-04073-2
    DOI: 10.1038/s41586-021-04073-2
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    Cited by:

    1. A. Korshunov & H. Hu & D. Subires & Y. Jiang & D. Călugăru & X. Feng & A. Rajapitamahuni & C. Yi & S. Roychowdhury & M. G. Vergniory & J. Strempfer & C. Shekhar & E. Vescovo & D. Chernyshov & A. H. Sa, 2023. "Softening of a flat phonon mode in the kagome ScV6Sn6," Nature Communications, Nature, vol. 14(1), pages 1-8, December.
    2. Lebing Chen & Xiaokun Teng & Hengxin Tan & Barry L. Winn & Garrett E. Granroth & Feng Ye & D. H. Yu & R. A. Mole & Bin Gao & Binghai Yan & Ming Yi & Pengcheng Dai, 2024. "Competing itinerant and local spin interactions in kagome metal FeGe," Nature Communications, Nature, vol. 15(1), pages 1-10, December.
    3. H. Suzuki & L. Wang & J. Bertinshaw & H. U. R. Strand & S. Käser & M. Krautloher & Z. Yang & N. Wentzell & O. Parcollet & F. Jerzembeck & N. Kikugawa & A. P. Mackenzie & A. Georges & P. Hansmann & H. , 2023. "Distinct spin and orbital dynamics in Sr2RuO4," Nature Communications, Nature, vol. 14(1), pages 1-7, December.
    4. Saizheng Cao & Chenchao Xu & Hiroshi Fukui & Taishun Manjo & Ying Dong & Ming Shi & Yang Liu & Chao Cao & Yu Song, 2023. "Competing charge-density wave instabilities in the kagome metal ScV6Sn6," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    5. Weijiong Chen & Clara Neerup Breiø & Freek Massee & Milan P. Allan & ‪Cedomir Petrovic & J. C. Séamus Davis & Peter J. Hirschfeld & Brian M. Andersen & Andreas Kreisel, 2023. "Interplay of hidden orbital order and superconductivity in CeCoIn5," Nature Communications, Nature, vol. 14(1), pages 1-7, December.

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