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Magnetic refrigeration material operating at a full temperature range required for hydrogen liquefaction

Author

Listed:
  • Xin Tang

    (National Institute for Materials Science
    International Center for Young Scientists, National Institute for Materials Science)

  • H. Sepehri-Amin

    (National Institute for Materials Science
    Tohoku University)

  • N. Terada

    (National Institute for Materials Science)

  • A. Martin-Cid

    (Japan Synchrotron Radiation Research Institute)

  • I. Kurniawan

    (National Institute for Materials Science
    University of Tsukuba)

  • S. Kobayashi

    (Japan Synchrotron Radiation Research Institute)

  • Y. Kotani

    (Japan Synchrotron Radiation Research Institute)

  • H. Takeya

    (National Institute for Materials Science)

  • J. Lai

    (National Institute for Materials Science)

  • Y. Matsushita

    (National Institute for Materials Science)

  • T. Ohkubo

    (National Institute for Materials Science)

  • Y. Miura

    (National Institute for Materials Science)

  • T. Nakamura

    (National Institute for Materials Science
    Tohoku University
    Japan Synchrotron Radiation Research Institute)

  • K. Hono

    (National Institute for Materials Science
    University of Tsukuba)

Abstract

Magnetic refrigeration (MR) is a key technique for hydrogen liquefaction. Although the MR has ideally higher performance than the conventional gas compression technique around the hydrogen liquefaction temperature, the lack of MR materials with high magnetic entropy change in a wide temperature range required for the hydrogen liquefaction is a bottle-neck for practical applications of MR cooling systems. Here, we show a series of materials with a giant magnetocaloric effect (MCE) in magnetic entropy change (-∆Sm > 0.2 J cm−3K−1) in the Er(Ho)Co2-based compounds, suitable for operation in the full temperature range required for hydrogen liquefaction (20-77 K). We also demonstrate that the giant MCE becomes reversible, enabling sustainable use of the MR materials, by eliminating the magneto-structural phase transition that leads to deterioration of the MCE. This discovery can lead to the application of Er(Ho)Co2-based alloys for the hydrogen liquefaction using MR cooling technology for the future green fuel society.

Suggested Citation

  • Xin Tang & H. Sepehri-Amin & N. Terada & A. Martin-Cid & I. Kurniawan & S. Kobayashi & Y. Kotani & H. Takeya & J. Lai & Y. Matsushita & T. Ohkubo & Y. Miura & T. Nakamura & K. Hono, 2022. "Magnetic refrigeration material operating at a full temperature range required for hydrogen liquefaction," Nature Communications, Nature, vol. 13(1), pages 1-8, December.
  • Handle: RePEc:nat:natcom:v:13:y:2022:i:1:d:10.1038_s41467-022-29340-2
    DOI: 10.1038/s41467-022-29340-2
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    References listed on IDEAS

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    1. Virgil Provenzano & Alexander J. Shapiro & Robert D. Shull, 2004. "Reduction of hysteresis losses in the magnetic refrigerant Gd5Ge2Si2 by the addition of iron," Nature, Nature, vol. 429(6994), pages 853-857, June.
    2. Virgil Provenzano & Alexander J. Shapiro & Robert D. Shull, 2004. "Correction: Corrigendum: Reduction of hysteresis losses in the magnetic refrigerant Gd5Ge2Si2 by the addition of iron," Nature, Nature, vol. 430(7001), pages 810-810, August.
    3. O. Tegus & E. Brück & K. H. J. Buschow & F. R. de Boer, 2002. "Transition-metal-based magnetic refrigerants for room-temperature applications," Nature, Nature, vol. 415(6868), pages 150-152, January.
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