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Linear-in temperature resistivity from an isotropic Planckian scattering rate

Author

Listed:
  • Gaël Grissonnanche

    (Université de Sherbrooke
    Cornell University
    Kavli Institute at Cornell for Nanoscale Science)

  • Yawen Fang

    (Cornell University)

  • Anaëlle Legros

    (Université de Sherbrooke
    SPEC, CEA, CNRS-UMR 3680, Université Paris-Saclay)

  • Simon Verret

    (Université de Sherbrooke)

  • Francis Laliberté

    (Université de Sherbrooke)

  • Clément Collignon

    (Université de Sherbrooke)

  • Jianshi Zhou

    (University of Texas at Austin)

  • David Graf

    (National High Magnetic Field Laboratory)

  • Paul A. Goddard

    (University of Warwick)

  • Louis Taillefer

    (Université de Sherbrooke
    Canadian Institute for Advanced Research)

  • B. J. Ramshaw

    (Cornell University
    Canadian Institute for Advanced Research)

Abstract

A variety of ‘strange metals’ exhibit resistivity that decreases linearly with temperature as the temperature decreases to zero1–3, in contrast to conventional metals where resistivity decreases quadratically with temperature. This linear-in-temperature resistivity has been attributed to charge carriers scattering at a rate given by ħ/τ = αkBT, where α is a constant of order unity, ħ is the Planck constant and kB is the Boltzmann constant. This simple relationship between the scattering rate and temperature is observed across a wide variety of materials, suggesting a fundamental upper limit on scattering—the ‘Planckian limit’4,5—but little is known about the underlying origins of this limit. Here we report a measurement of the angle-dependent magnetoresistance of La1.6−xNd0.4SrxCuO4—a hole-doped cuprate that shows linear-in-temperature resistivity down to the lowest measured temperatures6. The angle-dependent magnetoresistance shows a well defined Fermi surface that agrees quantitatively with angle-resolved photoemission spectroscopy measurements7 and reveals a linear-in-temperature scattering rate that saturates at the Planckian limit, namely α = 1.2 ± 0.4. Remarkably, we find that this Planckian scattering rate is isotropic, that is, it is independent of direction, in contrast to expectations from ‘hotspot’ models8,9. Our findings suggest that linear-in-temperature resistivity in strange metals emerges from a momentum-independent inelastic scattering rate that reaches the Planckian limit.

Suggested Citation

  • Gaël Grissonnanche & Yawen Fang & Anaëlle Legros & Simon Verret & Francis Laliberté & Clément Collignon & Jianshi Zhou & David Graf & Paul A. Goddard & Louis Taillefer & B. J. Ramshaw, 2021. "Linear-in temperature resistivity from an isotropic Planckian scattering rate," Nature, Nature, vol. 595(7869), pages 667-672, July.
  • Handle: RePEc:nat:nature:v:595:y:2021:i:7869:d:10.1038_s41586-021-03697-8
    DOI: 10.1038/s41586-021-03697-8
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    Cited by:

    1. Bastien Michon & Christophe Berthod & Carl Willem Rischau & Amirreza Ataei & Lu Chen & Seiki Komiya & Shimpei Ono & Louis Taillefer & Dirk Marel & Antoine Georges, 2023. "Reconciling scaling of the optical conductivity of cuprate superconductors with Planckian resistivity and specific heat," Nature Communications, Nature, vol. 14(1), pages 1-10, December.
    2. Shusen Ye & Miao Xu & Hongtao Yan & Zi-Xiang Li & Changwei Zou & Xintong Li & Zhenqi Hao & Chaohui Yin & Yiwen Chen & Xingjiang Zhou & Dung-Hai Lee & Yayu Wang, 2024. "Emergent normal fluid in the superconducting ground state of overdoped cuprates," Nature Communications, Nature, vol. 15(1), pages 1-8, December.

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