Nature Communications (Aug 2023)

Vacancy-mediated anomalous phononic and electronic transport in defective half-Heusler ZrNiBi

  • Wuyang Ren,
  • Wenhua Xue,
  • Shuping Guo,
  • Ran He,
  • Liangzi Deng,
  • Shaowei Song,
  • Andrei Sotnikov,
  • Kornelius Nielsch,
  • Jeroen van den Brink,
  • Guanhui Gao,
  • Shuo Chen,
  • Yimo Han,
  • Jiang Wu,
  • Ching-Wu Chu,
  • Zhiming Wang,
  • Yumei Wang,
  • Zhifeng Ren

DOI
https://doi.org/10.1038/s41467-023-40492-7
Journal volume & issue
Vol. 14, no. 1
pp. 1 – 10

Abstract

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Abstract Studies of vacancy-mediated anomalous transport properties have flourished in diverse fields since these properties endow solid materials with fascinating photoelectric, ferroelectric, and spin-electric behaviors. Although phononic and electronic transport underpin the physical origin of thermoelectrics, vacancy has only played a stereotyped role as a scattering center. Here we reveal the multifunctionality of vacancy in tailoring the transport properties of an emerging thermoelectric material, defective n-type ZrNiBi. The phonon kinetic process is mediated in both propagating velocity and relaxation time: vacancy-induced local soft bonds lower the phonon velocity while acoustic-optical phonon coupling, anisotropic vibrations, and point-defect scattering induced by vacancy shorten the relaxation time. Consequently, defective ZrNiBi exhibits the lowest lattice thermal conductivity among the half-Heusler family. In addition, a vacancy-induced flat band features prominently in its electronic band structure, which is not only desirable for electron-sufficient thermoelectric materials but also interesting for driving other novel physical phenomena. Finally, better thermoelectric performance is established in a ZrNiBi-based compound. Our findings not only demonstrate a promising thermoelectric material but also promote the fascinating vacancy-mediated anomalous transport properties for multidisciplinary explorations.