Nature Communications (Mar 2024)

Vacancies tailoring lattice anharmonicity of Zintl-type thermoelectrics

  • Jinfeng Zhu,
  • Qingyong Ren,
  • Chen Chen,
  • Chen Wang,
  • Mingfang Shu,
  • Miao He,
  • Cuiping Zhang,
  • Manh Duc Le,
  • Shuki Torri,
  • Chin-Wei Wang,
  • Jianli Wang,
  • Zhenxiang Cheng,
  • Lisi Li,
  • Guohua Wang,
  • Yuxuan Jiang,
  • Mingzai Wu,
  • Zhe Qu,
  • Xin Tong,
  • Yue Chen,
  • Qian Zhang,
  • Jie Ma

DOI
https://doi.org/10.1038/s41467-024-46895-4
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract While phonon anharmonicity affects lattice thermal conductivity intrinsically and is difficult to be modified, controllable lattice defects routinely function only by scattering phonons extrinsically. Here, through a comprehensive study of crystal structure and lattice dynamics of Zintl-type Sr(Cu,Ag,Zn)Sb thermoelectric compounds using neutron scattering techniques and theoretical simulations, we show that the role of vacancies in suppressing lattice thermal conductivity could extend beyond defect scattering. The vacancies in Sr2ZnSb2 significantly enhance lattice anharmonicity, causing a giant softening and broadening of the entire phonon spectrum and, together with defect scattering, leading to a ~ 86% decrease in the maximum lattice thermal conductivity compared to SrCuSb. We show that this huge lattice change arises from charge density reconstruction, which undermines both interlayer and intralayer atomic bonding strength in the hierarchical structure. These microscopic insights demonstrate a promise of artificially tailoring phonon anharmonicity through lattice defect engineering to manipulate lattice thermal conductivity in the design of energy conversion materials.