Nature Communications (Apr 2024)

High-entropy engineering of the crystal and electronic structures in a Dirac material

  • Antu Laha,
  • Suguru Yoshida,
  • Francisco Marques dos Santos Vieira,
  • Hemian Yi,
  • Seng Huat Lee,
  • Sai Venkata Gayathri Ayyagari,
  • Yingdong Guan,
  • Lujin Min,
  • Jose Gonzalez Jimenez,
  • Leixin Miao,
  • David Graf,
  • Saugata Sarker,
  • Weiwei Xie,
  • Nasim Alem,
  • Venkatraman Gopalan,
  • Cui-Zu Chang,
  • Ismaila Dabo,
  • Zhiqiang Mao

DOI
https://doi.org/10.1038/s41467-024-47781-9
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 11

Abstract

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Abstract Dirac and Weyl semimetals are a central topic of contemporary condensed matter physics, and the discovery of new compounds with Dirac/Weyl electronic states is crucial to the advancement of topological materials and quantum technologies. Here we show a widely applicable strategy that uses high configuration entropy to engineer relativistic electronic states. We take the AMnSb2 (A = Ba, Sr, Ca, Eu, and Yb) Dirac material family as an example and demonstrate that mixing of Ba, Sr, Ca, Eu and Yb at the A site generates the compound (Ba0.38Sr0.14Ca0.16Eu0.16Yb0.16)MnSb2 (denoted as A 5MnSb2), giving access to a polar structure with a space group that is not present in any of the parent compounds. A 5MnSb2 is an entropy-stabilized phase that preserves its linear band dispersion despite considerable lattice disorder. Although both A 5MnSb2 and AMnSb2 have quasi-two-dimensional crystal structures, the two-dimensional Dirac states in the pristine AMnSb2 evolve into a highly anisotropic quasi-three-dimensional Dirac state triggered by local structure distortions in the high-entropy phase, which is revealed by Shubnikov–de Haas oscillations measurements.