Nature Communications (Jun 2024)

Realization of monolayer ZrTe5 topological insulators with wide band gaps

  • Yong-Jie Xu,
  • Guohua Cao,
  • Qi-Yuan Li,
  • Cheng-Long Xue,
  • Wei-Min Zhao,
  • Qi-Wei Wang,
  • Li-Guo Dou,
  • Xuan Du,
  • Yu-Xin Meng,
  • Yuan-Kun Wang,
  • Yu-Hang Gao,
  • Zhen-Yu Jia,
  • Wei Li,
  • Lianlian Ji,
  • Fang-Sen Li,
  • Zhenyu Zhang,
  • Ping Cui,
  • Dingyu Xing,
  • Shao-Chun Li

DOI
https://doi.org/10.1038/s41467-024-49197-x
Journal volume & issue
Vol. 15, no. 1
pp. 1 – 8

Abstract

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Abstract Two-dimensional topological insulators hosting the quantum spin Hall effect have application potential in dissipationless electronics. To observe the quantum spin Hall effect at elevated temperatures, a wide band gap is indispensable to efficiently suppress bulk conduction. Yet, most candidate materials exhibit narrow or even negative band gaps. Here, via elegant control of van der Waals epitaxy, we have successfully grown monolayer ZrTe5 on a bilayer graphene/SiC substrate. The epitaxial ZrTe5 monolayer crystalizes in two allotrope isomers with different intralayer alignments of ZrTe3 prisms. Our scanning tunneling microscopy/spectroscopy characterization unveils an intrinsic full band gap as large as 254 meV and one-dimensional edge states localized along the periphery of the ZrTe5 monolayer. First-principles calculations further confirm that the large band gap originates from strong spin−orbit coupling, and the edge states are topologically nontrivial. These findings thus provide a highly desirable material platform for the exploration of the high-temperature quantum spin Hall effect.