- Main
Electronic evidence of temperature-induced Lifshitz transition and topological nature in ZrTe5
- Zhang, Yan;
- Wang, Chenlu;
- Yu, Li;
- Liu, Guodong;
- Liang, Aiji;
- Huang, Jianwei;
- Nie, Simin;
- Sun, Xuan;
- Zhang, Yuxiao;
- Shen, Bing;
- Liu, Jing;
- Weng, Hongming;
- Zhao, Lingxiao;
- Chen, Genfu;
- Jia, Xiaowen;
- Hu, Cheng;
- Ding, Ying;
- Zhao, Wenjuan;
- Gao, Qiang;
- Li, Cong;
- He, Shaolong;
- Zhao, Lin;
- Zhang, Fengfeng;
- Zhang, Shenjin;
- Yang, Feng;
- Wang, Zhimin;
- Peng, Qinjun;
- Dai, Xi;
- Fang, Zhong;
- Xu, Zuyan;
- Chen, Chuangtian;
- Zhou, XJ
- et al.
Published Web Location
https://doi.org/10.1038/ncomms15512Abstract
The topological materials have attracted much attention for their unique electronic structure and peculiar physical properties. ZrTe5 has host a long-standing puzzle on its anomalous transport properties manifested by its unusual resistivity peak and the reversal of the charge carrier type. It is also predicted that single-layer ZrTe5 is a two-dimensional topological insulator and there is possibly a topological phase transition in bulk ZrTe5. Here we report high-resolution laser-based angle-resolved photoemission measurements on the electronic structure and its detailed temperature evolution of ZrTe5. Our results provide direct electronic evidence on the temperature-induced Lifshitz transition, which gives a natural understanding on underlying origin of the resistivity anomaly in ZrTe5. In addition, we observe one-dimensional-like electronic features from the edges of the cracked ZrTe5 samples. Our observations indicate that ZrTe5 is a weak topological insulator and it exhibits a tendency to become a strong topological insulator when the layer distance is reduced.
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