Unconventional correlated insulator in CrOCl-interfaced Bernal bilayer graphene

Kaining Yang; Xiang Gao; Yaning Wang; Tongyao Zhang; Yuchen Gao; Xin Lu; Shihao Zhang; Jianpeng Liu; Pingfan Gu; Zhaoping Luo; Runjie Zheng; Shimin Cao; Hanwen Wang; Xingdan Sun; Kenji Watanabe; Takashi Taniguchi; Xiuyan Li; Jing Zhang; Xi Dai; Jian-Hao Chen; Yu Ye; Zheng Han

論文 Unconventional correlated insulator in CrOCl-interfaced Bernal bilayer graphene

Kaining Yang ; Xiang Gao ; Yaning Wang ; Tongyao Zhang ; Yuchen Gao ; Xin Lu ; Shihao Zhang ; Jianpeng Liu ; Pingfan Gu ; Zhaoping Luo ; Runjie Zheng ; Shimin Cao ; Hanwen Wang ; Xingdan Sun ; Kenji Watanabe (National Institute for Materials Science) ; Takashi Taniguchi (National Institute for Materials Science) ; Xiuyan Li ; Jing Zhang ; Xi Dai ; Jian-Hao Chen ; Yu Ye ; Zheng Han

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Kaining Yang, Xiang Gao, Yaning Wang, Tongyao Zhang, Yuchen Gao, Xin Lu, Shihao Zhang, Jianpeng Liu, Pingfan Gu, Zhaoping Luo, Runjie Zheng, Shimin Cao, Hanwen Wang, Xingdan Sun, Kenji Watanabe, Takashi Taniguchi, Xiuyan Li, Jing Zhang, Xi Dai, Jian-Hao Chen, Yu Ye, Zheng Han. Unconventional correlated insulator in CrOCl-interfaced Bernal bilayer graphene. Nature Communications. 2023, 14 (1), 2136.

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(abstract)

For two decades, two-dimensional carbon species, including graphene, have been the core of research in pursuing next-generation logic applications beyond the silicon technology. Yet the opening of a gap in a controllable range of doping, whilst keeping high conductance outside of this gapped state, has remained a grand challenge in them thus far. Here we show that, by bringing Bernal-stacked bilayer graphene in contact with an anti-ferromagnetic insulator CrOCl, a strong insulating behavior is observed in a wide range of positive total electron doping ntot and effective displacement field Deff at low temperatures. Transport measurements further prove that such an insulating phase can be well described by the picture of an inter-layer excitonic state in bilayer graphene owing to electron-hole interactions. The consequential over 1 GΩ excitonic insulator can be readily killed by tuning Deff and/or ntot, and the system recovers to a high mobility graphene with a sheet resistance of less than 100 Ω. It thus yields transistors with "ON-OFF" ratios reaching 10^7, and a CMOS-like graphene logic inverter is demonstrated. Our findings of the robust insulating phase in bilayer graphene may be a leap forward to fertilize the future carbon computing.

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