- Yang, Guanhua;
- Shao, Yan;
- Niu, Jiebin;
- Ma, Xiaolei;
- Lu, Congyan;
- Wei, Wei;
- Chuai, Xichen;
- Wang, Jiawei;
- Cao, Jingchen;
- Huang, Hao;
- Xu, Guangwei;
- Shi, Xuewen;
- Ji, Zhuoyu;
- Lu, Nianduan;
- Geng, Di;
- Qi, Jing;
- Cao, Yun;
- Liu, Zhongliu;
- Liu, Liwei;
- Huang, Yuan;
- Liao, Lei;
- Dang, Weiqi;
- Zhang, Zhengwei;
- Liu, Yuan;
- Duan, Xidong;
- Chen, Jiezhi;
- Fan, Zhiqiang;
- Jiang, Xiangwei;
- Wang, Yeliang;
- Li, Ling;
- Gao, Hong-Jun;
- Duan, Xiangfeng;
- Liu, Ming
In atomically-thin two-dimensional (2D) semiconductors, the nonuniformity in current flow due to its edge states may alter and even dictate the charge transport properties of the entire device. However, the influence of the edge states on electrical transport in 2D materials has not been sufficiently explored to date. Here, we systematically quantify the edge state contribution to electrical transport in monolayer MoS2/WSe2 field-effect transistors, revealing that the charge transport at low temperature is dominated by the edge conduction with the nonlinear behavior. The metallic edge states are revealed by scanning probe microscopy, scanning Kelvin probe force microscopy and first-principle calculations. Further analyses demonstrate that the edge-state dominated nonlinear transport shows a universal power-law scaling relationship with both temperature and bias voltage, which can be well explained by the 1D Luttinger liquid theory. These findings demonstrate the Luttinger liquid behavior in 2D materials and offer important insights into designing 2D electronics.