Zemin Pan, Wenqi Xiong, Jiaqi Dai, Yunhua Wang, Tao Jian, Xingxia Cui, Jinghao Deng, Xiaoyu Lin, Zhengbo Cheng, Yusong Bai, Chao Zhu, Da Huo, Geng Li, Min Feng, Jun He, Wei Ji, Shengjun Yuan, Fengcheng Wu, Chendong Zhang, and Hong-Jun Gao
Abstract:
Flat electronic bands near the Fermi level provide a fertile playground for realizing interaction-driven correlated physics. To date, related experiments have mostly been limited to engineered multilayer systems (e.g., moiré systems). Herein, we report an experimental realization of nearly flat bands across the Fermi level in monolayer MoTe2-x by fabricating a uniformly ordered mirror twin boundary superlattice (corresponding to a stoichiometry of MoTe56/33). The kagome flat bands are discovered by combining scanning tunnelling microscopy and theoretical calculations. The partial filling nature of flat bands yields a correlated insulating state exhibiting a hard gap as large as 15 meV. Moreover, we observe pronounced responses of the correlated states to magnetic fields, providing evidence for a spin-polarized ground state. Our work introduces a monolayer platform that manifests strong correlation effects arising from flattened electronic bands.
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