Robust Super-Moir\'e in Large Angle Single-Twist Bilayers
Abstract
Forming long wavelength moir\'e superlattices (MSL) at small-angle twist van der Waals (vdW) bilayers has been a key approach to creating moir\'e flat bands. The small-angle twist, however, leads to strong lattice reconstruction, causing domain walls and moir\'e disorders, which pose considerable challenges in engineering such platforms. At large twist angles, the rigid lattices render a more robust, but shorter wavelength MSL, making it difficult to engineer flat bands. Here, we depict a novel approach to tailoring robust super-moir\'e (SM) structures that combines the advantages of both small-twist and large-twist transition metal dichalcogenides (TMDs) bilayers using only a single twist angle near a commensurate angle. Structurally, we unveil the spontaneous formation of a periodic arrangement of three inequivalent commensurate moir\'e (CM) stacking, where the angle deviation from the commensurate angle can tune the periodicity. Electronically, we reveal a large set of van Hove singularities (VHSs) that indicate strong band hybridization, leading to flat bands near the valence band maximum. Our study paves the way for a new platform of robust SM bilayers with structural rigidity and controllable wavelength, extending the investigation of the interplay among band topology, quantum geometry, and moir\'e superconductivity to the large twist angle regime.
Keywords
Cite
@article{arxiv.2502.12335,
title = {Robust Super-Moir\'e in Large Angle Single-Twist Bilayers},
author = {Yanxing Li and Chuqiao Shi and Fan Zhang and Xiaohui Liu and Yuan Xue and Viet-Anh Ha and Qiang Gao and Chengye Dong and Yu-chuan Lin and Luke N Holtzman and Nicolas Morales-Durán and Hyunsue Kim and Yi Jiang and Madisen Holbrook and James Hone and Katayun Barmak and Joshua Robinson and Xiaoqin Li and Feliciano Giustino and Eslam Khalaf and Yimo Han and Chih-Kang Shih},
journal= {arXiv preprint arXiv:2502.12335},
year = {2025}
}