Nearly flat Chern band in periodically strained monolayer and bilayer graphene
Xiaohan Wan, Siddhartha Sarkar, Kai Sun, Shi‐Zeng Lin
Abstract
The flat band is a key ingredient for the realization of interesting quantum states for functionalities. In this paper, we investigate the conditions for the flat band in both monolayer and bilayer graphene under periodic strain. We find topological nearly flat bands with homogeneous distribution of Berry curvature in both systems. The quantum metric of the nearly flat band closely resembles that for Landau levels. For monolayer graphene, the strain field can be regarded as an effective gauge field, while for Bernal-stacked ($\mathit{AB}$-stacked) bilayer graphene, its role is beyond the description of a gauge field. We also provide an understanding of the origin of the nearly flat band in monolayer graphene in terms of the Jackiw-Rebbi model for Dirac fermions with sign-changing mass. In this paper, we suggest strained graphene as a promising platform for strongly correlated quantum states.