📝 SummarXiv

Abstract

The supermoir\'e lattice, arising from the interference of multiple moir\'e patterns, dramatically reshapes the electronic band structure by introducing new minibands and modifying band dispersion. Concurrently, strong electronic interactions within moir\'e flat bands lead to the emergence of various correlated states. However, the impact of the supermoir\'e lattice on the flat band systems with strong interactions remains largely unexplored. Here, we report the existence of the supermoir\'e lattice in the mirror-symmetry-broken twisted trilayer graphene, elucidating its role in generating mini-flat bands and mini-Dirac bands. Furthermore, we demonstrate interaction-induced symmetry-broken phases in the supermoir\'e mini-flat bands alongside the cascade of superconductor-insulator transitions enabled by the supermoir\'e lattice. Our work shows that robust superconductivity can exist in the mirror-symmetry-broken TTG and underscores the significance of the supermoir\'e lattice as an additional degree of freedom for tuning the electronic properties in twisted multilayer systems, sheds light on the correlated quantum phases such as superconductivity in the original moir\'e flat bands, and highlights the potential of using the supermoir\'e lattice to design and simulate novel quantum phases.