Moir\'e Engineering and Topological Flat Bands in Twisted Orbital-Active Bilayers

Abstract

Topological flat bands at the Fermi level offer a promising platform to study a variety of intriguing correlated phase of matter. Here we present band engineering in the twisted orbital-active bilayers with spin-orbit coupling. The symmetry constraints on the interlayer coupling that determines the effective potential for low-energy physics of moir\'e electrons are exhaustively derived for two-dimensional point groups. We find the line graph or biparticle sublattice of moir\'e pattern emerge with a minimal C3 symmetry, which exhibit isolated electronic flat bands with nontrivial topology. The band flatness is insensitive to the twist angle since they come from the interference effect. Armed with this guiding principle, we predict that twisted bilayers of 2H-PbS2 and CdS realize the salient physics to engineer two-dimensional topological quantum phases. At small twist angles, PbS2 heterostructures give rise to an emergent moir\'e Kagom\'e lattice, while CdS heterostructures lead to an emergent moir\'e honeycomb lattice, and both of them host moir\'e quantum spin Hall insulators with almost flat topological bands. We further study superconductivity of these two systems with local attractive interactions. The superfluid weight and Berezinskii-Kosterlitz-Thouless temperature are determined by multiband processes and quantum geometry of the band in the flat-band limit when the pairing potential exceeds the band width. Our results demonstrate twisted bilayers with multi-orbitals as a promising tunable platform to realize correlated topological phases.