Engineering topological flat bands in Γ-valley moiré systems with Ising-type SOC: twisted 1T-ZrS2 and 1T-SnSe2

Abstract

Twisted moiré superlattices hosting topological flat bands provide a platform to explore the interplay between topology and correlations. Here we investigate topological band structures in Γ-valley moiré systems based on 1T-ZrS2 and 1T-SnSe2. Using large-scale ab initio calculations and continuum modelling, we demonstrate that both materials exhibit an approximate spin-U(1) symmetry and host isolated topological moiré valence bands, including quantum spin Hall and high spin Chern states. By constructing a hierarchy of Γ-valley moiré continuum models, we show that isolated moiré bands carry a trivial C3 symmetry indicator when the low-energy physics is described by a single effective orbital and a single layer-hybridized branch, either bonding or antibonding. Topological bands therefore arise from inter-branch and/or inter-orbital coupling. Moreover, we determine interaction-driven phase diagrams using Hartree--Fock and exact diagonalization, finding various phases tunable by twist angle, interaction strength, and displacement field. We identify specific conditions under which fractional Chern insulators are favored. Together with previous work showing that the moiré conduction bands of 1T-ZrS2 and 1T-SnSe2 realize M-valley twisting and host quasi-one-dimensional physics, our results establish these systems as ideal platforms for strongly correlated moiré physics and provide a systematic framework for understanding topological band structures in Γ-valley moiré materials.