MML Seminar - Strongly correlated physics in twisted bilayer transition metal dichalcogenides

The investigation of twisted bilayer graphene has opened a “twistronics era”,providing unprecedented tunability for solid-state systems and an excellent platform forstrongly correlated quantum phases and their transitions. While twisted bilayer graphene requires involved multi-band descriptions, twisted bilayer transition metal dichalcogenides are simpler. In this talk, I will introduce some of our theoretical works as well as have a brief review of some of the most recent experimental progress.We studied two cases of twisted bilayer transition metal dichalcogenides: (1) effectivetriangular systems and (2) effective honeycomb systems. For triangular systems, we studypossible magnetic orders and spin liquids at half-filling; we also study the magnetic ordersat the van Hove filling, providing an explanation for the absence of the predicted quantumanomalous Hall effect in experiments. For honeycomb systems, we numerically reveal integer and fractional quantum anomalous Hall effects, providing theoretical support for the ground-breaking experimental discovery of fractional quantum anomalous Hall effects.