Metal-insulator transition in transition metal dichalcogenide heterobilayer moiré superlattices
Nicolás Morales-Durán, A. H. MacDonald, Paweł Potasz
Abstract
Moir\'e superlattices formed in two-dimensional semiconductor heterobilayers provide a new realization of Hubbard model physics in which the number of electrons per effective atom can be tuned at will. We report on an exact diagonalization study of the electronic properties of half-filled narrow moir\'e bands in which correlation strengths are varied by changing twist angles or interaction strengths. We construct a phase diagram for the bilayer, identifying where the metal-insulator phase transition occurs, estimating the sizes of the charge gaps in the insulating phase, and commenting on the nature of the transition and the importance of subdominant interaction parameters.
Topics & Concepts
SuperlatticeCondensed matter physicsMoiré patternMaterials sciencePhase diagramSemiconductorElectronTransition metalPhase transitionMetal–insulator transitionHubbard modelInsulator (electricity)Phase (matter)MetalPhysicsSuperconductivityChemistryQuantum mechanicsOpticsOptoelectronicsBiochemistryCatalysisMetallurgy2D Materials and ApplicationsZnO doping and propertiesPerovskite Materials and Applications