Excitons in fractionally-filled moir\'e superlattices

Abstract

Long-range Coulomb forces give rise to correlated insulating states when charge particles populate a moir\'e superlattice at certain fractional filling factors. Such behavior is characterized by a broken translation symmetry wherein particles spontaneously form a Wigner crystal. Focusing on the experimental findings of Xu et al. [Nature 587, 214 (2020)], we present a theory that captures the correlated insulating state of a fractionally-filled moir\'e superlattice through the energy shift and change in oscillator strength of the exciton absorption resonance. The theory shows that the experimental findings can only be supported if the electrons reside in a charge-ordered state (i.e., electrons are not randomly distributed among the sites of the moir\'e superlattice). Furthermore, we explain why the energy shifts of exciton resonances are qualitatively different in cases that the superlattice is nearly empty compared with a superlattice whose sites are doubly occupied.