Discrete Interactions between a few Interlayer Excitons Trapped at a MoSe2-WSe2 Heterointerface

Abstract

Interlayer excitons (IXs) in hetero-bilayers of transition metal dichalcogenides (TMDs) represent an exciting emergent class of long-lived dipolar composite bosons in an atomically thin, near-ideal two-dimensional (2D) system. The long-range interactions that arise from the spatial separation of electrons and holes can give rise to novel quantum, as well as classical multi-particle correlation effects. In order to acquire a detailed understanding of the possible many-body effects, the fundamental interactions between individual IXs have to be studied. Here, we trap a tunable number of dipolar within a nanoscale confinement potential induced by placing a MoSe2-WSe2 hetero-bilayer (HBL) onto an array of SiO2 nanopillars. We control the mean occupation of the IX trap via the optical excitation level and observe discrete sharp-line emission from different configurations of interacting IXs. We identify these features as different multiparticle states with NIX1-5 via their power dependencies and directly measure the hierarchy of dipolar and exchange interactions as NIX increases. The interlayer biexciton (NIX=2) is found to be an emission doublet that is blue-shifted from the single exciton by E=(8.40.6) meV and split by 2J=(1.20.5) meV. The blueshift is even more pronounced for triexcitons ((12.40.4) meV), quadexcitons ((15.50.6) meV) and quintexcitons ((18.20.8) meV). These values are shown to be mutually consistent with numerical modelling of dipolar excitons confined to a harmonic trapping potential having a confinement lengthscale in the range ≈ 3 nm. Our results contribute to the understanding of interactions between IXs in TMD HBLs at the discrete limit of only a few excitations and represent a key step towards exploring quantum correlations between them.