Fine structure of negatively charged and neutral excitons in monolayer MoS2

Abstract

We present experimental and theoretical results on the high-quality single-layer MoS2 which reveal the fine structure of charged excitons, i.e., trions. In the emission spectra we resolve and identify two trion peaks, T1 and T2, resembling the pair of singlet and triplet trion peaks (TS and TT) in tungsten-based materials. However, in polarization-dependent photoluminescence measurements we identify these peaks as novel intra- and inter-valley singlet trions, constituting the trion fine structure distinct from that already known in bright and dark 2D materials with large conduction-band splitting induced by the spin-orbit coupling. We show that the trion energy splitting in MoS2 is a sensitive probe of inter- and intra-valley carrier interaction. With additional support from theory we claim that the existence of these singlet trions combined with an anomalous excitonic g-factor and the characteristic temperature dependence of the emission spectra together suggest that monolayer MoS2 has a dark excitonic ground state, despite having "bright" single-particle arrangement of spin-polarized conduction bands.