Tracking the photoinduced dynamics of a dark excitonic state in single-layer WS$_2$ via resonant Autler-Townes splitting (2503.18530v1)

Abstract: Excitons in a monolayer transition metal dichalcogenides (1L-TMD) are highly bound states characterized by a Rydberg-like spectrum of discrete energy levels. Within this spectrum, states with odd-parity are known as dark excitons because transitions to the ground state are forbidden by selection rules. This makes their stationary and transient characterization challenging using linear optical techniques. Here, we demonstrate that the dynamics of a 2p dark excitonic state in 1L-WS$_2$ can be directly retrieved by measuring the Autler-Townes splitting of bright states in a three-pulse experiment. The splitting of the bright 1s excitonic state, observed by detuning a mid-infrared control field across the 1s-2p transition, provides an accurate characterization of the 2p state, which is used here to reveal its dynamics following a sudden photoinjection of free carriers in the conduction band. We observe a qualitatively different dynamics of the 1s and 2p levels, which is indicative of symmetry-dependent screening and exciton-exciton interactions. These findings provide new insights into many-body effects in TMDs, offering potential avenues for advancing the next generation optoelectronics.