Coherent light emission of exciton-polaritons in an atomically thin crystal at room temperature

The emergence of spatial and temporal coherence in optical light-fields emitted from solid-state systems is a fundamental phenomenon, rooting in a plethora of microscopic processes and it is intrinsically aligned with the control of light-matter coupling. Optical coherence is canonical for lasing systems. It also emerges in the superradiance of multiple, phase-locked emitters. More recently, coherence and long-range order have been investigated in bosonic condensates of thermalized light, as well as in exciton-polaritons driven to a ground state via stimulated scattering. Here, we experimentally show that the interaction between cavity photons with an atomically thin layer of material is sufficient to create strong light-matter coupling and coherent light emission at ambient conditions. Our experiments are conducted on a microcavity embedding a monolayer of WSe$_2$. We measure spatial and temporal coherence of the emitted light. The coherence build-up is accompanied by a threshold-like behaviour of the emitted light intensity, which is a fingerprint of a polariton laser effect. Our findings are of high application relevance, as they confirm the possibility to use atomically thin crystals as simple and versatile components of coherent light-sources at room temperature.