Directly visualizing the momentum forbidden dark excitons and their dynamics in atomically thin semiconductors
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Resolving the momentum degree of freedom of excitons - electron-hole pairs bound by the Coulomb attraction in a photoexcited semiconductor, has remained a largely elusive goal for decades. In atomically thin semiconductors, such a capability could probe the momentum forbidden dark excitons, which critically impact proposed opto-electronic technologies, but are not directly accessible via optical techniques. Here, we probe the momentum-state of excitons in a WSe2 monolayer by photoemitting their constituent electrons, and resolving them in time, momentum and energy. We obtain a direct visual of the momentum forbidden dark excitons, and study their properties, including their near-degeneracy with bright excitons and their formation pathways in the energy-momentum landscape. These dark excitons dominate the excited state distribution - a surprising finding that highlights their importance in atomically thin semiconductors.
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Excitonic Mott transition without population inversion
Excitonic resonance quenches ultrafast without optical gain in monolayer TMD, showing the Mott transition proceeds via nonthermal carriers and nonequilibrium screening instead of population inversion.
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