Enhanced multiexciton formation by an electron-hole plasma in 2D semiconductors.

Multiexcitons in monolayer WSe2 exhibit a suite of optoelectronic phenomena that are unique to those of their single exciton constituents. Here, photoluminescence action spectroscopy shows that multiexciton formation is enhanced with increasing optical excitation energy. This enhancement is attributed to the multiexciton formation processes from an electron-hole plasma and results in over 300% more multiexciton emission than at lower excitation energies at 4 K. The energetic onset of the enhancement coincides with the quasiparticle bandgap, corroborating the role of the electron-hole plasma, and the enhancement diminishes with increasing temperature. The results reveal that the strong interactions responsible for ultrafast exciton formation also affect multiexciton phenomena, and both multiexciton and single exciton states play significant roles in plasma thermalization in 2D semiconductors.