Brightened emission of dark trions in transition metal dichalcogenide monolayers

The optical emission spectra of semiconducting transition metal dichalcogenide monolayers highlight fascinating recombination processes of charged excitons (trions). When charge-tunable $\mathrm{WS}{\mathrm{e}}_{2}$ monolayers are moderately doped with electrons, a strong luminescence peak emerges just below the well-understood spectral lines associated with the recombination of negatively charged bright and dark trions. Despite previous investigations, its origin remains elusive. Here, we demonstrate that this luminescence peak is the result of electron-electron assisted recombination that brightens the dark trion emission. Supporting evidence for this second-order recombination process comes from identifying the brightened emission of positively charged dark trions when the monolayer is electrostatically doped with holes. Remarkably, the discovered hole-hole assisted luminescence peak emerges in the near-infrared, about 500 meV below the well-studied spectral region of excitons and trions. In magnetophotoluminescence experiments, we find that the $g$-factor of this new transition ($g=+4$) has an opposite sign compared to the well-known $g$-factor of neutral or charged excitons. This allows us to propose a mechanism of brightening of the positively charged dark trion involving the \ensuremath{\Gamma} valley of the valence band.