Unveiling valley lifetimes of free charge carriers in monolayer WSe$_2$.

Two-dimensional transition metal dichalcogenides (TMDs) offer the possibility to address the electron's valley degree of freedom making them interesting for valley-based electronics, so-called valleytronics. The device performance of potential valleytronic applications largely depends on the valley lifetimes of free charge carriers. Here, we report on nanosecond long, gate-dependent valley lifetimes of free charge carriers in WSe$_2$, unambiguously identified by the combination of time-resolved Kerr rotation (TRKR) and electrical transport measurements. While the valley polarization increases when tuning the Fermi level into the conduction or valence band, there is a strong decrease of the respective valley lifetime consistent with both electron-phonon and spin-orbit scattering. The longest lifetimes are seen for spin-polarized bound excitons in the band gap region. We explain our findings via two distinct, Fermi level-dependent scattering channels of optically excited, valley polarized bright trions either via dark or bound states. By electrostatic gating we demonstrate that WSe$_2$ can be tuned to be either an ideal host for long-lived localized spin states or allow for nanosecond valley lifetimes of free charge carriers (> 10 ns) explaining the huge variation in previously reported lifetimes extracted from TRKR.