Ultrafast doublon dynamics in photo-excited 1T-TaS$_2$

Strongly correlated systems exhibit intriguing properties, caused by intertwined microscopic interactions that are hard to disentangle in equilibrium. Here, we used non-equilibrium time-resolved photoemission spectroscopy to isolate and access fundamental Mott-physics in the quasi-two-dimensional transition-metal dichalcogenide 1T-TaS$_2$. Doublon-hole recombination is found to occur on time scales as short as the electronic hopping cycle $\hbar/J$. Despite strong electron-phonon interaction, the dynamics on short time scales can be explained by means of purely electronic effects within a single-band Hubbard model in the absence of additional, e.g. bosonic, coupling channels. We find that hole-doping governs the relaxation dynamics on ultrashort time scales, which opens the way for macroscopic control of ultrafast processes in such systems.