Excitonic Phase Transitions in MoSe2/WSe2 Heterobilayers

Homo- or hetero-junctions of two-dimensional (2D) materials provide unprecedented opportunities for the exploration of quantum phases. Among them, heterobilayers of transition metal dichalcogenides (TMDCs) are attractive because they not only inherit the strong Coulomb correlation and valley pseudo spin from constituent monolayers, but also yield long-lived and charge separated interlayer excitons to facilitate exciton condensation. Moreover, the great band tunability by interlayer twist angle opens the door to a rich spectrum of phenomena, such as moir\'e exciton lattices, topological mosaics, and correlated many-body physics associated with band flattening. Here we explore electronic phase transitions of interlayer excitons in the MoSe2/WSe2 heterobilayer. We show direct evidence for the Mott transition from an insulating exciton gas to a conducting plasma when excitation density (n_ex) is increased above the Mott density, n_Mott ~ 3x10^12 cm^-2. The upper limit in photo-generated density of charge separated electron/hole plasma is over 10^14 cm^-2, which is within the range for superconductivity demonstrated before in gate-doped TMDCs. We use time and space resolved photoluminescence imaging to map excitonic phase transitions and show that diffusivity is a strong function of n_ex. As n_ex is lowered, the diffusion coefficient decreases by ~3 orders of magnitude in the plasma phase, becomes nearly constant in the exciton phase, but further decreases again by one order of magnitude as nex approaches ~ 10^11 cm^-2. The latter is consistent with interlayer exciton trapping in periodic potential wells on the moir\'e landscape. These findings reveal fundamental bounds for potentially achieving different interlayer exciton phases, such as moir\'e exciton lattices, exciton condensates, conducting electron/hole plasmas, and superconductors.