Two-Dimensional Moir\'e Polaronic Electron Crystals

Realizing quantum phases of electrons with high critical temperatures (Tc) has been one of the most important goals in quantum materials research, as exemplified by the longstanding and sometimes contentious quest for high Tc superconductors. Recently, 2D moir\'e materials have emerged as the most versatile platform for the realization of a broad range of quantum phases. These quantum phases are commonly observed at cryogenic temperatures, but a few of them exhibit sufficiently high Tc, e.g., ~ 150 K for Mott insulator states in transition metal dichalcogenide (TMD) moir\'e interfaces. Here, we explore the origins of the stability of correlated states in WSe2/WS2 moir\'e superlattices by measuring the time scales of melting and their temperature dependences. Using exciton sensing and pump-probe reflectance spectroscopy, we find that ultrafast electronic excitation leads to melting of the Mott states on a time scale of 3.3 ps (at T = 11 K), which is approximately five times longer than that predicted from the charge hopping integral between moir\'e unit cells. We further find that the melting rates are thermally activated, with activation energies of Ea = 18 meV and 13 meV for the correlated states with one and two holes (v = -1 and -2) per moir\'e unit cell, respectively, suggesting significant electron-phonon coupling. The overall temperature dependences in the exciton oscillator strength, a proxy to the order parameter for the correlated states, gives estimates of Tc in agreement with the extracted Ea. Density functional theory (DFT) calculations on the moir\'e scale confirm polaron formation in the v = -1 Mott state and predict a hole polaron binding energy of 16 meV, in agreement with experiment. These findings suggest a close interplay of electron-electron and electron-phonon interactions in the formation of polaronic Mott insulators at TMD moir\'e interfaces.