Room-Temperature Electron-Hole Liquid in Monolayer MoS2

The strong correlation of elementary particles or quasi-particles like electrons, phonons, and excitons may give rise to macroscopic quantum states with exotic functionalities such as superconductivity, Bose-Einstein condensation, Mott insulator, and electron-hole liquid. However, the macroscopic quantum states usually only exist at cryogenic temperatures, and this has significantly limited their prospect for practical applications and fundamental research. Here we demonstrate the formation of macroscopic state of strongly correlated excitons at room temperature in monolayer MoS2. Excitons typically behave like non- interacting free gas, but the strongly correlated state are liquid-like, i.e., electron-hole liquid (EHL) with degenerate electrons and holes bound by collective interactions. The EHL formation in MoS2 is evidenced by a first order transition in photoluminescence (PL) and is consistent with the previous experimental observation of EHL. It is also supported by our theoretical calculation based on well-established EHL models. The room-temperature EHL may provide a model system to open up unprecedented opportunities for the fundamental studies of many-interacting quantum physics. Additionally, the EHL features super- broadband emission (u003e 175 meV), high luminescence yield, super-long charge lifetime (two orders of magnitude longer than excitons), and an ultimate density of excited charges (4.0x1013 cm-2). It may enable the development of novel photonic devices, such as extremely high-power and super-broadband lasers or LEDs.