Mott insulator state in a van der Waals flat-band compound

When many-body effects dominate over the kinetic energy of electrons, they will lead to exotic quantum phenomena, such as the fractional quantum Hall effect, unconventional superconductivity, Mott insulator, quantum spin liquid, ferromagnetism, heavy fermion behavior and so on. Flat-band systems, in which the kinetic energy is strongly quenched, are promising for realizing many-body quantum phases, such as the Mott-like insulator states and unconventional superconductivity associated with the flat bands emerging in twisted bilayer graphene. In this work, we have discovered a room-temperature Mott insulator state, which is derived from a half-filled flat band in a van der Waals compound Nb3Cl8. Since the half-filled flat band is well separated from the other bands, the Mott insulator state in Nb3Cl8 is a straightforward realization of the celebrated single-band Hubbard model. Our discovery provides an intriguing platform for studying the fundamental physics of Mott insulator, and paves the way for more correlated electronic states and Mott insulator-based devices by taking advantage of the high tunability of the electronic states of two-dimensional materials.