Optical detection of small polarons in vanadium dioxide and their critical role in mediating metal-insulator transition

In the pursuit of advanced photoelectric devices, researchers have uncovered near room-temperature metal-insulator transitions (MIT) in non-volatile VO2. Although theoretical investigations propose that polaron dynamics mediate the MIT, direct experimental evidence remains scarce. In this study, we present direct evidence of the polaron state in insulating VO2 through high-resolution spectroscopic ellipsometry measurements and first-principles calculations. We demonstrate that polaron dynamics play a complementary role in facilitating Peierls and Mott transitions to contribute to the MIT processes. Moreover, our observations and characterizations of conventional metallic and correlated plasmons in the respective phases of the VO2 film provide valuable insights into their electron structures. This study provides an understanding of the MIT mechanism in correlated systems and highlights how polarons, lattice distortions and electron correlations facilitate the phase transition processes in strongly-correlated systems, while further inspiring the development of new device functionalities.