Litcius/Paper detail

Room temperature Mott metal–insulator transition in V2O3 compounds induced via strain-engineering

Pía Homm, Mariela Menghini, Jin Won Seo, S. Peters, Jean‐Pierre Locquet

2021APL Materials58 citationsDOIOpen Access PDF

Abstract

Vanadium sesquioxide (V2O3) is an archetypal Mott insulator in which the atomic positions and electron correlations change as temperature, pressure, and doping are varied, giving rise to different structural, magnetic, or electronic phase transitions. Remarkably, the isostructural Mott transition in Cr-doped V2O3 between paramagnetic metallic and insulating phase observed in bulk has been elusive in thin film compounds so far. Here, via continuous lattice deformations induced by heteroepitaxy, we demonstrate a room temperature Mott metal–insulator transition in 1.5% Cr-doped and pure V2O3 thin films. By means of a controlled epitaxial strain, not only the structure but also the intrinsic electronic and optical properties of the thin films are stabilized at different intermediate states between the metallic and insulating phases, inaccessible in bulk materials. This leads to films with unique features such as a colossal change in room temperature resistivity (ΔR/R up to 100 000%) and a broad range of optical constant values as consequence of a strain-modulated bandgap. We propose a new phase diagram for pure and Cr-doped V2O3 thin films with the engineered in-plane lattice constant as a tunable parameter. Our results demonstrate that controlling phase transitions in correlated systems by epitaxial strain offers a radical new approach to create the next generation of Mott devices.

Topics & Concepts

Materials scienceCondensed matter physicsMetal–insulator transitionMott insulatorLattice constantDopingThin filmBand gapMott transitionSesquioxideIsostructuralNanotechnologyMetalCrystallographyOptoelectronicsCrystal structureDiffractionOpticsMetallurgySuperconductivityPhysicsHubbard modelChemistryTransition Metal Oxide NanomaterialsZnO doping and propertiesMagnetic and transport properties of perovskites and related materials