Abstract
Temperature-dependent magnetotransport measurements in magnetic fields of up to 12 T were performed on thin-film vanadium dioxide $({\text{VO}}_{2})$ across the metal-insulator transition (MIT). The Hall carrier density increases by 4 orders of magnitude at the MIT and accounts almost entirely for the resistance change. The Hall mobility varies little across the MIT and remains low, $\ensuremath{\sim}0.1\text{ }{\text{cm}}^{2}/\text{V}\text{ }\text{sec}$. Electrons are found to be the major carriers on both sides of the MIT. Small positive magnetoresistance in the semiconducting phase is measured.
Highlights
Vanadium dioxide is being actively investigated due to its potential in switching devices as well as fundamental scientific interest in understanding correlated electron systems
Temperature dependent magneto-transport measurements in magnetic fields of up to 12 Tesla were performed on thin film vanadium dioxide (VO2) across the metal-insulator transition (MIT)
Experiments by Cavalleri et al based on ultrafast spectroscopy provided evidence for the bandlike character of the low-T insulator and suggested that the atomic arrangement of the high-T rutile unit cell is necessary for the formation of the metallic phase of VO2 [6]
Summary
Vanadium dioxide is being actively investigated due to its potential in switching devices as well as fundamental scientific interest in understanding correlated electron systems. “Hall Carrier Density and Magnetoresistance Measurements in Thin-Film Vanadium Dioxide across the Metal-Insulator Transition.” Physical Review B 79 (15). Hall carrier density and magnetoresistance measurements in thin film vanadium dioxide across the metal-insulator transition
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