VOx Phase Mixture of Reduced Single Crystalline V2O5: VO2 Resistive Switching

The strongly correlated electron material, vanadium dioxide (VO2), has seen considerable attention and research application in metal-oxide electronics due to its metal-to-insulator transition close to room temperature. Vacuum annealing a V2O5(010) single crystal results in Wadsley phases (VnO2n+1, n > 1) and VO2. The resistance changes by a factor of 20 at 342 K, corresponding to the metal-to-insulator phase transition of VO2. Macroscopic voltage-current measurements with a probe separation on the millimetre scale result in Joule heating-induced resistive switching at extremely low voltages of under a volt. This can reduce the hysteresis and facilitate low temperature operation of VO2 devices, of potential benefit for switching speed and device stability. This is correlated to the low resistance of the system at temperatures below the transition. High-resolution transmission electron microscopy measurements reveal a complex structural relationship between V2O5, VO2 and V6O13 crystallites. Percolation paths incorporating both VO2 and metallic V6O13 are revealed, which can reduce the resistance below the transition and result in exceptionally low voltage resistive switching.

Automated summary

Vanadium dioxide (VO2), a strongly correlated electron material, has attracted significant attention in metal-oxide electronics due to its metal-to-insulator transition near room temperature. Vacuum annealing of V2O5(010) single crystal results in Wadsley phases and VO2. Macroscopic voltage-current measurements reveal resistive switching at extremely low voltages due to Joule heating. High-resolution transmission electron microscopy measurements show a complex structural relationship between V2O5, VO2, and V6O13 crystallites.