An Electrically Tuned Solid-State Thermal Memory Based on Metal-Insulator Transition of Single-Crystalline VO2 Nanobeams

A solid‐state thermal memory that can store and retain thermal information with temperature states as input and output is demonstrated experimentally. A single‐crystal VO2 nanobeam is used, undergoing a metal–insulator transition at ∼340 K, to obtain a nonlinear and hysteresis response in temperature. It is shown that the application of a voltage bias can substantially tune the characteristics of the thermal memory, to an extent that the heat conduction can be increased ∼60%, and the output HIGH/LOW temperature difference can be amplified over two orders of magnitude compared to an unbiased device. The realization of a solid‐state thermal memory combined with an effective electrical control thus allows the development of practical thermal devices for nano‐ to macroscale thermal management. A solid‐state thermal memory that can store and retain thermal information with temperature states was demonstrated based on metal–insulator transition of VO2 nanobeams. We show that the application of a voltage bias can substantially tune the characteristics of the thermal memory, to an extent that the output HIGH/LOW temperature difference can be amplified over two orders of magnitude.