ABSTRACT Correlated oxides such as VO 2 exhibit an electrically driven insulator–metal transition (IMT) that underlies their promise for neuromorphic and memory devices. Yet the IMT is not a uniform bulk process but a spatiotemporal phenomenon in which local heating nucleates filaments, contracts or dissolves them with the electric field, and couples to the environment. In this work, we directly image the VO 2 IMT dynamics by mid‐wave infrared, thermography synchronized with electrical transport, resolving device temperature with micrometer spatial and microsecond temporal resolution. At the single‐device level, we capture the full cycle of filament nucleation, contraction, and relaxation during current/voltage‐driven resistive switching. At the array level, we show that heat propagates across etched gaps with an effective length scale of ∼131 µm, enabling cooperative behaviors among electrically isolated devices. Short‐range distanced devices exhibit mutual filament attraction and sequential dissolution, while long‐range distanced devices differentiate into distinct roles: drivers that initiate switching, cooperative responders that undergo assisted self‐oscillations, and passive reporters that record the thermal field. These results reframe thermal crosstalk, long regarded as parasitic, as an intrinsic coupling channel and design principle for organizing collective switching behaviors, with direct implications for emergent circuit functionality in neuromorphic and unconventional computing architectures.
Qiu et al. (Wed,) studied this question.