Nanoengineering‐Enhanced Capillary Cooling Achieves Sustained Thermal Protection for Ultra‐High Heat Flux and Temperature

Abstract: Extreme thermal conditions with heat flux densities exceeding 1 MW·m−2 or temperatures reaching up to 1000 °C are prevalent in various situations. However, the ability of thermal protection either depends on specialized materials or is currently limited with existing cooling schemes. Herein, we propose an innovative cooling scheme that relies on evaporation‐driven capillary flow enhanced by nanoengineering‐designed porous structures with common materials. Experimentally‐obtained capillary flow cooling curve id… Show more