High‐Entropy Single‐Atom Evaporator: Collaborative Omnibearing Light Trapping Stereo Structures for Efficient Water Transport Dynamics

Abstract Achieving efficient photothermal evaporation requires a synergistic integration of thermal management, water transport dynamics, and light trapping—key elements often challenging to harmonize. Herein, A high‐entropy single‐atomic metal doped porous carbon (HESA) with ultra‐low metal content of 1.77 wt.% is designed as a new type of photothermal material through a green and convenient routine, which displays tunable hierarchical nano/micro/macro‐porous structure. By integrating molecular dynamics simulations with a 3D light capture structure, a HESA cone evaporator is prepared, utilizing only 3 wt.% of photothermal content. Under 1.0 sun illumination, the cone evaporator demonstrates an outstanding water evaporation rate of 2.86 kg m −2 h −1 and photothermal evaporation efficiency of 94.5%. Compared to conventional flat evaporators, the cone increases absorbed energy by 18% and enhances the evaporation rate by 58.7%. Molecular dynamics analyses reveal that the evaporator significantly improves water transfer kinetics, achieving an intermediate water content nearly twice that of pure water. Complementary COMSOL simulations further validate that the conical array structure enhances light absorption and optimizes water evaporation and diffusion. This meticulously designed evaporator leverages adaptive thermal and light management strategies, offering an effective solution to longstanding challenges in solar interfacial evaporation.