Tortuosity Engineering of Water Channels to Customized Water Supply for Enhancing Hydrogel Solar Evaporation

Abstract Hydrogel as a solar evaporator shows great potential in freshwater production. However, hydrogels often lead to an imbalance between solar energy input and water supply management due to their excessively high saturated water content. Thus, achieving a stable water‐energy‐balance in hydrogel evaporators remains challenging. Here, by tortuosity engineering designed water transport channels, a seamless high‐tortuosity/low‐tortuosity/high‐tortuosity structured hydrogel (SHLH structure hydrogel) evaporator is developed, which enables the hydrogel with customized water transport rate, leading to the controlled water supply at the evaporator interface. An excellent equilibrium between the photothermal conversion and water supply is established, and the maximum utilization of solar energy is realized, thereby achieving an excellent evaporation rate of 3.64 kg m –2 h –1 under one solar illumination. This tortuosity engineering controlled SHLH structured evaporator provides a novel strategy to attain water‐energy‐balance and expands new approaches for constructing hydrogel‐based evaporators with tailored water transportation capacity.