Enhanced Interfacial Solar Evaporation through Formation of Micro‐Meniscuses and Microdroplets to Reduce Evaporation Enthalpy

Interfacial solar water evaporation, a promising way to address water shortages and water pollution, has attracted increasing attention. However, low evaporation rates limit its practical applications. Reducing evaporation enthalpy is one of the most efficient ways to improve the evaporation rate. In this study, micro‐meniscuses and microdroplets (MMDs) are found and observed on the surface of the polypyrrole nanoarrays on hydrophilic carbon cloth. The MMDs can reduce the evaporation enthalpy of the system, thus resulting in a high evaporation rate of 2.16 kg m−2 h−1 in pure water under 1 sun. Dynamic calculations imply that the evaporation rate of MMDs is approximately at least 1.7 times and 1.8 times that of a flat liquid film, respectively. Under 1 sun, the evaporators with MMDs enable stable evaporation in continuous 72 h in 10.0 wt% NaCl solution, simulated seawater, and actual wastewater, with an evaporation rate of 1.86, 1.99, and 1.82 kg m−2 h−1, respectively. As far as it is known, these evaporation rates are the highest reported values for the 2D interfacial solar evaporator in high‐salinity brine or wastewater. It is believed that this work provided a novel pathway for designing an evaporator with low evaporation enthalpy and high evaporation performance. This study proposes a novel strategy for reducing the evaporation enthalpy by constructing micro‐meniscuses and microdroplets. A high evaporation rate of 2.16 kg m−2 h−1 is obtained in pure water under 1 sun. Combining this strategy with the flowing salt‐rejecting structure enables a stable evaporation rate in 10.0 wt% NaCl solution and simulated seawater.