Localized interfacial activation effect within interconnected porous photothermal matrix to promote solar-driven water evaporation

Herein, a localized interfacial activation strategy is proposed to promote solar evaporation. Considering that surfactants can weaken water interaction but on the other hand block evaporation due to physical coverage, surfactant-like graphene oxide (GO) and polydopamine (PDA) are assembled to be an interconnected porous photothermal matrix (IPPM) via an acid-assembly method. Hence, the activation interface is physically localized at the micro-frame surface of IPPM (composed of an rGO frame and PDA with an outward-facing indole structure), which can effectively decrease the interaction energy of interfacial water molecules. Meanwhile, the interconnected water channels in the IPPM ensure adequate water supplementation for interfacial evaporation. Consequently, the IPPM not only displays a high performance of 2.2 kg m(-2) h(-1) under 1 sun irradiation, but in particular exhibits an unparalleled advantage with a flux of over 10 kg m(-2) h(-1) under concentrated irradiation below 5 sun. The present development takes a new step towards the practical application of solar evaporation in the future.

Automated summary

In this study, a localized interfacial activation strategy is proposed to enhance solar evaporation. By assembling surfactant-like graphene oxide (GO) and polydopamine (PDA) into an interconnected porous photothermal matrix (IPPM), the activation interface is physically localized at the micro-frame surface of IPPM, effectively reducing the interaction energy of interfacial water molecules. The IPPM exhibits high performance under both normal and concentrated sunlight, showing great potential for practical application in solar evaporation.