Abstract
The increasing scarcity of freshwater resources has driven the rapid emergence of solar-driven interfacial evaporators (SDIEs) as a sustainable approach to harvest fresh water by utilizing solar energy. Lignocellulosic biomass, featuring natural abundance, excellent renewability, unique natural structures, and superior biodegradability compared to the synthetic polymers, is highly attractive for constructing solar steam generators. This review aims to offer an innovative and in-depth insight into designing and optimizing high-performance integrated solar interfacial evaporators derived from renewable lignocellulosic biomass. First, the structural characteristics of lignocellulosic biomass are briefly introduced, serving as photothermal layer or supporting substrates in SDIEs. Secondly, the fabrication methods and processing technologies of lignocellulosic biomass-based evaporators are summarized from the perspective of photothermal layer and supporting substrates. Next, the most recent advances of regulation and optimization strategies are proposed to improve evaporation efficiency. Subsequently, this review summarizes the diverse functionalities of SDIEs, including desalination, power generation, wastewater treatment and antimicrobial, atmospheric water harvesting, and photocatalytic hydrogen production. Finally, the challenges in this field and outlook on the future development are discussed, which are anticipated to provide new opportunities for the advancement of lignocellulosic biomass-based SDIEs.