Abstract
Nowadays, freshwater shortage, energy crisis and environmental pollution are the three major threats to human beings. Herein, we develop a photothermal material based on bagasse for solar steam generation to relieve freshwater crisis and mitigate environmental pollution caused by bio-waste. The mainly functional part of the solar driven steam generator in this paper is bagasse-based photothermal aerogel (B-PTA), which composes of carbonized bagasse (CB) and bagasse-derived cellulose fiber (BDCF). The B-PTA with CB can effectively absorb solar (~95%) and has an excellent light-to-heat ability. The B-PTA with DBCF has super-hydrophilicity, water transport and retention ability. Depending on the excellent light absorption and 3D water passageway, the B-PTA gives a water evaporation rate of 1.36 kg m–2 h–1, and can achieve a photothermal conversion efficiency of 77.34% under 1-sun illumination (1 kW m–2). The B-PTA has excellent stability that the efficiency without significant decrease after 20 cycles. In addition, the B-PTA can effectively desalt seawater and purify dye wastewater with natural sunlight. Therefore, turning bio-waste into valuable photothermal material for solar steam generation is possible. Due to the merits of low cost, scalability, environmental friendliness, B-PTA has the potential for real-world water purification.
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