Hyperstable and compressible plant fibers/chitosan aerogel as portable solar evaporator

Solar interfacial evaporation is an effective zero-energy method for seawater desalination, and solar evaporator is the key component in this evaporation system. Despite a great deal of solar evaporators have been reported, the poor portability of large-scale evaporators as well as high costs and materials toxicity still restrict their applications. In this work, a portable solar evaporator was constructed with low-cost plant fibers from papermaking pulp, using a facile method in absence of any toxic cross-linkers and solvents. The evaporator exhibited excellent stability and flexibility, and endured tremendous and repeated compression over 100 times. A large-scale evaporator could be compressed to reduce storage space by 78%, which would be portable for individuals. The evaporator presented a high evaporation rate of 1.38 kg m(-2)h(-1), and solar-to-vapour conversion efficiency of 84.27% under one sun irradiation. The portable solar evaporator was salt-rejecting, and worked well under harsh conditions of high salinity and different pH values. The entire material cost of this potable solar evaporator is approximately 1.75 U.S. dollar m(-2), much lower than those of conventional solar evaporators. This study provides a new approach for preparing portable and cost-effective solar evaporator.

Automated summary

This study presents a new approach for preparing a portable and cost-effective solar evaporator using plant fibers from papermaking pulp. The evaporator demonstrates excellent stability, flexibility, high evaporation rate, and solar-to-vapour conversion efficiency, making it suitable for operation under harsh conditions with high salinity and different pH values.