Making interfacial solar evaporation of seawater faster than fresh water

Author:

Xu Haolan1ORCID,Yu Huimin1,jin huanyu2ORCID,Qiu Meijia3,Sun Peng3,Cheng Chuanqi4ORCID,Wu Pan1,Wang Yida1,Wu Xuan1,Chu Dewei5,Zheng Min6,Qiu Tong7,Lu Yi8,Zhang Bin4ORCID,Mai Wenjie3ORCID,Yang Xiaofei8,Owens Gary1ORCID

Affiliation:

1. University of South Australia

2. University of Adelaide

3. Jinan University

4. Tianjin University

5. University of New South Wales

6. University of Aldelaide

7. Shanghai Jiao Tong University

8. Nanjing Forestry University

Abstract

Abstract Interfacial solar evaporation-based seawater desalination is regarded as one of the most promising strategies to alleviate freshwater scarcity. However, the solar evaporation rate of real seawater is significantly constricted by the ubiquitous salts present in seawater. In addition to the common issue of salt accumulation on the evaporation surface during solar evaporation, strong hydration between salt ions and water molecules leads to a lower evaporation rate for real seawater compared to pure water. Here we develop a facile and general strategy to reverse this occurrence, i.e., making the real seawater evaporation faster than pure water. By simply introducing specific mineral materials into the floating photothermal evaporator, ion exchange at air-water interfaces directly resulted in a decrease in seawater evaporation enthalpy, and consequently much higher seawater evaporation rates compared to pure water. This process is spontaneously realized during seawater solar evaporation. Considering the current enormous clean water production from evaporation-based desalination plants, such an evaporation performance improvement could potentially increase annual clean water production by more than a billion tons, benefiting millions of people worldwide.

Publisher

Research Square Platform LLC

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