A balancing act: Improved water treatment technique using 'energy matching'

Today, a large number of people worldwide suffer from shortage of fresh drinking water, especially in remote rural regions, causing a significant threat to human life and society. While techniques such as membrane distillation and Reverse Osmosis have been used to treat saline water and alleviate the situation, they suffer from limitations like low productivity, high cost and high energy consumption.

In recent years, direct solar steam generation (DSSG) has emerged as a viable technique for water purification. The process uses photothermal materials that can absorb high amounts of solar energy. These materials are then made to float in water, which helps to maintain localized heating and generate water vapor that is subsequently condensed to obtain clean water. Current DSSG methods have reached the limits of solar thermal efficiency and evaporation rate; however, given the demand for high-flux clean water in large-scale commercialization, further enhancement in evaporation rate is necessary. Previous studies have tried to do this by exploring absorbers to manipulate the input and required energy needed for evaporation, but the relationship between IE and RE has not been studied yet.

To this end, Prof Lei Miao from Shibaura Institute of Technology, Japan, along with co-authors Xiaojiang Mu and Jianhua Zhou from Guilin University of Electronic Technology, China, aimed to find a balance between IE and RE to optimize evaporation performance in DSSG. According to the researchers, the trick was to reduce the RE to match the IE, a unique concept called energy matching. For this, they came up with an innovative evaporation system based on bilayer structures of carbon nanotube aerogel-coated wood (CACW). The design provided three layers of thermal insulation, which (1) minimized heat loss and prevented a sudden temperature drop in the absorber and (2) regulated water transport to the evaporation surface. Prof Miao explains, "Water speed regulation is key to the 'energy matching' strategy employed in our design. By controlling the speed of water transport, we ensure that the RE for evaporation is balanced with the IE to the absorber." The findings of their study are published in Solar RRL.