Even in arid parts of the world, there is usually moisture in the air. This moisture could provide much-needed water for drinking and irrigation, but extracting water out of air is difficult. A new technology developed by KAUST researchers can consistently extract liters of water out of thin air each day without needing regular manual maintenance.
Harvesting water from air is not a new idea, or even a new technology, but existing solar-powered systems are clunky.
Solar-powered harvesters work in a two-stage cycle. An absorbent material first captures water from the air, and once it is saturated, the system is sealed and heated with sunlight to extract the captured water. Alternating between the two stages requires either manual labor or a switching system, which adds complexity and cost. The new harvester developed at KAUST requires neither — it passively alternates between the two stages so it can cycle continuously without intervention.
“Our initial inspiration came from observing natural processes: specifically how plants efficiently transport water from their roots to their leaves through specialized structures,” said Study Lead and Postdoc Kaijie Yang.
This gave the team the key idea for their new system. “In our system, mass transport bridges play a crucial role as a connection between the ‘open part’ for atmospheric water capture and the ‘closed part’ for freshwater generation,” explained Yang.
The mass transport bridges are a collection of vertical microchannels filled with a salt solution that absorbs water. The water-rich salt solution is pulled up the channel by the same capillary action that pulls water up plant stems, and then the concentrated salt solution diffuses back down to collect more water. “By optimizing the transport of mass and heat within the system, we enhanced its efficiency and effectiveness,” said Postdoc Tingting Pan, who worked on the project.
During testing the system in Saudi Arabia, each square meter produced 2-3 liters of water per day during the summer, and about 1-3 liters per day in the fall. During the tests, the team ran the system for several weeks without the need for maintenance. They also showed that it could be used as a direct point source to irrigate Chinese cabbage and desert trees.
“The materials we used were a water-wicking fabric, a low-cost hygroscopic salt and a plastic-based frame. We chose the materials for their affordability and availability, so we anticipate the cost is affordable for large-scale application in low-income areas,” said Senior Author Qiaoqiang Gan.
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