Enhanced Atmospheric Water Harvesting with Sunlight-Activated Sorption Ratcheting
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Date
2022-01-12
Publication Type
Journal Article
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Abstract
The global challenge of clean water scarcity needs to be confronted with novel sustainable, climate neutral solutions, over the entire spectrum of possible clean water availability. Atmospheric moisture represents a major untapped resource that can be harvested by sorbents, enabling water production in dry inland regions where it is needed. While benefiting from the utilization of an important renewable energy source, solar-driven, sorbent-based atmospheric water harvesting systems are inseparably based on a single water harvesting cycle per day, which severely limits the daily water productivity and the competitiveness of this very promising technology. Here, we rationally design an atmospheric water harvesting strategy, using durable hydrogel sorbents, that operates with sorption “ratcheting” ─ a large sequence of rapid adsorption and subsequent desorption steps ─ activated by direct sunlight. Employing theoretical considerations, we tailor the ratcheting timescales to the inherent sorption properties of the hydrogels, optimally exploiting their natural harvesting capabilities, while maintaining the sustainable utility of the daily cycle. Amplified by the favorable sorption properties and ratcheting stability of the sorbent, this strategy demonstrates an impressive ∼80% increase in water harvesting yield over the daily cycle systems. The generic nature of the ratcheting concept shows great potential to advance the water harvesting capabilities of a range of related systems.
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published
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Journal / series
Volume
14 (1)
Pages / Article No.
2237 - 2245
Publisher
American Chemical Society
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Subject
atmospheric water harvesting; sorption ratcheting; gel sorbent; hydrogel; deliquescent salt; sorption kinetics; photothermal; water-energy nexus
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Funding
179062 - On the fundamental role of substrate compliance and enhanced light absorption on droplet condensation and evaporation (SNF)