A Super‐Hygroscopic Solar‐Regenerated Alginate‐Based Composite for Atmospheric Water Harvesting

Global water scarcity is leading to increasingly tense competition across populations. In order to complement the largely fast‐depleting fresh water sources and mitigate the challenges generated by brine discharge from desalination, atmospheric water harvesting (AWH) has emerged to support long‐term...

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Bibliographic Details
Published in:Small (Weinheim an der Bergstrasse, Germany) Germany), 2024-09, Vol.20 (37), p.e2400420-n/a
Main Authors: Abd Elwadood, Samar N., Farinha, Andreia S. F., Al Wahedi, Yasser, Al Alili, Ali, Witkamp, Geert‐Jan, Dumée, Ludovic F., Karanikolos, Georgios N.
Format: Article
Language:English
Subjects:
alginate hybridization
Alginates
Aluminum phosphate
Desorption
Energy consumption
Fresh water
Graphene
hygroscopic hydrogels
micro‐channeling
moisture sorption
photothermal harvester
Porous materials
Sorbents
Stability
Water
Water discharge
water harvesting
Water supply
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Summary:Global water scarcity is leading to increasingly tense competition across populations. In order to complement the largely fast‐depleting fresh water sources and mitigate the challenges generated by brine discharge from desalination, atmospheric water harvesting (AWH) has emerged to support long‐term water supply. This work presents a novel alginate‐based hybrid material comprised of porous silico‐aluminophosphate‐34 (SAPO‐34) as fast‐transport channel medium as well as hydrophilicity and stability enhancer, and graphene‐based sheets as light absorber for solar‐enabled evaporation, both optimally incorporated in an alginate matrix, resulting in a composite sorbent capable of harvesting water from the atmosphere with a record intake of up to 6.85 gw gs−1. Natural sunlight is solely used to enable desorption achieving increase of the temperature of the developed network up to 60 °C and resulting in release of the sorbed water, with impurities content well below the World Health Organization (WHO) upper limits. After 30 cycles of sorption and desorption, the composite hydrogel displayed unchanged water uptake and stability. This work provides an impactful perspective toward sustainable generation of water from humidity without external energy consumption supporting the emergence of alternative water production solutions. A novel alginate‐based hybrid sorbent for AWH comprising porous SAPO‐34 as fast‐transport channel medium and hydrophilicity and stability enhancer, and graphene‐based sheets as light absorber for solar‐enabled evaporation. The sorbent exhibits a record intake of up to 6.85 gw gs−1 and is regenerated solely by solar irradiation producing clean water with impurities content well below the upper WHO limits.
ISSN:1613-6810
1613-6829
1613-6829
DOI:10.1002/smll.202400420