Direct solar vapor generation with micro‐3D printed hydrogel device

Direct solar vapor generation (SVG) provides a sustainable and eco‐friendly solution to the current global water scarcity challenges. However, existing SVG systems operating under natural sunlight suffer from low water yield and high energy requirement of vaporization. New materials with reduced lat...

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Bibliographic Details
Published in:EcoMat (Beijing, China) China), 2022-01, Vol.4 (1), p.n/a
Main Authors: Alketbi, Afra S., Raza, Aikifa, Sajjad, Muhammad, Li, Hongxia, AlMarzooqi, Faisal, Zhang, TieJun
Format: Article
Language:English
Subjects:
3-D printers
3D printing
absorber material
Anisotropy
Composite structures
COVID-19
Design
Electromagnetic absorption
Enthalpy
Evaporation
Evaporation rate
Fourier transforms
hydrogel
Hydrogels
Iron oxides
Latent heat
Light
Microchannels
Nanoparticles
Polymerization
Polyvinyl alcohol
Portable equipment
solar thermal energy conversion
Spectrum analysis
Three dimensional printing
Vaporization
Vapors
water production
Water purification
Water scarcity
Water supply
Water transport
Water yield
Wettability
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Summary:Direct solar vapor generation (SVG) provides a sustainable and eco‐friendly solution to the current global water scarcity challenges. However, existing SVG systems operating under natural sunlight suffer from low water yield and high energy requirement of vaporization. New materials with reduced latent heat of water vaporization are in urgent demand to boost SVG process. Herein, we propose a novel strategy to additively fabricate anisotropic hybrid 3D structure from photocurable thermoresponsive p(NIPAm‐co‐PEGDA) hydrogel on the top of PEGDA foam for SVG. The in‐situ post‐printing synthesis of iron oxide nanoparticles within the p(NIPAm‐co‐PEGDA) hydrogel on the top surface, thus introducing anisotropy, is achieved by adding metallic salt precursor into the printing solution. The as‐fabricated hydrogel composite structure exhibits superior light absorption properties and rapid capillary‐driven water transport through a 3D‐printed microchannel network within the hydrogel. As a result, our SVG device achieves an extraordinary water evaporation rate of 5.12 kg m−2 h−1 under one sun (1 kW/m2). The intrinsic water activation states, in addition to wettability modulation with temperature increase within p(NIPAm‐co‐PEGDA) hydrogel, plays a critical role in reducing the equivalent vaporization enthalpy and shifting the vaporization to relatively lower temperatures. The proposed hybrid SVG device is feasible, portable, and highly efficient, promising great potential for grand water‐energy nexus challenges. A 3D‐printed anisotropic hydrogel device is proposed for ultrahigh vapor generation with a rate of 5.12 kg m–2 h–1 under 1 sun. Efficient photothermal conversion and vapor release are achieved with Fe3O4 nanocomposite hydrogel and temperature‐stimulating wettability modulation, while continuous water supply is guaranteed through 3D‐printed p(NIPAm‐co‐PEGDA) hydrogel microchannels.
ISSN:2567-3173
2567-3173
DOI:10.1002/eom2.12157