Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System

Zhang, Shuai; Fu, Jingru; Das, Saikat; Ye, Kaiqi; Zhu, Weidong; Ben, Teng

doi:10.1002/ange.202208660

Cited by 5 publications

(2 citation statements)

References 46 publications

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“…11,12 Although researchers have incorporated hygroscopic salts into these materials to enhance their water adsorption capacity under ambient conditions, the strong affinity of hygroscopic salts for water molecules in turn leads to a reduced water release/production efficiency. 13,14 For example, Li et al reported a PAM-based hydrogel containing calcium chloride and carbon nanotubes with a maximum water adsorption capacity of 2.05 g g −1 and a low desorption efficiency of 55%. 15 The trade-off between water uptake (under low-mediate humidity) and water release efficiency under ambient conditions limits the practical applications of artificial AWH materials.…”

Section: ■ Introductionmentioning

confidence: 99%

“…At night, the tip of the spike array can liquefy the water vapor in the air, and the liquefied water droplets can gather around the stomata driven by the Laplace gradient and be absorbed by the fleshy stem, making it survive in harsh environments . Unfortunately, most of the artificial AWH materials based on hydrogels or metal–organic frameworks (MOFs) arguably have insufficient vapor liquefaction ability. , Although researchers have incorporated hygroscopic salts into these materials to enhance their water adsorption capacity under ambient conditions, the strong affinity of hygroscopic salts for water molecules in turn leads to a reduced water release/production efficiency. , For example, Li et al reported a PAM-based hydrogel containing calcium chloride and carbon nanotubes with a maximum water adsorption capacity of 2.05 g g –1 and a low desorption efficiency of 55% . The trade-off between water uptake (under low-mediate humidity) and water release efficiency under ambient conditions limits the practical applications of artificial AWH materials.…”

Section: Introductionmentioning

confidence: 99%

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Tillandsia-Inspired Composite Materials for Atmospheric Water Harvesting

Feng

Mao

Onggowarsito

et al. 2023

ACS Sustainable Chem. Eng.

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Atmospheric water harvesting (AWH) is a potentially promising small-scale approach to alleviate the water crisis in arid or semiarid regions. Inspired by the asymmetric structure of tillandsia leaves, a plant species native to semiarid regions, we report the development of a bioinspired composite (BiC) to draw moisture for AWH applications. With the advent of the post-COVID era, the nonwoven materials in used masks are discarded, landfilled, or incinerated along with the masks as medical waste, and the negative impact on the environment is inevitable. The nonwoven sheet has porosity, softness, and certain mechanical strength. We innovatively developed BiCs, immobilizing hygroscopic salt with a nonwoven mask for fast vapor liquefaction and using a polymer network to store water. The resulting BiC material manages to achieve a highwater adsorption capacity of 1.24 g g −1 under a low-moderate humidity environment and a high-water release ratio of ca. 90% without the use of photothermal materials, while maintaining high structural integrity in cyclic testing.

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Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Tillandsia-Inspired Composite Materials for Atmospheric Water Harvesting

Feng

Mao

Onggowarsito

et al. 2023

ACS Sustainable Chem. Eng.

View full text Add to dashboard Cite

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Correspondence on “Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System”

2023

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In a recent Research Article, Ben and coworkers reported a hydrogen-bonded framework prepared from a 4 + tetra-amidinium component and a 4 À tetra-sulfonate component, termed CPOS-6. They showed that CPOS-6 could reversibly adsorb and desorb water over a narrow humidity window, and that this material offered potential for applications in atmospheric water harvesting. This conclusion was supported by experiments that showed the material was stable over 50 adsorption/desorption cycles and that the kinetics of these cycles were very rapid. In this Correspondence we present additional structural data regarding this framework in both its hydrated and dehydrated states and thus discern the mechanism of water binding. These data do not disagree with Ben and co-workers' findings: rather they emphasise how remarkable the cyclability and rapid kinetics of adsorption/desorption are, as these processes involve a complete crystal-to-crystal rearrangement of the framework.

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Reply to the Correspondence on “Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System”

et al. 2023

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White et al., in a recent Correspondence, provided additional structural data to illustrate that CPOS-6 undergoes a single-crystal-to-single-crystal transformation during water adsorption/desorption. This finding gave a better understanding of the relevant experimental phenomena from the perspective of structural transformation and is a good complement to our previous results. However, we wish to emphasize that our research focuses on the kinetic behavior of water during ultrafast adsorption/desorption in nano-confined channels. Herein, we further interpret the rapid transport of water molecules in the nano-confined channels from the perspective of superfluidity.

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Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System

Cited by 5 publications

References 46 publications

Tillandsia-Inspired Composite Materials for Atmospheric Water Harvesting

Tillandsia-Inspired Composite Materials for Atmospheric Water Harvesting

Correspondence on “Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System”

Reply to the Correspondence on “Crystalline Porous Organic Salt for Ultrarapid Adsorption/Desorption‐Based Atmospheric Water Harvesting by Dual Hydrogen Bond System”

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