Using sound to synthesize covalent organic frameworks in water

Covalent organic frameworks (COFs) are typically synthesized using solvothermal conditions (>120 °C, >72 hours) in harmful organic solvents. Here we report a strategy to rapidly (<60 minutes) synthesize imine-linked COFs in aqueous acetic acid using sonochemistry and thus avoid most of the...

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Published inNature Synthesis Vol. 1; no. 1; pp. 87 - 95
Main Authors Zhao, Wei, Yan, Peiyao, Yang, Haofan, Bahri, Mounib, James, Alex M, Chen, Hongmei, Liu, Lunjie, Li, Boyu, Pang, Zhongfu, Clowes, Rob, Browning, Nigel D, Ward, John W, Wu, Yue, Cooper, Andrew I
Format Journal Article
LanguageEnglish
Published London Nature Publishing Group 01.01.2022
Subjects
Acetic acid
Acids
Adsorption
Aldehydes
Aqueous solutions
Cavitation
Covalence
Crystallinity
Fourier transforms
Hydrogen evolution
Investigations
Material properties
Methods
Photocatalysis
Porosity
Solvents
Sonochemical reactions
Synthesis
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Abstract Covalent organic frameworks (COFs) are typically synthesized using solvothermal conditions (>120 °C, >72 hours) in harmful organic solvents. Here we report a strategy to rapidly (<60 minutes) synthesize imine-linked COFs in aqueous acetic acid using sonochemistry and thus avoid most of the disadvantages of solvothermal methods. Using the sonochemical method, we synthesized to our knowledge previously unreported COFs. The crystallinity and porosity of these COFs is comparable to or better than those of the same materials made by established solvothermal routes. The sonochemical method even works in sustainable solvents, such as food-grade vinegar. The generality of the method is shown in the preparation of a 2D COF with pendant functionalization and of a COF with 3D connectivity. Finally, a COF synthesized sonochemically acts as an excellent photocatalyst for the sacrificial hydrogen evolution from water, showing a more sustained catalytic performance compared with that of its solvothermal analogue. The speed, ease and generality of this sonochemical method together with improved material quality makes the use of sound an enabling methodology for the rapid discovery of functional COFs.A sonochemical route rapidly synthesizes covalent organic frameworks (COFs) in aqueous solutions of acetic acid. This method has operational advantages compared with conventional solvothermal routes and yields COFs of higher crystallinity and porosity, and hence improved materials properties.
AbstractList Covalent organic frameworks (COFs) are typically synthesized using solvothermal conditions (>120 °C, >72 hours) in harmful organic solvents. Here we report a strategy to rapidly (<60 minutes) synthesize imine-linked COFs in aqueous acetic acid using sonochemistry and thus avoid most of the disadvantages of solvothermal methods. Using the sonochemical method, we synthesized to our knowledge previously unreported COFs. The crystallinity and porosity of these COFs is comparable to or better than those of the same materials made by established solvothermal routes. The sonochemical method even works in sustainable solvents, such as food-grade vinegar. The generality of the method is shown in the preparation of a 2D COF with pendant functionalization and of a COF with 3D connectivity. Finally, a COF synthesized sonochemically acts as an excellent photocatalyst for the sacrificial hydrogen evolution from water, showing a more sustained catalytic performance compared with that of its solvothermal analogue. The speed, ease and generality of this sonochemical method together with improved material quality makes the use of sound an enabling methodology for the rapid discovery of functional COFs.A sonochemical route rapidly synthesizes covalent organic frameworks (COFs) in aqueous solutions of acetic acid. This method has operational advantages compared with conventional solvothermal routes and yields COFs of higher crystallinity and porosity, and hence improved materials properties.
Author Zhao, Wei
Li, Boyu
James, Alex M
Clowes, Rob
Yan, Peiyao
Bahri, Mounib
Yang, Haofan
Wu, Yue
Liu, Lunjie
Ward, John W
Cooper, Andrew I
Browning, Nigel D
Chen, Hongmei
Pang, Zhongfu
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  fullname: Wu, Yue
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  givenname: Andrew I
  surname: Cooper
  fullname: Cooper, Andrew I
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Snippet Covalent organic frameworks (COFs) are typically synthesized using solvothermal conditions (>120 °C, >72 hours) in harmful organic solvents. Here we report a...
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SubjectTerms Acetic acid
Acids
Adsorption
Aldehydes
Aqueous solutions
Cavitation
Covalence
Crystallinity
Fourier transforms
Hydrogen evolution
Investigations
Material properties
Methods
Photocatalysis
Porosity
Solvents
Sonochemical reactions
Synthesis
Title Using sound to synthesize covalent organic frameworks in water
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