Cyano‐Functionalized Graphitic Carbon Nitride with Adsorption and Photoreduction Isosite Achieving Efficient Uranium Extraction from Seawater

Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride (g‐C3N4‐CN) with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared to achieve efficient photocatalytic ur...

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Published inAdvanced functional materials Vol. 34; no. 19
Main Authors Hu, Enmin, Chen, Qian, Gao, Qiong, Fan, Xiaofeng, Luo, Xingjian, Wei, Yu, Wu, Guang, Deng, Haibo, Xu, Shicheng, Wang, Peng, Liu, Liping, He, Rong, Chen, Xianjie, Zhu, Wenkun, Zhu, Yongfa
Format Journal Article
LanguageEnglish
Published Hoboken Wiley Subscription Services, Inc 01.05.2024
Subjects
Adsorption
adsorption and photoreduction isosite
Carbon
Carbon nitride
cyano group
Cyano groups
graphitic carbon nitride
Photocatalysis
Seawater
Uranium
uranium extraction
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Abstract Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride (g‐C3N4‐CN) with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared to achieve efficient photocatalytic uranium extraction from seawater. As the key of the isosite structure, the cyano group not only dramatically promotes the separation of photogenerated charges of g‐C3N4‐CN and enriched electrons around it, but also greatly improves the adsorption capacity and selectivity for U(VI) over g‐C3N4‐CN by complexing with U(VI). Therefore, g‐C3N4‐CN exhibits efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g−1, significantly higher than most reported g‐C3N4‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater. Briefly, this work illustrates the importance of constructing the isosite structure of adsorption and photoreduction for U(VI) in improving the photocatalytic uranium extraction performance. The cyano‐functionalized graphitic carbon nitride with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared, which achieves efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g−1, significantly higher than most reported g‐C3N4‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater.
AbstractList Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride (g‐C3N4‐CN) with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared to achieve efficient photocatalytic uranium extraction from seawater. As the key of the isosite structure, the cyano group not only dramatically promotes the separation of photogenerated charges of g‐C3N4‐CN and enriched electrons around it, but also greatly improves the adsorption capacity and selectivity for U(VI) over g‐C3N4‐CN by complexing with U(VI). Therefore, g‐C3N4‐CN exhibits efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g−1, significantly higher than most reported g‐C3N4‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater. Briefly, this work illustrates the importance of constructing the isosite structure of adsorption and photoreduction for U(VI) in improving the photocatalytic uranium extraction performance.
Abstract Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride (g‐C 3 N 4 ‐CN) with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared to achieve efficient photocatalytic uranium extraction from seawater. As the key of the isosite structure, the cyano group not only dramatically promotes the separation of photogenerated charges of g‐C 3 N 4 ‐CN and enriched electrons around it, but also greatly improves the adsorption capacity and selectivity for U(VI) over g‐C 3 N 4 ‐CN by complexing with U(VI). Therefore, g‐C 3 N 4 ‐CN exhibits efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g −1 , significantly higher than most reported g‐C 3 N 4 ‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater. Briefly, this work illustrates the importance of constructing the isosite structure of adsorption and photoreduction for U(VI) in improving the photocatalytic uranium extraction performance.
Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride (g‐C3N4‐CN) with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared to achieve efficient photocatalytic uranium extraction from seawater. As the key of the isosite structure, the cyano group not only dramatically promotes the separation of photogenerated charges of g‐C3N4‐CN and enriched electrons around it, but also greatly improves the adsorption capacity and selectivity for U(VI) over g‐C3N4‐CN by complexing with U(VI). Therefore, g‐C3N4‐CN exhibits efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g−1, significantly higher than most reported g‐C3N4‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater. Briefly, this work illustrates the importance of constructing the isosite structure of adsorption and photoreduction for U(VI) in improving the photocatalytic uranium extraction performance. The cyano‐functionalized graphitic carbon nitride with an isosite structure of adsorption and photoreduction for U(VI) is successfully prepared, which achieves efficient and stable photocatalytic U(VI) reduction performance, with a saturated uranium extraction capacity of 2644.3 mg g−1, significantly higher than most reported g‐C3N4‐based photocatalysts. Moreover, it also performs well in solar light‐driven uranium extraction from actual seawater.
Author Wang, Peng
Fan, Xiaofeng
Deng, Haibo
Gao, Qiong
Luo, Xingjian
Chen, Xianjie
Xu, Shicheng
Zhu, Wenkun
Zhu, Yongfa
Liu, Liping
Wu, Guang
He, Rong
Chen, Qian
Wei, Yu
Hu, Enmin
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Snippet Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon nitride...
Abstract Photocatalytic uranium extraction from seawater is an ideal strategy to obtain uranium resources. Herein, the cyano‐functionalized graphitic carbon...
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SubjectTerms Adsorption
adsorption and photoreduction isosite
Carbon
Carbon nitride
cyano group
Cyano groups
graphitic carbon nitride
Photocatalysis
Seawater
Uranium
uranium extraction
Title Cyano‐Functionalized Graphitic Carbon Nitride with Adsorption and Photoreduction Isosite Achieving Efficient Uranium Extraction from Seawater
URI https://onlinelibrary.wiley.com/doi/abs/10.1002%2Fadfm.202312215
https://www.proquest.com/docview/3051824022/abstract/
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