Strengthening Fe(II)/Fe(III) Dynamic Cycling by Surface Sulfation to Achieve Efficient Electrochemical Uranium Extraction at Ultralow Cell Voltage

Wang, Yanjing; Song, Minglei; Wei, Jianrong; You, Jie; Chen, Siping; Wang, Shuangyin; Wang, Yanyong

doi:10.1021/acs.est.3c05133

Environ. Sci. Technol.

2023

DOI: 10.1021/acs.est.3c05133

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Strengthening Fe(II)/Fe(III) Dynamic Cycling by Surface Sulfation to Achieve Efficient Electrochemical Uranium Extraction at Ultralow Cell Voltage

Yanjing Wang,

Minglei Song,

Jianrong Wei

et al.

Abstract: Electrochemically mediated Fe(II)/Fe(III) redox-coupled uranium extraction can efficiently reduce the cell voltage of electrochemical uranium extraction (EUE). How to regulate the surface structure to enhance the uranium acyl ion adsorption capacity and strengthen the Fe(II)/Fe(III) redox cycle process is crucial for EUE. In this work, we developed surface sulfated nanoreduced iron (S-NRI) for EUE and exhibited improved properties for EUE at an ultralow cell voltage (−0.1 V). Compared with a nanoreduced iron (… Show more

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Cited by 9 publications

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A Supramolecular Organic Framework‐Mediated Electrochemical Strategy Achieves Highly Selective and Continuous Uranium Extraction

Wang,

Xu,

Wang

et al. 2024

Adv Funct Materials

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The integration of selectivity and electron transfer ability remains a primary challenge in developing electrode materials for uranium electroextraction. Herein, a phenanthroline‐based supramolecular organic framework (MPSOF) is elaborately constructed as a pioneering cathode material through the hydrogen bond‐driven self‐assembly of melamine and 1,10‐phenanthroline 2,9‐dicarboxylic acid (PDA) for selective and continuous electrochemical uranium extraction (EUE). PDA moieties selectively capture UO22+, while the hydrogen bond‐supporting frameworks provide an efficient electron transfer channel for the redox of UO22+. These structural features enable the rapid formation and spontaneous shedding of uranium precipitate from MPSOF, allowing for the regeneration of the selective adsorption sites. As a result, MPSOF‐mediated EUE exhibits a high extraction capacity of 7311 mg U g−1 at a low voltage of −3.5 V but does not reach equilibrium. Cyclic EUE is employed to uranium extraction from simulated high‐salt radioactive effluents and attains high selectivity for uranium. The electroextraction mechanism is confirmed, wherein uranium species transform into (UO2)O2·4H2O. This work not only provides an efficient electrode material for uranium electroextraction, but also presents a novel electrochemical strategy for separation and adsorption of other radionuclides and contaminant ions.

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A Supramolecular Organic Framework‐Mediated Electrochemical Strategy Achieves Highly Selective and Continuous Uranium Extraction

Wang,

Xu,

Wang

et al. 2024

Adv Funct Materials

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Rich electron delocalization structure in carbon nitride inducing radical transfer for high‐performance photocatalytic uranyl reduction

Liu,

Li,

Yao

et al. 2024

Carbon Energy

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Investigating the activation of the persulfate process through heterogeneous carbonaceous catalysts to expedite the reduction of uranyl ions (U(VI)) is imperative. The primary hurdle involves understanding the transfer and distribution of photogenerated carriers during the reduction process in this intricate system and deciphering the role of activated groups in promoting reduction efficiency. In this study, we strategically regulate the structure of polymeric carbon nitride to promote the N‐doped state, thereby facilitating delocalization electron enrichment. The resulting active sites effectively activate peroxyl disulfate (PDS), generating radicals that expedite the selective reduction of U(VI). This strategic approach mitigates the inherent disadvantage of the short half‐life of free radicals in persulfate‐based advanced oxidation processes. As a consequence of our endeavors and with the simultaneous presence of PDS and hydrogen peroxide, we achieve an exceptional photoreduction efficiency of 100% within a remarkably short period of 20 min. This breakthrough presents a high‐efficiency application with significant potential for addressing the pollution associated with uranyl‐containing wastewater. Our findings not only contribute to the fundamental understanding of AOPs but also offer a practical solution with implications for environmental remediation.

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Interface coupling induced built-in electric fields accelerate electro-assisted uranium extraction over Co3O4@FeOx nanosheet arrays

Zhou,

Li,

Shao

et al. 2024

Applied Catalysis B: Environment and Energy

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Strengthening Fe(II)/Fe(III) Dynamic Cycling by Surface Sulfation to Achieve Efficient Electrochemical Uranium Extraction at Ultralow Cell Voltage

Cited by 9 publications

References 38 publications

A Supramolecular Organic Framework‐Mediated Electrochemical Strategy Achieves Highly Selective and Continuous Uranium Extraction

A Supramolecular Organic Framework‐Mediated Electrochemical Strategy Achieves Highly Selective and Continuous Uranium Extraction

Rich electron delocalization structure in carbon nitride inducing radical transfer for high‐performance photocatalytic uranyl reduction

Interface coupling induced built-in electric fields accelerate electro-assisted uranium extraction over Co3O4@FeOx nanosheet arrays

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