Heart Trabeculae‐Inspired Superhydrophilic Electrode for Electric‐Assisted Uranium Extraction from Seawater

Using nuclear power to replace electricity generated from fossil fuels is an effective strategy to reduce global carbon dioxide emissions and also spurs the search for new sources of nuclear fuel. Extracting uranium from seawater has a significant reserve advantage, although its ultralow concentrati...

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Bibliographic Details
Published in:Advanced functional materials 2025-01, Vol.35 (2), p.n/a
Main Authors: Li, Tingyang, Yan, Zidi, Chen, Shusen, Song, Yan, Lin, Xiangbin, Zhang, Zhehua, Yang, Linsen, He, Xiaofeng, Qian, Yongchao, Zhou, Shengyang, Li, Xin, Wang, Qingchen, Kong, Xiang‐Yu, Jiang, Lei, Wen, Liping
Format: Article
Language:English
Subjects:
Adsorption
bioinspired fractal structures
Carbon dioxide
Carbon dioxide concentration
cardiac trabeculae
electric‐assisted adsorption
Electrodes
Energy technology
Fractals
Nuclear fuels
Seawater
Uranium
uranium extraction from seawater
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Summary:Using nuclear power to replace electricity generated from fossil fuels is an effective strategy to reduce global carbon dioxide emissions and also spurs the search for new sources of nuclear fuel. Extracting uranium from seawater has a significant reserve advantage, although its ultralow concentration presents substantial challenges. Here, inspired by the fractal structure of cardiac trabeculae on the inner surface of the heart, a uranium enrichment electrode with a superhydrophilic and uranium‐affinitive fractal surface is developed. This innovative design enhances rapid charge/ion transfer, ensures complete surface wetting, and provides numerous adsorption sites. By synergistically integrating the advantages of electric‐assisted processes and bioinspired microstructures predicated on chemical coordination principles, the electrode demonstrates a uranium adsorption capacity of 13.2 mg g−1 following a 7‐d exposure to natural seawater. This research not only demonstrates an effective strategy for the development of advanced uranium enrichment electrodes but also provides more possibilities for innovative approaches in sustainable energy technology. Drawing inspiration from how trabeculae enhance the heart's blood supply area, a composite electrode endowed with a biomimetic fractal structure, designed for the high‐efficiency, electric‐assisted extraction of uranium from seawater is fabricated. By amalgamating electrically assisted ion migration with a bioinspired architecture, a capacity of 13.2 mg g−1 is achieved within only 7 d of contact with natural seawater.
ISSN:1616-301X
1616-3028
DOI:10.1002/adfm.202412349