Enrichment and Separation of Radionuclides by Organic Polymer Materials: A Review

Zhang, Xinyue; Yang, Xinyi; Rong, Qiuyu; Liu, Xiaolu; Zhou, Yilun; Yang, Hui; Wang, Guofu; Chen, Zhongshan; Wang, Xiangke

doi:10.1021/acsestengg.3c00543

Cited by 24 publications

(1 citation statement)

References 103 publications

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“…Uranium is one of the most important raw materials for nuclear power, but radioactive wastewater will be inevitably produced during uranium mining. Uranium in radioactive wastewater typically exists in the hexavalent oxidation state, U(VI), with the high mobility and radiotoxicity, representing potential environmental hazard in the long term. − So far, a variety of methods have been developed, such as chemical precipitation, ion exchange, , solvent extraction, , membrane separation, , sorption, , and photocatalysis, − to remove it from radioactive wastewater. Among them, photocatalytic technology is considered to be one of the most promising options for treating uranium-containing radioactive wastewater, due to the advantages of fast kinetics, high selectivity, and the oxidation state transition from soluble hexavalent U(VI) to insoluble tetravalent U(IV). , …”

Section: Introductionmentioning

confidence: 99%

Enhanced Photocatalytic Removal of U(VI) from Real Radioactive Wastewater by Modulating the Surface Charge Microenvironment in Porphyrin-Based Hydrogen-Bonded Organic Framework

Wu,

Zhao,

Yin

et al. 2024

ACS Appl. Mater. Interfaces

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Reduction of soluble U(VI) to insoluble U(IV) based on photocatalysts is a simple, environmentally friendly, and efficient method for treating radioactive wastewater. The present study involved the systematic comparison of the photoelectric properties of three metalloporphyrins with different metal centers and the synthesis of a novel porphyrin-based hydrogen-bonded organic framework (Ni-pHOF) photocatalyst by modulating the surface charge microenvironment in porphyrin for enhanced photocatalytic removal of U(VI) from wastewater. Compared to the metal-free HOF, the surface charge microenvironment around the Ni atom in Ni-pHOF accelerated the reduction kinetics of U(VI) under visible light illumination at the initial moment, showing a high removal rate, even in air. The removal rate of U(VI) from aqueous solution by Ni-pHOF can achieve over 98% in the presence of coexisting nonoxidizing cations and only decreased by less than 8% after five cycles, exhibiting high selectivity and good reusability. Furthermore, Ni-pHOF can remove 86.74% of U(VI) from real low-level radioactive wastewater after 120 min of illumination, showcasing practical application potential. Density functional theory (DFT) calculations and electron paramagnetic resonance (EPR) spectra indicated that modulating the surface charge microenvironment in Ni-pHOF through porphyrin metallization is conducive to improving the charge separation efficiency, prompting more e − and • O 2 − to participate in the reduction reaction of U(VI). This work provides new insights into the metallization of porphyrin-based HOFs and paves a new way for the tailoring of porphyrin-based HOFs/COFs by modulating the surface charge microenvironment to achieve efficient recovery of U(VI) from real radioactive wastewater.

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Section: Introductionmentioning

confidence: 99%

Enhanced Photocatalytic Removal of U(VI) from Real Radioactive Wastewater by Modulating the Surface Charge Microenvironment in Porphyrin-Based Hydrogen-Bonded Organic Framework

Wu,

Zhao,

Yin

et al. 2024

ACS Appl. Mater. Interfaces

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Scavenging Radionuclide by Shapeable Porous Materials

Jing,

Li,

et al. 2024

ChemPlusChem

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Nuclear energy is a competitive and environmentally friendly low‐carbon energy source. It is seen as an important avenue for satisfying energy demands, responding to the energy crisis, and mitigating global climate change. However, much attention has been paid to achieving the effective treatment of radionuclide oxoanions produced in nuclear waste. Initially, advanced adsorbents were mainly available in powder form, which meant that additional purification processes were usually required for separation and recovery in industrial applications. Therefore, to meet the practical requirements of industrial applications, materials need to be molded and processed into forms such as beads, membranes, gels, and resins. Here, we summarize the fabrication of porous materials used for capturing typical radionuclide oxoanions, including UO22+, TcO4−, IO3−, SeO32−, and SeO4−.

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Theoretical Implications of Bifunctional Ligands to Improve Uranium Extraction Performance

Xu,

Wang,

et al. 2024

Eur J Inorg Chem

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Extraction of uranium from seawater is considered to be an effective way to solve the shortage of uranium resources, and the development of efficient adsorption functional groups is the key to uranium extraction. In this work, the complexation of uranyl cations with a series of diamidoxime and bifunctional (amidoximate‐carboxylate, amidoximate‐phosphate) ligands has been probed by quantum chemical calculations. For most of the uranyl complexes, the amidoxime groups adopt η2 mode to uranyl cations. Based on bonding analyses, we found that the uranyl complexes with methyl‐substituted ligands (H2L′) possess stronger covalent interactions than those with phenyl‐substituted ligands (H2L). Consequently, the uranyl complexes with H2L’ are more stable in the extraction process according to thermodynamic analysis. The amidoximate‐phosphate bifunctional ligand (H2L3′) has stronger extraction capacity to uranyl cations than other ligands, which is related to the relatively lower decomposition energy, and it shows selectivity in seawater for uranyl cations over vanadium ions, which may be a potential ligand for uranium extraction. Therefore, the introduction of synergistic functional groups, i. e. the bifunctional ligands, enhance the extraction properties of uranyl cations. This work improves understanding of synergistic ligands, and may contribute to design and development of efficient ligands for recovery of uranium from seawater.

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Enrichment and Separation of Radionuclides by Organic Polymer Materials: A Review

Cited by 24 publications

References 103 publications

Enhanced Photocatalytic Removal of U(VI) from Real Radioactive Wastewater by Modulating the Surface Charge Microenvironment in Porphyrin-Based Hydrogen-Bonded Organic Framework

Enhanced Photocatalytic Removal of U(VI) from Real Radioactive Wastewater by Modulating the Surface Charge Microenvironment in Porphyrin-Based Hydrogen-Bonded Organic Framework

Scavenging Radionuclide by Shapeable Porous Materials

Theoretical Implications of Bifunctional Ligands to Improve Uranium Extraction Performance

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