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Co-construction of molecular-level uranyl-specific "nano-holes" with amidoxime and amino groups on natural bamboo strips for specifically capturing uranium from seawater.

Authors :
Wang, Ying
Lin, Zaiwen
Zhu, Jiahui
Liu, Jingyuan
Yu, Jing
Liu, Qi
Chen, Rongrong
Li, Ying
Wang, Jun
Source :
Journal of Hazardous Materials. Sep2022, Vol. 437, pN.PAG-N.PAG. 1p.
Publication Year :
2022

Abstract

Efficiently capturing of uranium (VI) [U(VI)] from seawater elicits unparalleled attraction for sustaining the uplifted requirement for nuclear fuel. However, obtaining the abundant U(VI) resource from seawater has always seriously restricted by competitive adsorption from higher concentrations of competitors, especially vanadium (V) [V(V)]. Herein, based on amidoximized natural bamboo strips with hierarchical porous structure, the molecular-level uranyl-specific "nano-holes" was co-constructed by the intramolecular hydrogen bonds for specifically trapping U(VI) from seawater. Manipulating the branched degrees of amino groups enabled the creation of a series of the molecular-level uranyl-specific "nano-holes" that exhibit ultrahigh affinity and selective adsorption of U(VI) with a adsorption capacity 1.8 fold higher compared to that of V(V) after 30 days floating in the Yellow Sea basin, conquering the long-term challenge of the competitive adsorption of V(V) for amidoxime-based adsorbents applied to extract U(VI) from seawater. The diameter of the molecular-level uranyl-specific "nano-holes" is approximately 12.07 Å, significantly larger than (UO 2) 3 (OH) 3 + (10.37 Å) and smaller than HV 10 O 28 5-, thereby exhibiting specifically trapping of U(VI) in a series of adsorption experiments with different U(VI)-V(V) ratios. Besides, the adsorption model based on the combination of experimental and theoretical results is accompanied by "hydrogen bond breaking and coordination bond formation". [Display omitted] [ABSTRACT FROM AUTHOR]

Details

Language :
English
ISSN :
03043894
Volume :
437
Database :
Academic Search Index
Journal :
Journal of Hazardous Materials
Publication Type :
Academic Journal
Accession number :
158117055
Full Text :
https://doi.org/10.1016/j.jhazmat.2022.129407