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Porous Cationic Electrospun Fibers with Sufficient Adsorption Sites for Effective and Continuous <sup>99</sup>TcO<sub>4</sub><sup>−</sup> Uptake

Rui Zhao, Dingyang Chen, Nvwa Gao, Li‐Yong Yuan, Wei Hu, Fengchao Cui, Yuyang Tian, Wei‐Qun Shi, Shengqian Ma, Guangshan Zhu

2022Advanced Functional Materials83 citationsDOI

Abstract

Abstract Removal of radioactive technetium‐99 ( 99 TcO 4 − ) from water by effective adsorbents is highly desired but remains a challenge. The currently used resin adsorbents possess several obstacles, such as slow adsorption kinetics and low adsorption capacity. To address these issues, herein a type of fibrous adsorbent with porosity and hyper‐branched quaternary ammonium groups, namely porous cationic electrospun fibers (PCE fibers), is successfully prepared. PCE fibers can remove 97% of 99 TcO 4 − within 1 min and the equilibrium time of 99% removal is 20 min. The predicted maximum adsorption capacity toward the surrogate ReO 4 − can reach 826 mg g −1 , which is higher than the state of art anion‐exchange resins and most of the other reported adsorbents. Furthermore, PCE fibers have good selectivity for ReO 4 − in the presence of competitive anions, and can retain ReO 4 − uptake under extreme conditions including high acid–base and gamma irradiation. Importantly, PCE fibrous adsorptive membrane is employed for dynamic ReO 4 − removal from simulated Hanford LAW stream with a processing capacity of 600 kg simulated stream per kilogram PCE fibers. The excellent performance highlights the advantages of PCE fibers over traditional resins in technetium removal.

Topics & Concepts

AdsorptionMaterials scienceCationic polymerizationChemical engineeringPorosityNuclear chemistryComposite materialPolymer chemistryOrganic chemistryChemistryEngineeringChemical Synthesis and CharacterizationRadioactive element chemistry and processingCovalent Organic Framework Applications