Zwitterionic adsorbents derived from self-Exfoliated ionic covalent organic frameworks for efficient Co-Removal of anionic and cationic radionuclides

Zwitterionic adsorbents derived from self-Exfoliated ionic covalent organic frameworks for efficient Co-Removal of anionic and cationic radionuclides

[Display omitted] •Ionic COFs with different degrees of exfoliation were synthesized by varying the number of hydroxyl groups.•Ionic COFs were confirmed as large-area ultrathin nanosheets.•Mechanistic studies revealed that hydroxyl groups raised electron density, altering Coulomb repulsion in ionic...

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Bibliographic Details
Published in:Chemical engineering journal (Lausanne, Switzerland : 1996) Vol. 497; p. 154882
Main Authors: Ouyang, Zhengdong, Li, Xiaofeng, Zhang, Jie, Li, Bo, Long, Honghan, Zhang, Yingdan, Yu, Kaifu, Li, Yang, Ma, Lijian
Format: Journal Article
Language:English
Published: Elsevier B.V 01-10-2024
Subjects:
Adsorbent
Covalent organic frameworks
Ionic COFs
Radionuclides
Self-exfoliated nanosheet
Covalent organic frameworks
Ionic COFs
Self-exfoliated nanosheet
Radionuclides
Adsorbent
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Summary:[Display omitted] •Ionic COFs with different degrees of exfoliation were synthesized by varying the number of hydroxyl groups.•Ionic COFs were confirmed as large-area ultrathin nanosheets.•Mechanistic studies revealed that hydroxyl groups raised electron density, altering Coulomb repulsion in ionic COFs.•A novel zwitterionic COF exhibited excellent uptake capabilities for co-removal of cationic and anionic radionuclides. Exfoliating Covalent Organic Frameworks (COFs) into few-layer or even monolayer nanosheets not only improves the exposure of active sites and facilitates mass transfer efficiency, but also enhances their solubility or dispersion to achieve solution processability. As the Coulomb repulsion can weaken the stacking interactions, the construction of ionic COFs shows promising prospects for obtaining self-stripping nanosheets, but precisely controlling the self-exfoliated degree remains a challenge. Herein, we found for the first time that varying the number of hydroxyl groups in the building blocks could significantly affect the self-exfoliated degree for ionic COFs, and thus successfully produced a series of ionic COFs with stepwise solubility differences. Interestingly, the trend of self-exfoliated degree and solubility of cationic (EBCOFs) and anionic COFs (SDCOFs) were completely opposite to each other. Mechanistic studies indicated that more hydroxyl groups as electron donating groups increased the electron density of ionic COFs, resulting in a decrease in the Coulomb repulsion of cationic COFs (EBCOFs) but an increase in the Coulomb repulsion of anionic COFs (SDCOFs). Furthermore, in order to achieve the efficient co-removal of anionic and cationic radionuclides, we assembled cationic and anionic COF nanosheets through electrostatic attraction to obtain a novel zwitterionic COF (EB@SD COF) with both anion and cation adsorption sites. Impressively, EB@SD COF demonstrated rapid and efficient co-adsorption of ReO4- (a substitute for TcO4-) and Sr2+ with the maximum adsorption capacities of 117.6 and 122.4 mg/g, respectively. This work not only developed an effective zwitterionic COF adsorbent for the co-removal of radionuclides but also broadened the horizon of preparation methods for self-exfoliated ionic COFs.
ISSN:1385-8947
DOI:10.1016/j.cej.2024.154882