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Nanoporous N-Rich Covalent Organic Frameworks with High Specific Surface Area for Efficient Adsorption of Iodine and Methyl Iodide

Wen-Zhi She, Qiu‐Lin Wen, Hai-Chi Zhang, Jin-Zhou Liu, Rong Sheng Li, Jian Ling, Qiue Cao

2023ACS Applied Nano Materials51 citationsDOI

Abstract

With the rapid development of the nuclear industry, the effective treatment of radioactive iodine has become an urgent and challenging task. In this article, we synthesized a nanoporous nitrogen-rich covalent organic framework (TTA-DMTP-COF) with a specific surface area of up to 2332 m 2 /g for the adsorption of iodine (I 2 ) and methyl iodide (CH 3 I). Adsorption experiments showed that TTA-DMTP-COF exhibited effective I 2 and CH 3 I adsorption properties; the maximum adsorption capacity of I 2 is as high as 2.59 g·g –1, and the maximum adsorption capacity of CH 3 I is 1.60 g·g –1 . In addition, TTA-DMTP-COF can effectively adsorb iodine from an iodine–cyclohexane solution, and the adsorption amount is as high as 516.46 mg/g. Mechanistic studies have shown that I 2 and CH 3 I enter the nanopores of COF materials and form charge transfer complexes with various functional groups in TTA-DMTP-COF (including imines, triazine moieties, and residual amino groups). The N-methylation reaction specifically binds CH 3 I to the nucleophilic N site and generates polyiodides during the adsorption process. Our work demonstrates that TTA-DMTP-COF is an excellent candidate material capable of capturing radioactive iodine from air and solution in harsh environments.

Topics & Concepts

AdsorptionMethyl iodideCovalent organic frameworkNanoporousChemistryIodideIodineCovalent bondTriazineCyclohexaneOrganic chemistryInorganic chemistryCovalent Organic Framework ApplicationsMetal-Organic Frameworks: Synthesis and ApplicationsRadioactive element chemistry and processing