吸附
钍
共价键
材料科学
铀
选择性吸附
金属有机骨架
选择性
无机化学
稀土
锕系元素
化学工程
金属
网络共价键合
共价结合
共价有机骨架
表面改性
放射性废物
动力学
纳米技术
作者
Shangui Chen,Kaili Yu,Xiaofang Su,Hui Hu,J. Zhao,Baoshan Wang,Zhongliang Wen,Afia Saleem,Mengdi Wang,Songtao Xiao,Yanan Gao
摘要
ABSTRACT Developing high‐efficiency adsorbents for the selective capture of thorium from uranium and rare earth elements necessitates integrating multiple critical functions, including strong adsorption ability, exceptional selectivity, and acid‐resistance performance, posing a technically challenging task. Herein, guided by the hard‐soft acid‐base (HSAB) principle, a series of imine‐linked covalent organic frameworks (COFs) functionalized by oxygen‐rich groups is designed and synthesized. The abundance of high‐affinity dual‐active N and O sites on the COF skeleton enables rapid adsorption kinetics and superior Th(IV) uptake. Particularly, TPT‐PA‐COOH and TPT‐PA‐SO 3 H exhibit record‐breaking saturated adsorption capacity and Th/U separation selectivity, making them the most efficient Th(IV) adsorbent reported to date. Especially, the introduction of –COOH or –SO 3 H groups renders the 2D COFs highly acid‐resistant, while keeping good Th(IV) adsorption capacity and selectivity even under harsh acidic conditions. These findings provide insight into the coordination mechanism between thorium and functional binding sites, thus advancing applications of COFs in the separation of thorium from radioactive wastewater.
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