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通过热力学和动力学协同控制结晶从较小和较大类似物中高度选择性分离中等尺寸阴离子污染物

Highly Selective Separation Intermediate-Size Anionic Pollutants from Smaller and Larger Analogs via Thermodynamically and Kinetically Cooperative-Controlled Crystallization.

作者信息

Mi Yongsheng, Zhao Chaofeng, Xue Shaomin, Ding Ning, Du Yao, Su Hui, Li Shenghua, Pang Siping

机构信息

School of Materials Science & Engineering Beijing Institute of Technology Beijing 100081 P. R. China.

出版信息

Adv Sci (Weinh). 2021 Feb 1;8(6):2003243. doi: 10.1002/advs.202003243. eCollection 2021 Mar.

DOI:10.1002/advs.202003243
PMID:33747732
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC7967070/
Abstract

Selective separation of organic species, particularly that of intermediate-size ones from their analogs, remains challenging because of their similar structures and properties. Here, a novel strategy is presented, cooperatively (thermodynamically and kinetically) controlled crystallization for the highly selective separation of intermediate-size anionic pollutants from their analogs in water through one-pot construction of cationic metal-organic frameworks (CMOFs) with higher stabilities and faster crystallization, which are based on the target anions as charge-balancing anions. 4,4'-azo-triazole and Cu are chosen as suitable ligand and metal ion for CMOF construction because they can form stronger intermolecular interaction with -toluenesulfonate anion (Ts-) compared to its analogs. For this combination, a condition is established, under which the crystallization rate of a Ts--based CMOF is remarkably high while those of analog-based CMOFs are almost zero. As a result, the faster crystallization and higher stability cooperatively endow the cationic framework with a close-to-100% selectivity for Ts- over its analogs in two-component mixtures, and this preference is retained in a practical mixture containing more than seven competing (analogs and inorganic) anions. The nature of the free Ts- anion in the cationic framework also allows the resultant CMOF to be recyclable via anion exchange.

摘要

有机物种的选择性分离,尤其是中等尺寸的有机物种与其类似物的分离,由于其结构和性质相似,仍然具有挑战性。在此,我们提出了一种新策略,即通过一锅法构建具有更高稳定性和更快结晶速度的阳离子金属有机框架(CMOFs),以协同(热力学和动力学)控制结晶,从而在水中从类似物中高度选择性地分离中等尺寸的阴离子污染物,这些CMOFs以目标阴离子作为电荷平衡阴离子。选择4,4'-偶氮三唑和铜作为构建CMOF的合适配体和金属离子,因为与类似物相比,它们可以与对甲苯磺酸根阴离子(Ts-)形成更强的分子间相互作用。对于这种组合,建立了一种条件,在此条件下,基于Ts-的CMOF的结晶速率非常高,而基于类似物的CMOF的结晶速率几乎为零。结果,更快的结晶速度和更高的稳定性协同赋予阳离子框架在两组分混合物中对Ts-相对于其类似物接近100%的选择性,并且这种偏好性在含有超过七种竞争性(类似物和无机)阴离子的实际混合物中得以保留。阳离子框架中游离Ts-阴离子的性质还使得所得的CMOF能够通过阴离子交换实现循环利用。

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