Redox-Responsive Halogen Bonding as a Highly Selective Interaction for Electrochemical Separations

IF 8.5 Q1 CHEMISTRY, MULTIDISCIPLINARY JACS Au Pub Date : 2024-06-10 DOI:10.1021/jacsau.4c0026510.1021/jacsau.4c00265
Nayeong Kim, Vijaya S. Jeyaraj, Johannes Elbert, Sung Jin Seo, Alexander V. Mironenko and Xiao Su*, 
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Abstract

Leveraging specific noncovalent interactions can broaden the mechanims for selective electrochemical separations beyond solely electrostatic interactions. Here, we explore redox-responsive halogen bonding (XB) for selective electrosorption in nonaqueous media, by taking advantage of directional interactions of XB alongisde a cooperative and synergistic ferrocene redox-center. We designed and evaluated a new redox-active XB donor polymer, poly(5-iodo-4-ferrocenyl-1-(4-vinylbenzyl)-1H-1,2,3-triazole) (P(FcTS-I)), for the electrochemically switchable binding and release of target organic and inorganic ions at a heterogeneous interface. Under applied potential, the oxidized ferrocene amplifies the halogen binding site, leading to significantly enhanced uptake and selectivity towards key inorganic and organic species, including chloride, bisulfate, and benzenesulfonate, compared to the open-circuit potential or the hydrogen bonding donor analog. Density functional theory calculations, as well as spectroscopic analysis, offer mechanistic insight into the degree of amplification of σ-holes at a molecular level, with selectivity modulated by charge transfer and dispersion interactions. Our work highlights the potential of XB in selective electrosorption by uniquely leveraging noncovalent interactions for redox-mediated electrochemical separations.

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氧化还原反应卤素键作为电化学分离的高选择性相互作用
利用特定的非共价相互作用可以拓宽选择性电化学分离的机制,而不仅仅是静电相互作用。在这里,我们利用 XB 与二茂铁氧化还原中心的定向相互作用,探索氧化还原反应卤键(XB)在非水介质中的选择性电吸附。我们设计并评估了一种新型氧化还原活性 XB 给体聚合物--聚(5-碘-4-二茂铁基-1-(4-乙烯基苄基)-1H-1,2,3-三唑)(P(FcTS-I)),用于在异质界面上电化学切换目标有机和无机离子的结合和释放。与开路电位或氢键供体类似物相比,在施加电位时,氧化二茂铁会放大卤素结合位点,从而显著增强对关键无机和有机物种(包括氯化物、硫酸氢盐和苯磺酸盐)的吸收和选择性。密度泛函理论计算和光谱分析从机理上揭示了σ孔在分子水平上的放大程度,选择性受电荷转移和弥散相互作用的调节。我们的工作通过独特地利用氧化还原介导的电化学分离中的非共价相互作用,突出了 XB 在选择性电吸附方面的潜力。
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9.10
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0.00%
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审稿时长
10 weeks
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Issue Editorial Masthead Issue Publication Information Announcing the Winner of the 2024 JACS Au Outstanding Paper Award Announcing the Winner of the 2024 JACS Au Outstanding Paper Award. Weak Base-Promoted Direct Cross-Coupling of Naphthalene-1,8-diaminato-substituted Arylboron Compounds
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