Cation Induced Changes to the Structure of Cryptophane Cages

IF 3.5 3区化学 Q2 CHEMISTRY, INORGANIC & NUCLEAR

Dalton Transactions Pub Date : 2024-09-26 DOI:10.1039/d4dt01824a

Oscar H. Lloyd Williams, Claudia S. Cox, Meng Y. Zhang, Martina Lessio, Olivia Rusli, William Donald, Lachlan Jekimovs, David Marshall, Michael Craig Pfrunder, Berwyck Poad, Thierry Brotin, Nicole Joy Rijs

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Abstract

Here the monocation complexes of seven anti-cryptophanes are examined with high-resolution ion-mobility mass spectrometry. The relative size of the [cation+cryptophane]⁺ complexes were compared based on their measured mobilities and derived collisional cross sections. A paradoxical trend of structural contraction was observed for complexes of increasing cation size. Density functional theory confirmed encapsulation occurs for cation = Na⁺, K⁺, Rb⁺, Cs⁺ and NH₄⁺. However, cation = Li⁺ preferred oxygen coordination at a linker over encapsulation within the cavity, leading to a slightly larger gas phase structure overall. Protonated cryptophanes yielded much larger collision cross sections via imploded cryptophane structures. Thus, competing physical effects led to the observed non-periodic size trend of the complexes. Trends in complexation from isothermal titration calorimetry and other condensed phase techniques were borne out by the gas phase studies. Further, predicted cavity sizes compared with the gas phase experimental findings reveal more about the encapsulation mechanisms themselves.

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阳离子诱导的色烷笼结构变化

本文采用高分辨率离子迁移率质谱法研究了七种抗色氨酸的单配位复合物。根据测得的迁移率和推导的碰撞截面，比较了[阳离子+色烷]+ 复合物的相对大小。在阳离子尺寸不断增大的复合物中，观察到了结构收缩的矛盾趋势。密度泛函理论证实，当阳离子=Na+、K+、Rb+、Cs+和NH4+时，会发生包裹。然而，阳离子 = Li+ 更倾向于在链接处氧配位，而不是在空腔内封装，从而导致气相结构总体略大。质子化隐烷通过内爆隐烷结构产生的碰撞截面要大得多。因此，相互竞争的物理效应导致了所观察到的复合物的非周期性大小趋势。气相研究证实了等温滴定量热法和其他凝聚相技术得出的络合趋势。此外，与气相实验结果相比，预测的空腔尺寸更能揭示封装机制本身。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Dalton Transactions 化学-无机化学与核化学

CiteScore

6.60

自引率

7.50%

发文量

1832

审稿时长

1.5 months

期刊介绍： Dalton Transactions is a journal for all areas of inorganic chemistry, which encompasses the organometallic, bioinorganic and materials chemistry of the elements, with applications including synthesis, catalysis, energy conversion/storage, electrical devices and medicine. Dalton Transactions welcomes high-quality, original submissions in all of these areas and more, where the advancement of knowledge in inorganic chemistry is significant.