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作为设计原型的抗癌剂:对含三芳基甲基部分离子液体结构-性质关系的见解。

Anticancer Agents as Design Archetypes: Insights into the Structure-Property Relationships of Ionic Liquids with a Triarylmethyl Moiety.

作者信息

Anderson Grace I, Hardy David, Hillesheim Patrick C, Wagle Durgesh V, Zeller Matthias, Baker Gary A, Mirjafari Arsalan

机构信息

Department of Chemistry and Physics, Florida Gulf Coast University, Fort Myers, Florida 33965, United States.

Department of Chemistry and Physics, Ave Maria University, Ave Maria, Florida 34142, United States.

出版信息

ACS Phys Chem Au. 2022 Dec 7;3(1):94-106. doi: 10.1021/acsphyschemau.2c00048. eCollection 2023 Jan 25.

DOI:10.1021/acsphyschemau.2c00048
PMID:36718259
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9881241/
Abstract

A fundamental challenge underlying the design principles of ionic liquids (ILs) entails a lack of understanding into how tailored properties arise from the molecular framework of the constituent ions. Herein, we present detailed analyses of novel functional ILs containing a triarylmethyl (trityl) motif. Combining an empirically driven molecular design, thermophysical analysis, X-ray crystallography, and computational modeling, we achieved an in-depth understanding of structure-property relationships, establishing a coherent correlation with distinct trends between the thermophysical properties and functional diversity of the compound library. We observe a coherent relationship between melting ( ) and glass transition ( ) temperatures and the location and type of chemical modification of the cation. Furthermore, there is an inverse correlation between the simulated dipole moment and the / of the salts. Specifically, chlorination of the ILs both reduces and reorients the dipole moment, a key property controlling intermolecular interactions, thus allowing for control over / values. The observed trends are particularly apparent when comparing the phase transitions and dipole moments, allowing for the development of predictive models. Ultimately, trends in structural features and characterized properties align with established studies in physicochemical relationships for ILs, underpinning the formation and stability of these new lipophilic, low-melting salts.

摘要

离子液体(ILs)设计原则背后的一个基本挑战是,人们对如何从组成离子的分子框架中产生定制特性缺乏了解。在此,我们对含有三芳基甲基(三苯甲基)基序的新型功能性离子液体进行了详细分析。结合经验驱动的分子设计、热物理分析、X射线晶体学和计算建模,我们深入了解了结构-性质关系,在化合物库的热物理性质和功能多样性之间的不同趋势建立了连贯的相关性。我们观察到熔点( )和玻璃化转变温度( )与阳离子化学修饰的位置和类型之间存在连贯关系。此外,盐的模拟偶极矩与 / 之间存在负相关。具体而言,离子液体的氯化既降低了偶极矩又使其重新定向,这是控制分子间相互作用的关键性质,从而实现了对 / 值的控制。在比较相变和偶极矩时,观察到的趋势尤为明显,这有助于开发预测模型。最终,结构特征和表征性质的趋势与离子液体物理化学关系的既定研究一致,为这些新型亲脂性低熔点盐的形成和稳定性提供了支撑。

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