Chenming Li, Pascal Mai, Niclas Festag, Anja Marinow, Wolfgang H Binder
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引用次数: 0
摘要
超分子键系统周围的分子环境会极大地影响其稳定性和主-客复合物的组装,其中以氢键(H 键)最为突出。众所周知,汉密尔顿受体-巴比妥酸主-客复合物在溶液中通常形成 1:1 摩尔比的复合物。然而,在聚合物基质中,这些复合物可以形成偏离标准 1:1 复合物的高阶组装,这对表征具有挑战性,通常需要采用实验室密集型方法。在本研究中,一种新型汉密尔顿受体(H)配备了环戊烯分子,并作为宿主与阿洛巴比妥(B)形成宿主-宿主复合物(H-B),然后进行共价交联。在不同溶剂和不同温度下进行的紫外可见光谱滴定实验表明,含有额外 H 键位点的极性溶剂会显著减少 1:1 H-B 复合物的形成,这表现在关联常数的降低上。高阶聚合体(HH-二聚体、HHH-三聚体)随后通过烯烃交叉嵌合(CM)反应共价固定,然后通过电喷雾离子化质谱(ESI MS)进行分析。这种先通过 CM 固定再通过 ESI MS 的两步法被扩展用于研究聚异丁烯(PIB)基质中的 H-B 模型复合物,从而提供了一种在无溶剂(聚合物)环境中分析复合物主-客体组装的直接方法。
Proximity Effects and Aggregation of Hamilton-Receptor Barbiturate Host-Guest Complexes Probed by Cross-Metathesis and ESI MS Analysis.
The molecular environment around supramolecular bonding systems significantly affects their stability and the assembly of host-guest complexes, most prominent for hydrogen bonds (H-bonds). Hamilton receptor-barbiturate host-guest complexes are well-known in solution, typically forming a 1 : 1 molar ratio complex. However, within a polymer matrix, these complexes can form higher-order assemblies, deviating from the standard 1 : 1 complex, which are challenging to characterize and often require lab-intensive methods. In this study, a novel Hamilton receptor (H) was equipped with cyclopentene moieties and used as a host to form host-guest complexes (H-B) with allobarbital (B), followed by covalent crosslinking. UV-Vis spectroscopy titration experiments in different solvents and at various temperatures revealed that polar solvents containing additional H-bonding sites significantly reduce the formation of the 1 : 1 H-B complex, as indicated by a reduced association constant. Higher-order aggregates (HH-dimer, HHH-trimer) were subsequently detected via an alkene cross-metathesis (CM) reaction to fix the assemblies covalently, followed by analysis via electrospray ionization mass spectrometry (ESI MS). This two-step method, firstly via CM fixation followed by ESI MS, was extended to study the H-B model complex within a polyisobutylene (PIB) matrix, presenting a direct method to analyze the complex host-guest assembly in solvent-free (polymer) environments.
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