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钯(μ-L)铂 钯(μ-L)钌氯:氯辅助配体作为M(μ-L)M'异二金属超分子结构主客体相互作用的决定性因素。

Pd(μ-L)Pt Pd(μ-L)RuCl: chlorido ancillary ligands as defining factors in the host-guest interactions of M(μ-L)M' heterodimetallic supramolecular architectures.

作者信息

Gearing Hayden B, Cziferszky Monika, Söhnel Tilo, Wright L James, Crowley James D, Hartinger Christian G

机构信息

School of Chemical Sciences, University of Auckland Private Bag 92019 Auckland 1142 New Zealand

Institute of Pharmacy/Pharmaceutical Chemistry, University of Innsbruck, Centre for Chemistry and Biomedicine Innrain 80-82/IV 6020 Innsbruck Austria.

出版信息

Chem Sci. 2025 Mar 24;16(17):7294-7301. doi: 10.1039/d5sc00209e. eCollection 2025 Apr 30.

DOI:10.1039/d5sc00209e
PMID:40171034
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC11956028/
Abstract

In supramolecular architectures, the interactions between host and guest molecules are governed by non-covalent forces such as hydrogen (H) bonding, hydrophobic and electrostatic interactions. We alter here the cavity microenvironment to control the interactions between guest and host molecules and study the effects of introducing axial chlorido ligands through the use of an octahedral building block in M(μ-L)M' architectures. We prepared the heterodimetallic Pd(μ-L)Pt C and Pd(μ-L)RuClC architectures and demonstrated the role of 'classic' non-covalent forces in their host-guest chemistry with anionic and neutral molecules, while the cages also underwent disassembly and reassembly upon addition of external stimuli. This culminated in the isolation of a 1 : 1 host-guest complex between C and the dianionic 1,5-naphthalenedisulfonate which was characterized by single crystal X-ray diffraction studies. These showed the guest occupied the central cavity and was held in place by H bonding. The -chlorido ligand in C played an important role in the capture of neutral guest molecules. In particular, it allowed for finetuning of the cavity properties of the supramolecular architectures by limiting the formation of H bonds and restricting the cavity size while offering alternative interactions.

摘要

在超分子结构中,主体分子与客体分子之间的相互作用由非共价力控制,如氢键、疏水相互作用和静电相互作用。我们在此改变空腔微环境以控制客体与主体分子之间的相互作用,并通过在M(μ-L)M'结构中使用八面体构建块来研究引入轴向氯配体的效果。我们制备了异二金属Pd(μ-L)Pt C和Pd(μ-L)RuClC结构,并证明了“经典”非共价力在它们与阴离子和中性分子的主客体化学中的作用,同时这些笼子在添加外部刺激时也会发生拆卸和重新组装。这最终导致分离出C与二价阴离子1,5-萘二磺酸盐之间的1∶1主客体配合物,该配合物通过单晶X射线衍射研究进行了表征。这些研究表明客体占据了中心空腔,并通过氢键固定在原位。C中的氯配体在捕获中性客体分子中起重要作用。特别是,它通过限制氢键的形成和限制空腔大小,同时提供替代相互作用,实现了对超分子结构空腔性质的微调。

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