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在芴酮支架中形成对称性降低和角度偏差的钯分子篮状结构以调控钯三面管的主客体化学。

Formation of a Pd Molecular Basket Architecture of Reduced Symmetry and Angular Deviation in a Fluorenone Scaffold to Govern the Host-Guest Chemistry of Pd Trifacial Tubes.

作者信息

Aggarwal Medha, Banerjee Ranit, Hickey Neal, Mukherjee Partha Sarathi

机构信息

Department of Inorganic and Physical Chemistry, Indian Institute of Science, Bangalore 560012, India.

Department of Chemical and Pharmaceutical Sciences, University of Trieste, Trieste 34127, Italy.

出版信息

JACS Au. 2025 May 9;5(5):2368-2378. doi: 10.1021/jacsau.5c00390. eCollection 2025 May 26.

DOI:10.1021/jacsau.5c00390
PMID:40443883
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12117451/
Abstract

The employment of flexible ligands with significant conformational freedom in coordination-driven self-assembly enables the formation of unique and intricate structures. In this study, the self-assembly of such a fluorenone-appended ligand () with a sterically demanding acceptor, [Pd-(tmed)-(ONO)] (), generated a new and unique molecular basket architecture, () () (), featuring a large hollow cavity. possesses an unusual twisted architecture of low symmetry, consisting of 16 Pd-(II) centers arranged as four tetrahedra connected by eight flexible ligands, representing a structurally complex system reminiscent of biological architectures. Designing such entropically disfavored, large architectures of reduced symmetry is challenging but desirable, since they can act as ideal models to study complicated natural systems. The host-guest property of supramolecular hosts is governed by the confined cavities and noncovalent interactions, which are dictated by the angular disposition of ligand coordination sites. To explore this, the fluorenone scaffold was used to synthesize two other tetradentate ligands ( and ) that differed in the spatial distributions of their coordination vectors. The self-assembly of these ligands with [Pd-(en)-(ONO)] () resulted in the formation of water-soluble () (//) trifacial tubes of different geometries with varying internal cavity dimensions. These angular variations further altered the orientation of the fluorenone carbonyl groups within the cavities, thereby modulating their guest binding abilities and highlighting the importance of tailoring supramolecular hosts for specific guest binding.

摘要

在配位驱动的自组装中使用具有显著构象自由度的柔性配体能够形成独特而复杂的结构。在本研究中,这种带有芴酮的配体()与位阻较大的受体[Pd-(tmed)-(ONO)]()自组装,生成了一种新的独特分子篮状结构() () (),其具有一个大的中空腔。 具有不寻常的低对称性扭曲结构,由16个Pd-(II)中心排列成四个通过八个柔性配体连接的四面体组成,代表了一个让人联想到生物结构的结构复杂系统。设计这种熵不利的、对称性降低的大型结构具有挑战性但很有必要,因为它们可以作为研究复杂自然系统的理想模型。超分子主体的主客体性质由受限的空腔和非共价相互作用决定,这些相互作用由配体配位位点的角度配置决定。为了探究这一点,芴酮支架被用于合成另外两种四齿配体( 和 ),它们的配位向量空间分布不同。这些配体与[Pd-(en)-(ONO)]()自组装,形成了具有不同内部空腔尺寸的不同几何形状的水溶性() (//) 三面管。这些角度变化进一步改变了空腔内芴酮羰基的取向,从而调节了它们的客体结合能力,并突出了为特定客体结合定制超分子主体的重要性。

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