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Strain‐Induced Heteromorphosis Multi‐Cavity Cages: Tension‐Driven Self‐Expansion Strategy for Controllable Enhancement of Complexity in Supramolecular Assembly

Jun Wang, Zhilong Jiang, Jia‐Fu Yin, He Zhao, Qiangqiang Dong, Kaixiu Li, Wanying Zhong, Die Liu, Jie Yuan, Panchao Yin, Yiming Li, Yifan Lin, Mingzhao Chen, Pingshan Wang

2023Angewandte Chemie International Edition11 citationsDOI

Abstract

Abstract Coordinative supramolecular cages with adjustable cavities have found extensive applications in various fields, but the cavity modification strategies for multi‐functional structures are still challenging. Here, we present a tension‐driven self‐expansion strategy for construction of multi‐cavity cages with high structural complexity. Under the regulation of strain‐induced capping ligands, unprecedented heteromorphosis triple‐cavity cages S 2 / S 4 were obtained based on a metallo‐organic ligand (MOL) scaffold. The heteromorphosis cages exhibited significant higher cavity diversity than the homomorphous double‐cavity cages S 1 / S 3 ; all of the cages were thoroughly characterized through various analytical techniques including (1D and 2D) NMR, ESI‐MS, TWIM‐MS, AFM, and SAXS analyses. Furthermore, the encapsulation of porphyrin in the cavities of these multi‐cavity cages were investigated. This research opens up new possibilities for the architecture of heteromorphosis supramolecular cages via precisely controlled “scaffold‐capping” assembly with preorganized ligands, which could have potential applications in the development of multifunctional structures with higher complexity.

Topics & Concepts

Supramolecular chemistryPorphyrinMaterials scienceSmall-angle X-ray scatteringScaffoldNanotechnologySelf-assemblyCrystallographyChemistryOpticsComputer scienceScatteringCrystal structurePhysicsPhotochemistryDatabaseSupramolecular Chemistry and ComplexesSupramolecular Self-Assembly in MaterialsMolecular Sensors and Ion Detection