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Diastereoselective Self‐Assembly of Low‐Symmetry Pd <sub> <i>n</i> </sub> L <sub> 2 <i>n</i> </sub> Nanocages through Coordination‐Sphere Engineering**

Paulina Molinska, Andrew Tarzia, Louise Male, Kim E. Jelfs, James E. M. Lewis

2023Angewandte Chemie International Edition43 citationsDOIOpen Access PDF

Abstract

Abstract Metal‐organic cages (MOCs) are popular host architectures assembled from ligands and metal ions/nodes. Assembling structurally complex, low‐symmetry MOCs with anisotropic cavities can be limited by the formation of statistical isomer libraries. We set out to investigate the use of primary coordination‐sphere engineering (CSE) to bias isomer selectivity within homo‐ and heteroleptic Pd n L 2 n cages. Unexpected differences in selectivities between alternative donor groups led us to recognise the significant impact of the second coordination sphere on isomer stabilities. From this, molecular‐level insight into the origins of selectivity between cis and trans diastereoisomers was gained, highlighting the importance of both host–guest and host‐solvent interactions, in addition to ligand design. This detailed understanding allows precision engineering of low‐symmetry MOC assemblies without wholesale redesign of the ligand framework, and fundamentally provides a theoretical scaffold for the development of stimuli‐responsive, shape‐shifting MOCs.

Topics & Concepts

NanocagesCoordination sphereSymmetry (geometry)MetalSelf-assemblyMetal ions in aqueous solutionCrystallographyIonSelectivityMaterials scienceChemistryNanotechnologyGeometryMathematicsOrganic chemistryCatalysisMetal-Organic Frameworks: Synthesis and ApplicationsSupramolecular Chemistry and ComplexesMagnetism in coordination complexes
Diastereoselective Self‐Assembly of Low‐Symmetry Pd <sub> <i>n</i> </sub> L <sub> 2 <i>n</i> </sub> Nanocages through Coordination‐Sphere Engineering** | Litcius