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Rational design of metal–organic cages to increase the number of components via dihedral angle control

Tsukasa Abe, Keisuke Takeuchi, Masahiro Higashi, Hirofumi Sato, Shûichi Hiraoka

2024Nature Communications19 citationsDOIOpen Access PDF

Abstract

The general principles of discrete, large self-assemblies composed of numerous components are not unveiled and the artificial formation of such entities is a challenging topic. In metal–organic cages, design strategies for tuning the coordination directions in multitopic ligands by the bend and twist angles were previously developed to solve this problem. In this study, the importance of remote geometric communications between components is emphasized, realizing several types of metal–organic assemblies based on dihedral angle control in multitopic ligands although they have the same coordination directions. Self-assembly of a tritopic ligand with dihedral angles θ = 36.5° and a cis-protected Pd(II) ion affords M9L6 and M12L8 cages as kinetic and thermodynamic products, respectively, whereas an M12L8 sheet is formed when θ = 90°. Geometric analyses of strains in the subcomponent rings reveals that remote geometric communications among neighboring multitopic ligands through coordination bonds are key for large assemblies. General design principles for self-assembly of discrete, large metal-organic cages composed of numerous components are challenging to develop. Here, the authors use remote geometric communications between components to realize several types of metal–organic assemblies based on dihedral angle control in multitopic ligands.

Topics & Concepts

Dihedral angleRational designMetalMaterials scienceChemistryNanotechnologyOrganic chemistryMetallurgyHydrogen bondMoleculeSupramolecular Chemistry and ComplexesMagnetism in coordination complexesSupramolecular Self-Assembly in Materials