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Topologically Controlled Syntheses of Unimolecular Oligo[<i>n</i>]catenanes

Nathan D. Colley, Mark A. Nosiglia, Sheila L. Tran, Gray H. Harlan, Christy Chang, Ruihan Li, Abigail O. Delawder, Yipei Zhang, Jonathan C. Barnes

2022ACS Central Science23 citationsDOIOpen Access PDF

Abstract

Catenanes are a well-known class of mechanically interlocked molecules that possess chain-like architectures and have been investigated for decades as molecular machines and switches. However, the synthesis of higher-order catenanes with multiple, linearly interlocked molecular rings has been greatly impeded by the generation of unwanted oligomeric byproducts and figure-of-eight topologies that compete with productive ring closings. Here, we report two general strategies for the synthesis of oligo[n]catenanes that rely on a molecular “zip-tie” strategy, where the “zip-tie” is a central core macrocycle precursor bearing two phenanthroline (phen) ligands to make odd-numbered oligo[n]catenanes, or a preformed asymmetric iron(II) complex consisting of two macrocycle precursors bearing phen and terpyridine ligands to make even-numbered oligo[n]catenanes. In either case, preformed macrocycles or [2]catenanes are threaded onto the central “zip-tie” core using metal templation prior to ring-closing metathesis (RCM) reactions that generate several mechanical bonds in one pot. Using these synthetic strategies, a family of well-defined linear oligo[n]catenanes were synthesized, where n = 2, 3, 4, 5, or 6 interlocked molecular rings, and n = 6 represents the highest number of linearly interlocked rings reported to date for any isolated unimolecular oligo[n]catenane.

Topics & Concepts

CatenaneChemistryRing (chemistry)StereochemistryRing-closing metathesisCombinatorial chemistryMoleculeMetathesisNanotechnologyMaterials sciencePolymerizationOrganic chemistryPolymerSupramolecular Chemistry and ComplexesChemical Synthesis and AnalysisSupramolecular Self-Assembly in Materials