Main-chain metallopolymers at the static–dynamic boundary based on nickelocene

Main-chain metallopolymers at the static–dynamic boundary based on nickelocene

2019-12-03 06:42:40

Interactions between metal ions and ligands in metal-containing polymers involve two bonding extremes: persistent covalent bonding, in which the polymers are essentially static in nature, or labile coordination bonding, which leads to dynamic supramolecular materials. Main-chain polymetallocenes based on ferrocene and cobaltocene fall into the former category because of the presence of strong metal–cyclopentadienyl bonds. Herein, we describe a main-chain polynickelocene—formed by ring-opening polymerization of a moderately strained [3]nickelocenophane monomer—that can be switched between static and dynamic states because of the relatively weak nickel–cyclopentadienyl ligand interactions. This is illustrated by the observation that, at a low concentration or at an elevated temperature in a coordinating or polar solvent, depolymerization of the polynickelocene occurs. A study of this dynamic polymer–monomer equilibrium by 1H NMR spectroscopy allowed the determination of the associated thermodynamic parameters. Microrheology data, however, indicated that under similar conditions the polynickelocene is considered to be static on the shorter rheological timescale. Main-chain polymetallocenes are typically static in nature due to strong metal–ligand bonding. Now, it has been shown that such polymers based on nickelocene are dynamic due to weaker nickel–cyclopentadienyl interactions, and at low concentration or at elevated temperature, depolymerization to the moderately strained monomer occurs.

Abstract

Interactions between metal ions and ligands in metal-containing polymers involve two bonding extremes: persistent covalent bonding, in which the polymers are essentially static in nature, or labile coordination bonding, which leads to dynamic supramolecular materials. Main-chain polymetallocenes based on ferrocene and cobaltocene fall into the former category because of the presence of strong metal–cyclopentadienyl bonds. Herein, we describe a main-chain polynickelocene—formed by ring-opening polymerization of a moderately strained [3]nickelocenophane monomer—that can be switched between static and dynamic states because of the relatively weak nickel–cyclopentadienyl ligand interactions. This is illustrated by the observation that, at a low concentration or at an elevated temperature in a coordinating or polar solvent, depolymerization of the polynickelocene occurs. A study of this dynamic polymer–monomer equilibrium by 1H NMR spectroscopy allowed the determination of the associated thermodynamic parameters. Microrheology data, however, indicated that under similar conditions the polynickelocene is considered to be static on the shorter rheological timescale.

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Acknowledgements

R.A.M., A.D.R., G.R.W. and I.M. thank the Engineering and Physical Sciences Research Council (EPSRC) for funding. D.W.H. is supported by a EPSRC doctoral training centre grant [EP/G036780/1]. The authors thank B. MacCreath for assistance in performing the DLS microrheology measurements.

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Affiliations

  1. School of Chemistry, University of Bristol, Cantock's Close, Bristol, BS8 1TS, UK

    • Rebecca A. Musgrave
    • , Andrew D. Russell
    • , Dominic W. Hayward
    • , George R. Whittell
    • , Paul G. Lawrence
    • , Paul J. Gates
    •  & Ian Manners

  2. Department of Chemistry, University of Oxford, Chemical Research Laboratory, Mansfield Road, Oxford, OX1 3TA, UK

    • Jennifer C. Green

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Contributions

R.A.M., A.D.R. and I.M. devised the project. R.A.M. carried out the experiments with assistance from A.D.R. The SAXS data were collected and analysed by D.W.H. Microrheology experiments were performed by R.A.M. and G.R.W. Paramagnetic NMR experiments were designed with assistance from P.G.L., mass spectrometry was performed by P.J.G. and computational chemistry was performed by J.C.G. The manuscript was written by R.A.M. with input from A.D.R., G.R.W. and I.M. The project was supervised by I.M. with input from G.R.W.

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Correspondence to Ian Manners.

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Musgrave, R., Russell, A., Hayward, D. et al. Main-chain metallopolymers at the static–dynamic boundary based on nickelocene. Nature Chem 9, 743–750 (2017) doi:10.1038/nchem.2743

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