Improving the mechanical properties of graphene oxide based materials by covalent attachment of polymer chains

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Cano, M., Khan, U., Sainsbury, T., O'Neill, A., Wang, Z., McGovern, I.T., Maser, W.K., (...), Coleman, J.N., Improving the mechanical properties of graphene oxide based materials by covalent attachment of polymer chains, Carbon, 52, 2013, 363-371

Abstract

We report on the modification of graphene oxide (GO) with polyvinylalcohol (PVA) leading to the mechanical improvement of GO based materials. First, GO was covalently functionalised with PVA by esterification of carboxylic groups on GO with hydroxyl groups of PVA resulting in functionalised f-(PVA)GO. This was carried out for PVA of six different molecular weights. This functionalised graphene oxide could be formed into a paper-like material by vacuum filtration. Papers prepared from f-(PVA)GO showed significant increases in mechanical properties compared to those prepared with GO or with simple mixtures of GO and PVA. The best performance was achieved for PVA functional groups with molecular weights between 50 and 150 kg/mol. Improvements in Young?s moduli of 60% and tensile strength of 400% were observed relative to GO-only paper. The improved mechanical properties are attributed to enhanced inter-flake stress transfer due to the covalently bonded PVA. Second, functionalised f-(PVA)GO was used as filler in PVA-based composites. The application of a pre-selection method allowed the use of only the largest functionalised f-(PVA)GO flakes. This resulted in substantially reinforced PVA-f-(PVA)GO composites. Both modulus and strength increased by 40% relative to the pure polymer for f-(PVA)GO loadings below 0.3 vol.%.

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Sponsor: Science Foundation Ireland (SFI)
Grant Number: 07/IN.7/I1772

Author's Homepage: http://people.tcd.ie/colemaj
Type of material: Journal Article