A green and solvent-free method for simultaneously producing graphene nanoplatelets, nanoscrolls, and nanodots and functionalizing their surface for epoxy nanocomposites
Mohannad Naeem Houshi , Mathias Aakyiir , Sanjay Stephen , Ruoyu Wang , Hsu-Chiang Kuan , Qingshi Meng , Jun Ma
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引用次数: 1
Abstract
Graphene is an emerging class of multifunctional additives for plastic manufacturing. However, achieving the exfoliation and dispersion of graphene in polymers such as epoxy has been a significant challenge, typically requiring chemical modification or oxidation as well as organic solvents and/or surfactants, because exceptionally high-surface area graphene often stack themselves. Herein we report the preparation, exfoliation, surface modification, and dispersion of graphene nanomaterials in epoxy by a simple ball milling process. The prepared graphene nanomaterials exhibit a range of morphologies, i.e. nanoplatelets, nanoscrolls, and nanodots. These materials demonstrate high electrical conductivity, 1750 ± 41 S/cm, for a film of ∼6 μm in thickness. Furthermore, as the graphene nanomaterials' surface was functionalized with amine groups for affinity with epoxy, the nanomaterials were found to disperse readily in epoxy. At 0.25 vol% of graphene, the epoxy nanocomposite exhibited a 52% increment of fracture toughness and an 11% increment of Young's modulus. Notably, an electrical percolation threshold was observed at 0.52 vol% for the nanocomposites.
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