• Omara, Marcus A.
• Jurewicz, Izabela
• Salvage, Jonathan P.
• King, Alice A. K.
• Dalton, Alan B.
• Graf, Aline Amorim
• Sehnal, Anne C.
• Lynch, Peter J.
• Large, Matthew J.
• Ogilvie, Sean P.

Abstract

<p>Here, an approach is presented to incorporate graphene nanosheets into a silicone rubber matrix via solid stabilization of oil-in-water emulsions. These emulsions can be cured into discrete, graphene-coated silicone balls or continuous, elastomeric films by controlling the degree of coalescence. The electromechanical properties of the resulting composites as a function of interdiffusion time and graphene loading level are characterized. With conductivities approaching 1 S m⁻¹, elongation to break up to 160%, and a gauge factor of ≈20 in the low-strain linear regime, small strains such as pulse can be accurately measured. At higher strains, the electromechanical response exhibits a robust exponential dependence, allowing accurate readout for higher strain movements such as chest motion and joint bending. The exponential gauge factor is found to be ≈20, independent of loading level and valid up to 80% strain; this consistent performance is due to the emulsion-templated microstructure of the composites. The robust behavior may facilitate high-strain sensing in the nonlinear regime using nanocomposites, where relative resistance change values in excess of 10⁷ enable highly accurate bodily motion monitoring.</p>

Topics

• nanocomposite
• impedance spectroscopy
• microstructure
• rubber
• interdiffusion