Polyvinyl Alcohol-Few Layer Graphene Composite Films Prepared from Aqueous Colloids. Investigations of Mechanical, Conductive and Gas Barrier Properties

TL;DR

This study develops PVA films with few layer graphene via a simple aqueous colloid method, enhancing mechanical strength, electrical conductivity, and gas barrier properties, with potential applications in packaging and electronics.

Contribution

Introduces a rapid, bio-compatible exfoliation method for FLG in PVA films, achieving superior properties compared to GO-based composites.

Findings

Young's modulus maximized at 1% FLG

Electrical conductivity reaches 10^-3 S/cm at 3% FLG

Oxygen transmission reduced by up to 60%

Abstract

Quasi all water soluble composites use graphene oxide (GO) or reduced graphene oxide (rGO) as graphene based additives despite the long and harsh conditions required for their preparation. Herein, polyvinyl alcohol (PVA) films containing few layer graphene (FLG) are prepared by the co-mixing of aqueous colloids and casting, where the FLG colloid is first obtained via an effcient, rapid, simple, and bio-compatible exfoliation method providing access to relatively large FLG flakes. The enhanced mechanical, electrical conductivity, and O2 barrier properties of the films are investigated and discussed together with the structure of the films. In four different series of the composites, the best Young modulus is measured for the films containing around 1% of FLG. The most significant enhancement is obtained for the series with the largest FLG sheets contrary to the elongation at break which is well improved for the series with the lowest FLG sheets. Relatively high one-side electrical conductivity and low percolation threshold are achieved when compared to GO(rGO) composites (almost 10-3 S.cm-1 for 3% of FLG and transport at 0.5% FLG), while the conductivity is affected by the formation of a macroscopic branched FLG network. The composites demonstrate a reduction of O2 transmission rate up to 60%.