Watcharotone et al. (2007) fabricat

Watcharotone et al. (2007) fabricated a transparent, electrical conductor by employing a simple sol-gel, spin-coating, chemical reduction, and thermal-curing route. The group used graphene oxide (GO) sheets mixed in the silica solution to obtain metal-encapsulated graphene nanocomposites [118]. In 2008, Chen et al. [119] fabricated graphene conducting paper that was electrically conducting, mechanically strong, and biocompatible. They uniformly dispersed graphene sheets in a solution using vacuum filtration followed by moderate thermal annealing. Recently, Cheng et al. (2013) synthesized carbon-coated SnO-graphene sheet composites in a green approach via a single-pot hydrothermal route. The composite was fabricated as an anode material for an Li-ion battery, and it exhibited high storage capacity and improved cyclic performance [120]. Similarly, Perera et al. (2013) synthesized V2O5 nanowire-graphene nanocomposite as an electrode material. The composite electrode exhibited an equilibrated electric double layer (EDL), energy density of 38.8 Wh kg−1, and pseudocapacitance at a power density of 455 W kg−1, and, also, the composite material showed a high specific capacitance of 80 F g−1. These results clearly indicate that the composite electrode was capable of effective storage and deliverance of charges toward high energy applications [121]. Lee et al. (2013) used cryomilling to synthesize fine particles of graphene and chitosan. The mixture was sonicated and layered to form a composite. The graphene particles conferred a cumulative effect in improving the mechanical attributes of the composite and also decreased the agglomeration quotient of graphene during mixing [122]. Guo et al. (2011) prepared a water-dispersed graphene-tryptophan-PVA nanocomposite for improving tensile strength, modulus, and thermal stability. There was a 23% increase in tensile strength when only a small loading of graphene (0.2 wt %) was introduced in the PVA matrix [123]. Ansari et al. (2013) studied the DC electrical conductivity retention of their indigenously prepared graphene-Pani-MWCNT nanocomposite in air and also assessed the cyclic aging. They found that Pani-graphene showed higher electrical conductivity and good stability for the DC electrical conductivity retention under isothermal conditions [124]. Jeon et al. (2012) prepared an exfoliated-grapheme- (EG-) cellulose acetate nanocomposite using the melt compounding method. They found that exfoliated graphene (EG) was uniformly dispersed in the host matrix with lower loadings. They also found that the composite had high thermal stability and improved conductivity and modulus [125]. The great number of application- and property-oriented possibilities suggests that future research and prospects for graphene-based nanocomposites are likely to expand tremendously in every discipline, with many surprises and products in store.