TY - JOUR
T1 - The Role of Interlayer Adhesion in Graphene Oxide upon Its Reinforcement of Nanocomposites
AU - Li, Zheling
AU - Kinloch, Ian
AU - Young, Robert
N1 - Supplementary material Supplementary material consisting of the analysis of damage and unloading behaviour, and original data sets in a Powerpoint file are available for this paper.
PY - 2016/5/30
Y1 - 2016/5/30
N2 - Graphene oxide (GO) has become a well-established reinforcement for polymer-based nanocomposites. It provides stronger interfacial interaction with the matrix when compared with that of graphene, but its intrinsic stiffness and strength are somewhat compromised because of the presence of functional groups damaging the graphene lattice and increasing its thickness, and its tendency to adopt a crumpled structure. Although the micromechanics of graphene reinforcement in nanocomposites has been studied widely, the corresponding micromechanics investigations on GO have not been undertaken in such detail. In this work, it is shown that the deformation micromechanics of GO can be followed using Raman spectroscopy and the observed behaviour can be analysed with continuum mechanics. Furthermore, it is shown that the reinforcement efficiency of GO is independent of its number of layers and stacking configurations, indicating that it is not necessary to ensure a high degree of exfoliation of GO in the polymer matrix. It also demonstrates the possibility of increasing the concentration of GO in nanocomposites without sacrificing mechanical reinforcement efficiency.
AB - Graphene oxide (GO) has become a well-established reinforcement for polymer-based nanocomposites. It provides stronger interfacial interaction with the matrix when compared with that of graphene, but its intrinsic stiffness and strength are somewhat compromised because of the presence of functional groups damaging the graphene lattice and increasing its thickness, and its tendency to adopt a crumpled structure. Although the micromechanics of graphene reinforcement in nanocomposites has been studied widely, the corresponding micromechanics investigations on GO have not been undertaken in such detail. In this work, it is shown that the deformation micromechanics of GO can be followed using Raman spectroscopy and the observed behaviour can be analysed with continuum mechanics. Furthermore, it is shown that the reinforcement efficiency of GO is independent of its number of layers and stacking configurations, indicating that it is not necessary to ensure a high degree of exfoliation of GO in the polymer matrix. It also demonstrates the possibility of increasing the concentration of GO in nanocomposites without sacrificing mechanical reinforcement efficiency.
U2 - 10.1098/rsta.2015.0283
DO - 10.1098/rsta.2015.0283
M3 - Article
SN - 1471-2946
VL - 374
JO - Royal Society of London. Proceedings A. Mathematical, Physical and Engineering Sciences
JF - Royal Society of London. Proceedings A. Mathematical, Physical and Engineering Sciences
M1 - 20150283
ER -