Gradient evolution in graphene reinforced carbon/carbon composites

Abstract

<p>Graphene-guided <a href="https://www.sciencedirect.com/topics/engineering/carbonization" title="Learn more about carbonization from ScienceDirect's AI-generated Topic Pages">carbonization</a> is an effective route to achieve carbon-reinforcement/carbon matrix (C/C) composites with high mechanical performance at lower energy consumption, due to the reduced anneal temperatures required. However, the underlying <a href="https://www.sciencedirect.com/topics/engineering/microstructure-evolution" title="Learn more about microstructure evolution from ScienceDirect's AI-generated Topic Pages">microstructure evolution</a> mechanisms associated with this phenomenon remain mysterious. Here, through large-scale reactive molecular dynamics simulations, we revealed a “<em>gradient evolution</em>” effect occurred in carbon matrix, which gives rise to the formation of additional stacked <a href="https://www.sciencedirect.com/topics/engineering/layer-graphene" title="Learn more about graphene layers from ScienceDirect's AI-generated Topic Pages">graphene layers</a> in the vicinity of the original introduced <a href="https://www.sciencedirect.com/topics/engineering/graphene-sheet" title="Learn more about graphene sheet from ScienceDirect's AI-generated Topic Pages">graphene sheet</a>. Two microstructure evolution pathways correlated with such effect are identified: (1) near the introduced graphene surface, one or two graphene-like layers rapidly developed due to the growth of curved carbon <a href="https://www.sciencedirect.com/topics/engineering/nanosheet" title="Learn more about nanosheets from ScienceDirect's AI-generated Topic Pages">nanosheets</a> via edge-crosslinking, (2) away from the graphene surface, graphene-like layers progressively promoted by reconstruction of dissociated <a href="https://www.sciencedirect.com/topics/engineering/disordered-carbon" title="Learn more about disordered carbon from ScienceDirect's AI-generated Topic Pages">disordered carbon</a> nanosheets. As a result, the graphene reinforced C/C composites exhibit significantly improved tensile modulus and strength in comparison to those without graphene. Our study not only provides fundamental insights into the graphene-induced carbonization phenomenon, but also emphasizes the unprecedented potential of graphene as an excellent reinforcement for C/C composites.</p>