Abstract
Finite element method (FEM) is a powerful tool to predict the properties and reveal the mechanisms of metal-matrix composites (MMCs) with very complex architectures and novel microstructures. Recent studies have demonstrated the effectiveness of network reinforcement architectures on simultaneous strengthening and toughening. Here, as a key factor in modeling network architecture, the critical microstructure size was studied via FEM. We found that a critical microstructure size of 23 [Formula: see text]m (cell count [Formula: see text]20) existed in the FEM model, beyond which the crack deflection may be feasibly induced from particle-rich to matrix regions, leading to crack propagation in the ductile matrix cells and thus high strength and elongation. While, with cell size 20–23 [Formula: see text]m in SiC/6061Al model, the composite strength and elongation remained intact, implying that the maximal microstructure size is 23 [Formula: see text]m for effective network architecture simulations.
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