Abstract:A modified effective medium assumption (EMA) model was adapted to quantitatively calculate the effects of matrix properties, size distribution of silicon carbide particles and interfacial decohesion on the elastoplastic deformation behavior in Al matrix composites reinforced by SiC particles with average size 5 μm and volume fraction 12%. The theoretical results coincided well with the stress strain correlation obtained from experiment. The current research indicated that loading transfer from matrix to reinforcement, grain refinement in matrix and high density dislocation originating from difference of thermal expansion coefficient between SiC particles and Al matrix heighten the flow stress of the composites, but interfacial decohesion is opposite. The loading transfer, grain refinement and dislocation strengthening are the main strengthening mechanism of 12%SiC(5 μm)/Al composites, and interfacial decohesion and ductile fracture of Al matrix are the dominating fracture modes in the composites.