Plasticity of a two-phase composite with partially debonded inclusions

The effective elastoplastic behavior of a two-phase composite consisting of partially debonded elastic inclusions and a ductile matrix is investigated by a homogenization method. The method drew information from a recent study by the authors on the effective elastic moduli of the said composite and from an energy approach suggested by Qui and Weng, J. Appl. Mech., 59, 261 [1992] to address the homogenized plastic state of the heterogeneously deformed ductile matrix. Two types of partial debonding configuration are considered; the first is on the top and bottom of the aligned oblate inclusions and the other is on the lateral surface of the prolate ones, with special reference to spherical inclusions for both types of debonding. The transversely isotropic elastoplastic properties of the partially debonded composite are found to be highly dependent upon the debonding mode and the volume concentration and shape of inclusions. A damage mechanics based on Weibull's statistical function is also proposed to study the progressive partial debonding of the initially bonded composite under pure tension and under biaxial tension, respectively, for these two types of partial debonding. It is found that the interfacial strength, particle concentration, inclusion shape and debonding mode all play significant role in the overall response of the heterogeneous system during the progressive debonding process.