Effect‐of Processing Varcables on Interfacial Properties of an SiG‐Fiber‐Reinforced Reaction‐Bonded Si3N4 Matrix Composite

Abstract

Fiber/matrix interfacial debonding and frictional sliding stresses were evaluated by single‐fiber pushout tests on unidirectional continuous silicon‐carbide‐fiber‐reinforced, reaction‐bonded silicon nitride matrix composites. The debonding and maximum pushout loads required to overcome interfacial friction were obtained from load–displacement plots of pushout tests. Interfacial debonding and frictional sliding stresses were evaluated for composites with various fiber contents and fiber surface conditions (coated and uncoated), and after matrix densification by hot isostatic pressing (HIPing). For as‐fabricated composites, both debonding and frictional sliding stresses decreased with increasing fiber content. The HIPed composites, however, exhibited higher interfacial debonding and frictional sliding stresses than those of the as‐fabricated composites. These results were related to variations in axial and transverse residual stresses on fibers in the composites. A shear‐lag model developed for a partially debonded composite, including full residual stress field, was employed to analyze the nonlinear dependence of maximum pushout load on embedded fiber length for as‐fabricated and HIPed composites. Interfacial friction coefficients of 0.1–0.16 fitted the experimental data well. The extremely high debonding stress observed in uncoated fibers is believed to be due to strong chemical bonding between fiber and matrix.