PyC interphase growth mechanism and control models of C/SiC composites

To better understand the pyrocarbon (PyC) interphase growth mechanism, a series of experiments was conducted on the PyC deposited on T-300TM and T-700TM carbon fibers by the chemical vapor infiltration (CVI) method. Nine groups of fabrication parameters were used to analyze the effects of deposition temperature, pressure, and residence time on the PyC interphase growth mechanism. Atomic force microscopy (AFM), scanning electron microscopy (SEM), high-resolution transmission electron microscopy (TEM), X-ray diffraction analysis (XRD), Raman spectroscopy, and nanoindentation tests were performed to characterize the microstructures of carbon fibers and PyC interphase. The PyC interphase growth mechanism was discussed, and the relationships between the fabrication parameters, R (C2/C6) value, texture type, and interphase thickness were established through numerical simulations. The hardness and modulus of PyC for T-300TM and T-700TM carbon fibers were measured. The tensile behaviors of C/SiC minicomposites with medium and high textures PyC interphases were analyzed. The C/SiC composite with the medium texture PyC interphase possessed the higher fracture strength and failure strain with a longer fiber pullout length at the fracture surface.

Automated summary

A series of experiments were conducted to investigate the PyC interphase growth mechanism on T-300TM and T-700TM carbon fibers deposited by chemical vapor infiltration (CVI). Characterization techniques including AFM, SEM, TEM, XRD, Raman spectroscopy, and nanoindentation tests were used to analyze the microstructures. Numerical simulations were employed to establish the relationships between fabrication parameters, R (C2/C6) value, texture type, and interphase thickness. Hardness and modulus of PyC for T-300TM and T-700TM carbon fibers were measured. The tensile behaviors of C/SiC composites with different PyC interphases were analyzed, and the composite with medium texture PyC interphase showed better performance.