4.7 Article

Deformation-induced microstructural evolution of fiber-matrix interface in pyrolytic carbon-carbon composites

Journal

ACTA MATERIALIA
Volume 242, Issue -, Pages -

Publisher

PERGAMON-ELSEVIER SCIENCE LTD
DOI: 10.1016/j.actamat.2022.118498

Keywords

Carbon; Composites; Graphitization; Pyrocarbon; Interface; Nanoindentation; Electron microscopy

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The mechanical properties of Carbon-Carbon (C/C) composites are greatly influenced by the strength of the fiber-matrix interface. However, little attention has been given to the pre-fracture behavior that determines this interface strength. This study investigates the structural changes caused by inelastic energy dissipation prior to fracture in C/C composites using flat-punch Nanoindentation coupled with Transmission Electron Microscopy (TEM). The results demonstrate that the dissipated energy causes graphitization of the composite and leads to a weakening of the interface, which is indicated by a reduction in basal interplanar spacing and relative Orientation Angle between crystallites within the fiber and matrix regions. A hypothesis is proposed that suggests a higher initial OA-mismatch results in a higher interface strength due to more energy dissipation. This study establishes the importance of pre-fracture microstructural evolution mechanisms in dictating interface strength and presents a novel hypothesis for the design of C/C mechanical properties.
Mechanical properties of Carbon-Carbon (C/C) composites critically depend on the fiber-matrix interfacestrength. However, almost no attention has been given to the pre-fracture behavior dictating this interface-strength. This study reports structural changes caused by inelastic energy dissipated prior to fracture, under flat-punch Nanoindentation. This test is coupled ex-situ with Transmission Electron Microscopy (TEM) to obtain electron-diffraction signatures. An axis-alignment procedure for semicrystalline carbon structures in the composite is proposed to obtain accurate diffraction data. Results reveal that the dissipated energy graphitizes the composite, evidenced by a reduction in basal interplanar spacing of graphitic crystallites within fiber and matrix regions. Furthermore, a drastic reduction in the relative Orientation Angle (OA) between crystallites of both regions is observed. Both these structural changes imply a progressive weakening of the interface leading toward fracture. A first hypothesis for interface-strength is forwarded proposing that a higher initial OA-mismatch allows more scope for energy-dissipation by the observed mechanisms to yield higher interface-strength. The proposed hypothesis is successfully corroborated by comparing two C/C materials having distinct heat-treatment histories. Thus, this study establishes the role of pre-fracture microstructural evolution mechanisms in dictating interface-strength and proposes a novel hypothesis for informed design of C/C mechanical properties. (c) 2022 Acta Materialia Inc. Published by Elsevier Ltd. All rights reserved.

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