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Mechanical properties and oxidation resistance of phenolic formaldehyde interlocking CNTs-Cf/SiC composite

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Abstract To improve the mechanical properties and oxidation resistance of short carbon fiber reinforced silicon carbide matrix composites, carbon nanotubes (CNTs) were grown in-situ on carbon fiber surfaces through continuous… Click to show full abstract

Abstract To improve the mechanical properties and oxidation resistance of short carbon fiber reinforced silicon carbide matrix composites, carbon nanotubes (CNTs) were grown in-situ on carbon fiber surfaces through continuous CVD, a small amount of phenolic formaldehyde (PF) was added to the matrix to densify the composite and interlock the fiber and the matrix. The CNTs-Cf/PF/SiC composite was fabricated by combining pre-casting and hot-pressing. Microstructural analyses revealed that CNTs were successfully grown on carbon fiber surfaces with entangled structures, while PF presented cobweb-like structure which tightly bonded the fiber and the matrix. Compared with CNTs-Cf/SiC and Cf/SiC, the flexural strength of CNTs-Cf/PF/SiC increased by 15.27% and 51.95%. After heat treatment, the weight loss of CNTs-Cf/PF/SiC reached 21.05%, and 31.9% of flexural strength retained after 15 thermal shock cycles at 1400 °C. These enhanced properties were indicative of its enormous potential to replace traditional Cf/SiC composite.

Keywords: cnts sic; mechanical properties; properties oxidation; sic composite; oxidation resistance; fiber

Journal Title: Ceramics International
Year Published: 2019

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