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Fiber strength utilization in carbon/carbon composites

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Abstract

The utilization of tensile strength of carbon fibers in unidirectional carbon/carbon (C/C) composites was studied for a series of four mesophase-pitch-based carbon fibers in a carbon matrix derived from a polyarylacetylene (PAA) resin. The fibers had moduli of 35, 75, 105, and 130 Mpsi. Composite processing conditions ranged from the cured-resin state to various heat-treatment temperatures (HTT’s) from 1100 to 2750 °C for the C/C’s. Room-temperature tensile strength and modulus were measured for the various processing conditions, and were correlated with SEM observations of fracture surfaces, fiber and matrix microstructures, and fiber/matrix interphase structures. Fiber tensile strength utilization (FSU) is defined as the ratio of apparent fiber strength in the C/C to the fiber strength in an epoxy-resin-matrix composite. Carbonization heat treatment to 1100 °C results in a brittle carbon matrix that bonds strongly with the three lower modulus fibers, resulting in matrix-dominated failure at FSU values of 24 to 35%. However, the composite with the 130-Mpsi-modulus filament had an FSU of 79%. It is attributed to a combination of tough fracture within the filament itself and a weaker fiber/matrix interface. Both factors lead to crack deflection and blunting rather than to crack propagation. The presence of a weakened interface is inferred from observations of fiber pullout. Much of the FSU of the three lower modulus fibers is recovered by HTT to 2100 or 2400 °C, principally as a result of interface weakening, which works to prevent matrix-dominated fracture. With HTT to 2750 °C, there is a drop in FSU for all the composites; it is apparently the result of a combination of fiber degradation and reduced matrix stress-transfer capability.

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Authors and Affiliations

  1. Mechanics and Materials Technology Center, The Aerospace Corporation, 90245, El Segundo, California, USA

    Rafael J. Zaldivar & Gerald S. Rellick

  2. Department of Materials Science and Engineering, University of California, 90024, Los Angeles, California, USA

    J. M. Yang

Authors
  1. Rafael J. Zaldivar
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  2. Gerald S. Rellick
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  3. J. M. Yang
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Zaldivar, R.J., Rellick, G.S. & Yang, J.M. Fiber strength utilization in carbon/carbon composites. Journal of Materials Research 8, 501–511 (1993). https://doi.org/10.1557/JMR.1993.0501

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  • DOI: https://doi.org/10.1557/JMR.1993.0501

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