In-situ characterization of damage evolution in metal matrix composites

Jay C. Hanan, Ersan Üstündag*, Irene J. Beyerlein, Jonathan D. Almer, Ulrich Lienert, Dean R. Haeffner

*Corresponding author for this work

Research output: Contribution to conferencePaperpeer-review

Abstract

A composite's local response to initial damage under stress is the primary micromechanical process determining its fracture toughness, strength, and lifetime. Through the use of high energy X-ray microdiffraction, the elastic lattice strains of both phases in a Ti-SiC composite were revealed providing the in-situ load transfer under applied tensile stress at the scale of the microstructure. To understand the damage evolution, the measured strains were compared to those predicted by a modified shear lag model. Comparisons between the model and the data demonstrated the importance of accounting for the matrix axial and shear stiffness, provided an optimal stiffness ratio for load transfer and planar interpretation of the geometry in the composite, showed the matrix within and around the damage zone sustained axial load, and highlighted matrix yielding observed in the composite. It was also shown that an area detector is essential in such a study as it provides multiaxial strain data and helps eliminate the "graininess" problem.

Original languageEnglish
Pages111-119
Number of pages9
Publication statusPublished - 2004
Externally publishedYes
EventICCM-14 - San Diego, CA, United States
Duration: 14 Jul 200318 Jul 2003

Conference

ConferenceICCM-14
Country/TerritoryUnited States
CitySan Diego, CA
Period14/07/0318/07/03

Keywords

  • Damage evolution
  • Mechanical properties
  • Metal matrix composites
  • Micromechanical modeling
  • X-ray diffraction

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