The effect of temperature on the chemistry and morphology of the interphase in an SCS6/Ti–6Al–4V metal matrix composite

C. Jones; C. J. Kiely; S. S. Wang

doi:10.1557/JMR.1990.1435

Abstract

The changes in the chemistry and morphology within the interphase region of an SCS6/Ti–6A1–4V metal matrix composite upon exposing the samples to varying heat treatments have been studied using Auger electron spectroscopy, TEM and convergent beam diffraction techniques. These changes, such as the formation of small TiC particles at one interface and the narrowing of a protective pyrocarbon layer at another, induce fracture to occur at different places within the interphase upon heating. The reasons for this are explained. Evidence for a change in phase of a TixSiy(C) layer to the more thermodynamically stable Ti5Si3 is also given.

References

¹Martineau, P., Lahaye, M., Pailler, R., Naslain, R., Couzi, M., and Cruege, F., J. Mater. Sci. 19, 2731 (1984).CrossRef Google Scholar

²Martineau, P., Pailler, R., Lahaye, M., and Naslain, R., J. Mater. Sci. 19, 2749 (1984).CrossRef Google Scholar

³Pailler, R., Martineau, P., Lahaye, M., and Naslain, R., Revue de Chimie Minerale 18, 520 (1981).Google Scholar

⁴Debolt, H. E., Suplinskas, R. J., Cornie, J. A., Henze, T. W., and Hauze, W., U.S. Patent 4340636, July 20 (1982).Google Scholar

⁵Jones, C., Kiely, C. J., and Wang, S. S., J. Mater. Res. 4 (2), 327 (1989).CrossRef Google Scholar

⁶Brukl, C. E., AFML TR-65–2, Part 2, U. S. Air Force Materials Laboratories, Wright-Patterson AFB, OH, 7 (1965).Google Scholar

⁷Nutt, S. R. and Wawner, F. E., J. Mater. Sci. 20, 1953 (1985).CrossRef Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Reeves, A. J. Dunlop, H. and Clyne, T. W. 1992. The effect of interfacial reaction layer thickness on fracture of titanium-SiC particulate composites. Metallurgical Transactions A, Vol. 23, Issue. 3, p. 977.

Warrier, S.G. and Lin, R.Y. 1993. Interfacial reactions in titanium/SCS fiber composites during fabrication. Scripta Metallurgica et Materialia, Vol. 28, Issue. 3, p. 313.

Ferraris, M. Badini, C. Marino, F. Marchetti, F. and Girardi, S. 1993. Interfacial reactions in a Ti-6Al-4V based composite: role of the TiB2 coating. Journal of Materials Science, Vol. 28, Issue. 7, p. 1983.

Turner, S. P. Taylor, R. Gordon, F. H. and Clyne, T. W. 1993. Thermal conductivities of Ti-SiC and Ti-TiB2 particulate composites. Journal of Materials Science, Vol. 28, Issue. 14, p. 3969.

Valente, T. and Bartuli, C. 1994. A plasma spray process for the manufacture of long-fiber reinforced Ti-6Al-4V composite monotapes. Journal of Thermal Spray Technology, Vol. 3, Issue. 1, p. 63.

Badini, C. Ferraris, M. and Marchetti, F. 1994. Thermal stability of interfaces in Ti-6Al-4V reinforced by SiC Sigma fibres. Journal of Materials Science, Vol. 29, Issue. 18, p. 4840.

Warrier, S. G. Chen, S. H. Wu, S. K. and Lin, R. Y. 1996. Interface characterization of ceramic fiber-reinforced ti alloy composites manufactured by infrared processing. Metallurgical and Materials Transactions A, Vol. 27, Issue. 5, p. 1379.

Warrier, S. G. and Lin, R. Y. 1996. Infrared infiltration and properties of SCS-6/Ti alloy composites. Journal of Materials Science, Vol. 31, Issue. 7, p. 1821.

Johnson, WS Masters, JE Wilson, DW Valente, T and Carassiti, F 1996. Hot Pressing of Plasma-Sprayed SiC Fiber-Reinforced Ti-6Al-4V Alloy. Journal of Composites Technology and Research, Vol. 18, Issue. 2, p. 89.

Oral, B. Ernst, K.-H. and Schmutz, C.J. 1996. Adhesion and structural changes of multi-layered and multi-doped a-C:H films during annealing. Diamond and Related Materials, Vol. 5, Issue. 9, p. 932.

Thomas, M. P. Bate, S. Robertson, G. and Winstone, M. R. 1998. Development of novel specimens for mechanical testing of fibre reinforced titanium metal matrix composite. Materials Science and Technology, Vol. 14, Issue. 9, p. 1009.

Vahlas, Constantin Hall, Ian W. and Haurie, Isabelle 1999. Investigation of interfacial reactivity in composite materials. Materials Science and Engineering: A, Vol. 259, Issue. 2, p. 269.

Rawal, Suraj P. 2001. Interface structure in graphite‐fiber‐reinforced metal–matrix composites. Surface and Interface Analysis, Vol. 31, Issue. 7, p. 692.

Hung, Y.-C. and Withers, P.J. 2012. Fibre bridging during high temperature fatigue crack growth in Ti/SiC composites. Acta Materialia, Vol. 60, Issue. 3, p. 958.

Wu, Ming Zhang, Kan Huang, Hao Li, Hu Wang, Minjuan Zhang, Shuming Chen, Jianhong and Wen, Mao 2017. Temperature-dependent evolution of interfacial zones in SiCf/C/Ti17 composites. RSC Advances, Vol. 7, Issue. 72, p. 45327.

Wang, Ying Xu, Xu Zhao, Wenxia Li, Nan McDonald, Samuel A. Chai, Yuan Atkinson, Michael Dobson, Katherine J. Michalik, Stefan Fan, Yingwei Withers, Philip J. Zhou, Xiaorong and Burnett, Timothy L. 2021. Damage accumulation during high temperature fatigue of Ti/SiCf metal matrix composites under different stress amplitudes. Acta Materialia, Vol. 213, Issue. , p. 116976.

Article contents

The effect of temperature on the chemistry and morphology of the interphase in an SCS6/Ti–6Al–4V metal matrix composite

Abstract

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

The effect of temperature on the chemistry and morphology of the interphase in an SCS6/Ti–6Al–4V metal matrix composite

Abstract

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests