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Characterization of Shape Memory and Superelastic Effects by Instrumented Indentation Experiments

Published online by Cambridge University Press:  11 February 2011

Wangyang Ni
Affiliation:
Materials and Processes Laboratory, General Motors Research and Development Center, Warren, MI 48090, USA Department of Chemical Engineering and Materials Science, Michigan State University, East Lansing, MI, 48824, USA
Yang-Tse Cheng
Affiliation:
Materials and Processes Laboratory, General Motors Research and Development Center, Warren, MI 48090, USA
David S. Grummon
Affiliation:
Department of Chemical Engineering and Materials Science, Michigan State University, East Lansing, MI, 48824, USA
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Abstract

The shape memory and superelastic effects of martensitic and austenitic NiTi alloys were studied by instrumented indentation experiments. The shape memory effect was quantitatively characterized by the thermo-activated depth recovery ratio of the residual indentation depth. The superelasticity of austenitic NiTi was quantitatively characterized by the depth and work recovery ratios obtained from the load-displacement curves. The shape memory and superelastic effects under different indenters (Berkovich, Vickers, and spherical) and loads were rationalized using the concept of the representative strain and maximum strain. This study demonstrates that instrumented indentation techniques are useful in the quantitative characterization of the shape memory and superelastic effects in micro- and nano-meter length scale.

Type
Research Article
Copyright
Copyright © Materials Research Society 2003

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References

REFERENCES

[1] Otsuka, K., and Wayman, C. M., Shape Memory Alloys (Cambridge University Press, Cambridge, 1998).Google Scholar
[2] Richman, R. H., and McNaughton, W. P., Journal of Materials Engineering and Performance 6, 633641 (1997).Google Scholar
[3] Zhang, T., and Li, D. Y., Materials Science and Engineering A293, 208214 (2000).Google Scholar
[4] Hiraga, H., Inoue, T., Shimura, H., and Matsunawa, A., Wear 231, 272278 (1999).Google Scholar
[5] Singh, J., and Alpas, A. T., Wear 181–183, 302311 (1995).Google Scholar
[6] Liu, R., and Li, D. Y., Materials Science and Engineering A277, 169175 (2000).Google Scholar
[7] Ni, W., and Grummon, D. S., MRS Symp. Proc. 697, P2.9.1–P2.9.6 (2002).Google Scholar
[8] Liang, Y. N., Li, S. Z., Jin, Y.B., Jin, W., and Li, S., Wear 198, 236241 (1996).Google Scholar
[9] Lin, H. C., Wu, S. K., and Yeh, C. H., Wear 249, 557565 (2001).Google Scholar
[10] Cheng, F. T., Shi, P., and Man, H. C., Scripta Materialia 45, 1089 (2001).Google Scholar
[11] Liu, R., and Li, D., Wear 250–251, 956964 (2001).Google Scholar
[12] Ni, W., Cheng, Y. T., and Grummon, D. S., Applied Physics Letters 80, 33103312 (2002).Google Scholar
[13] Oliver, W. C., and Pharr, G. M., J. Mater. Res. 7, 15641583 (1992).Google Scholar
[14] Tabor, D., The Hardness of Metals (Oxford University Press, London, 1951).Google Scholar
[15] Tabor, D., Philosophical Magazine A 74, 12071212 (1996).Google Scholar
[16] Chaudhri, M. M., Acta mater. 46, 3047 (1998).Google Scholar
[17] Mata, M., Anglada, M., and Alcalá, J., J. Mat. Res. 17, 964 (2002).Google Scholar
[18] Lim, Y. Y., and Chaudhri, M. M., Phys. Stat. Sol. 194, 19 (2002).Google Scholar
[19] Ni, W., Cheng, Y.-T., and Grummon, D. S. (to be published).Google Scholar