Hostname: page-component-cd9895bd7-lnqnp Total loading time: 0 Render date: 2024-12-29T10:38:30.104Z Has data issue: false hasContentIssue false

Grain Boundary Analysis of HT9 Steel after Accelerated Creep Testing

Published online by Cambridge University Press:  01 February 2011

Zhe Leng
Affiliation:
lengzhe2008@gmail.com, Washington State University, School of Mechanical and Materials Engineering, Pullman, Washington, United States
David Field
Affiliation:
lengzhe2008@gmail.com, Washington State University, School of Mechanical and Materials Engineering, Pullman, Washington, United States
Get access

Abstract

Ferritic/martensitic steels are attractive materials for use as components in nuclear reactors because of their high strength and good swelling resistance. Grain boundary specific phenomena (such as segregation, voiding, cracking, etc) are prevalent in these materials so grain boundary character is of primary importance. Certain types of boundaries are more susceptible to thermal creep damage whereas others tend to resist damage. If more damage resistant boundaries can be introduced into the structures, this will result in steel that is more resistant to the processes of degradation that prevail in high-temperature environments. We have characterized the grain boundary structure in HT9 steel by electron backscatter diffraction to identify boundaries that are resistant to degradation and those that are more susceptible to damage in extreme environments. It is found that intergranular damage is mitigated by a high fraction of low energy boundaries, and certain kinds of grain boundaries are more favored by intergranular cracks.

Type
Research Article
Copyright
Copyright © Materials Research Society 2010

Access options

Get access to the full version of this content by using one of the access options below. (Log in options will check for institutional or personal access. Content may require purchase if you do not have access.)

References

[1] Klueh, R.L. and Harries, D.R. ASTM, West Conshihocken (2001) p. 1.Google Scholar
[2] Kim, S.H. Ryu, W.S. and Kuk, I.H.: J. Kor. Nucl. Soc. 31 (1999) 561.Google Scholar
[3] Chang, Han-Jou, Kai, Ji-Jung, Tsai, Chuen-Horng, J. Nucl. Matls, 212–215 (1994) 574578 Google Scholar
[4] Field, D.P. and Adams, B.L., Metall. Trans, 23A (1992) 2515.Google Scholar
[5] Lillo, Thomas, Cole, James, Frary, Megan, and Schlegel, Scott, Metall. Mater. Trans 40A, (2009) 2803.Google Scholar
[6] Gourgues, A.F, Matls. Sci. Tech, 18 (2002) 119.Google Scholar
[7] Amodeo, Robert J. and Ghoniem, Nasr M., J. Nucl. Matls, 122–123 (1984) 91.Google Scholar
[8] G. Gupta, Ampornrat, P. Ren, X. Sridharan, K. Allen, T.R. Was, G.S., J. Nucl. Matls 361 (2007) 160.Google Scholar
[9] Fournier, B. Sauzay, M. Barcelo, F. Rauch, E. Renault, A. Cozzika, T. Dupuy, L. and Pineau, A. Metall. Mater. Trans 40A (2009) page 330341.10.1007/s11661-008-9687-yGoogle Scholar
[10] Watanabe, T. Tsurekawa, S. Kobayashi, S. and Yamaura, S. Material Science and Engineering A (2005), 410–411, 140147 Google Scholar
[11] Boehlert, C. J. and Longanbach, S. C. J. Material. Res, Vol. 23, No. 2, Feb 2008. 500506 Google Scholar
[12] Lillo, T. Cole, J. Frary, M. and Schlegel, S. Metallurgical and Materials transactions A, Vol. 40A Dec. 2009, 28032811.Google Scholar
[13] Watanable, T. Metall. Trans. A. 1983. 14A. 531545 Google Scholar
[14] Watanable, T. Res. Mech. 1984. 11. P47 Google Scholar
[15] Rohrer, G.S. and Randle, V. Electron Backscatter Diffraction in Material Science. Chapter 16, P215229.Google Scholar