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Journal of Materials Science

, Volume 44, Issue 9, pp 2247–2256 | Cite as

First report on observation of abnormal creep in a Zr–2.5wt.%Nb alloy at low stresses

  • R. Kishore
  • S. Banerjee
  • P. Rama Rao
Festschrift in honour of Prof T R Anantharaman on the occasion of his 80th birthday

Abstract

Low-stress creep behaviour of a two-phase Zr–2.5%Nb alloy, differently heat treated, has been investigated using helical test specimens. The phase diagram of the α (hcp) + β (bcc) alloy is characterized by the monotectoid reaction at 893 ± 10 K: β1 → (α + β2) where β1 (Zr–20Nb) and β2 (Zr–80Nb) have widely differing compositions. At the creep testing temperature, 818 K, which is close to but below the monotectoid temperature, the creep rate for samples with the equilibrium α + β2 structure has been found to be considerably higher, over an order of magnitude, than that in samples with the metastable α + β1 structure. Microstructural changes accompanying the markedly enhanced creep rate for the α + β2 structure at stresses as low as 1–4 MPa have been explained in terms of the relative stability of the β1 and the β2 phases during the creep process. An attempt has been made to elicit the likely mechanism underlying the observed enhancement of creep rate and the changes in morphology, composition and volume fraction of the β phase.

Keywords

Creep Rate Creep Deformation Diffusional Creep Creep Process Pressurize Heavy Water Nuclear Reactor 

Notes

Acknowledgements

One of us (P. Rama Rao) is grateful to the Indian Space Research Organization for the award of a Professorship. The authors place on record their grateful thanks to Dr. G. Malakondaiah of Defence Metallurgical Research Laboratory for his valuable suggestions and to Professor G.W. Greenwood of the University of Sheffield, UK for his helpful comments.

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Copyright information

© Springer Science+Business Media, LLC 2008

Authors and Affiliations

  1. 1.Bhabha Atomic Research Centre, TrombayMumbaiIndia
  2. 2.International Advanced Research Centre for Powder Metallurgy and New Materials (ARCI)Balapur, HyderabadIndia

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