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Pseudoelasticity in High Strengthening Fcc Single Crystals

Published online by Cambridge University Press:  10 February 2011

Yu.I. Chumlyakov ,
I. V. Kireeva ,
G. S. Kapasova  and
E. I. Litvinova
Yu.I. Chumlyakov
Affiliation:
Siberian Physical Technical Institute, 1, Revolution sq., Tomsk 634050, Russia, chum@phys.tsu.tomsk.su
I. V. Kireeva
Affiliation:
Siberian Physical Technical Institute, 1, Revolution sq., Tomsk 634050, Russia, chum@phys.tsu.tomsk.su
G. S. Kapasova
Affiliation:
Siberian Physical Technical Institute, 1, Revolution sq., Tomsk 634050, Russia, chum@phys.tsu.tomsk.su
E. I. Litvinova
Affiliation:
Siberian Physical Technical Institute, 1, Revolution sq., Tomsk 634050, Russia, chum@phys.tsu.tomsk.su
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Abstract

It was experimentally shown that the achievement of a high deforming stress level due to dispersion hardening and solid solution strengthening of FCC single crystals with a low stacking-fault energy leads to the deformation mechanism changing from slip to twinning, the dependence of mechanical properties on a crystal orientation and a sign of applied stresses. During deformation by twinning at T<150–300K effects of pseudoelasticity associated with elastic twinning is observed.

Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 459: Symposium Y – Materials for Smart Systems II , 1996 , 395
Copyright
Copyright © Materials Research Society 1997

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References

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