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High-temperature in-situ microscopy during stress-induced phase transformations in Co49Ni21Ga30 shape memory alloy single crystals

  • Jayaram Dadda , Hans J-rgen Maier , Ibrahim Karaman and Yuri Chumlyakov
Published/Copyright: June 11, 2013
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International Journal of Materials Research
From the journal International Journal of Materials Research Volume 101 Issue 12

Abstract

This paper reports on the role of repeated stress-induced martensite transformations at different temperatures (referred to as “training”) on the pseudoelasticity and microstructural evolution of as-grown Co49Ni21Ga30 [001]-oriented shape memory alloy single crystals under compression. The training resulted in a reduction in transformation stress levels and a stable microstructure with a multi-variant configuration reducing the observed transformation strains. Training also improved the recoverability giving way to a large pseudoelastic temperature window of 400°C. In-situ microscopy revealed the martensite stabilization to be due to pinning of moving interfaces especially at temperatures above 120°C. An insight into the evolution of microstructure and stressüstrain behavior in terms of stress hysteresis changes with test temperature is provided, and the possible operant mechanisms are discussed.

Keywords: Stress-induced martensite; High-temperature pseudoelasticity; Martensite stabilization; DIC; High-temperature shape memory alloys
* Correspondence address, Dr.-Ing. Jayaram Dadda, c/o Prof. Dr.-Ing. H. J. Maier, Lehrstuhl für Werkstoffkunde (LWK), University of Paderborn, Pohlweg 47ü49, 33098 Paderborn, Germany. Tel.: +49 5251 60 5235, Fax: +49 5251 60 3884. E-mail:

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Received: 2009-8-28
Accepted: 2010-9-10
Published Online: 2013-06-11
Published in Print: 2010-12-01

© 2010, Carl Hanser Verlag, München

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https://doi.org/10.3139/146.110427
Keywords for this article
Stress-induced martensite; High-temperature pseudoelasticity; Martensite stabilization; DIC; High-temperature shape memory alloys

Articles in the same Issue

  1. Basic
  2. High-temperature in-situ microscopy during stress-induced phase transformations in Co49Ni21Ga30 shape memory alloy single crystals
  3. Contents
  4. contents
  5. Editorial
  6. Editorial December 2010
  7. Basic
  8. Atomic mobilities and diffusivities in the fcc, L12 and B2 phases of the Ni-Al system
  9. Experimental investigation of the Zn–Fe–V system at 450°C
  10. Time resolved X-ray imaging of eutectic cellular patterns evolving during solidification of ternary Al–Cu–Ag alloys
  11. Reassessment of the Mg–Ge binary system using CALPHAD supported by first-principles calculation
  12. A quantitative modeling of the unloading behavior of metals during a tensile test
  13. A technique for diameter enlargement in SiC crystal growth
  14. Applied
  15. Thermal and chemical stability of Cr2AlC in contact with α-Al2O3 and NiAl
  16. Microstructure and mechanical properties of Zn25Al3Cu based composites with large Al2O3 particles at room and elevated temperatures
  17. An investigation on Incoloy800-SS304 clad plate by explosive welding
  18. Effect of grain boundary precipitates on vibration damping of FeüCrüMgüAl/Si alloy
  19. Adsorption of metal ions on magnetic carbon nanomaterials bearing chitosan-functionalized silica
  20. Tensile and in-vitro degradation study of electro spun fibrous mat produced from eri silk fibroin
  21. Study of the influence of UV-irradiation on the photodegradation of plasticized poly(para-tert-butylstyrene) films
  22. Enhanced photocatalytic activity of beryllium doped titania in visible light on the degradation of methyl orange dye
  23. Progress in chemistry modelling for vapour and aerosol transport analyses
  24. DGM News
  25. Personal
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