Orientation dependence of cyclic stability of superelasticity of Ti 50.2 Ni 49.8  alloy single crystals under compression

I. V. Kireeva; Киреева И. В.; Yu. I. Chumlyakov; Чумляков Ю. И.; A. V. Vyrodova; Выродова А. В.; A. A. Saraeva; Сараева А. А.; Z. V. Pobedennaya; Победенная З. В.; E. C. Marchenko; Марченко Е. С.

doi:10.31857/S0015323024080131

Orientation dependence of cyclic stability of superelasticity of Ti_50.2Ni_49.8 alloy single crystals under compression

Authors: Kireeva I.V.¹, Chumlyakov Y.I.¹, Vyrodova A.V.¹, Saraeva A.A.¹, Pobedennaya Z.V.¹, Marchenko E.C.¹
Affiliations:
1. Siberian Physical-Technical Institute, National Research Tomsk State University
Issue: Vol 125, No 8 (2024)
Pages: 1029-1038
Section: СТРУКТУРА, ФАЗОВЫЕ ПРЕВРАЩЕНИЯ И ДИФФУЗИЯ
URL: https://journal-vniispk.ru/0015-3230/article/view/280219
DOI: https://doi.org/10.31857/S0015323024080131
EDN: https://elibrary.ru/JVTAEY
ID: 280219

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Abstract

The effect of marforming (low-temperature compression deformation of В19′-martensite at 203 K and subsequent annealing at 713 K for 0.5 h) on superelasticity (SE), temperature range of SE, and cyclic stability of superelastic behavior 323 K are studied on [001]_В₂ and [ $1$ 12]_В₂ single crystals of the Ti_50.2Ni_49.8 (at %) alloy under compression. It is shown that marforming leads to an increase in the offset yield strength σ_0.1 of the high-temperature В2-phase and to the development of SE, which was not observed in quenched crystals. The orientation dependence of the SE temperature range and the cyclic stability of superelastic behavior, which is determined by the orientation dependence of the σ_0.1 stresses of the В2-phase, is established. The maximum SE temperature range is 87 K, and the cyclic stability of superelastic behavior at a temperature of 323 K is sound in the [001]_В₂ orientation with a high σ_0.1 stress level of the В2-phase.

Keywords

single crystals of Ti50.2Ni49.8 alloy, superelasticity, cyclic stability, compression

References

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