Effect of hydrogen on the elastic and anelastic properties of the R phase in Ti50Ni46.1Fe3.9 alloy

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Abstract

The linear and non-linear internal friction, effective Young’s modulus, and amplitude-dependent modulus defect of a Ti50Ni46.1Fe3.9 alloy have been studied after different heat treatments, affecting hydrogen content, at temperatures of 13–300 K, and frequencies near 90 kHz. It has been shown that the contamination of the alloy by hydrogen gives rise to an internal friction maximum in the R martensitic phase and a complicated pinning stage in the temperature dependence of the effective Young’s modulus at temperatures corresponding to the high-temperature side of the maximum. Dehydrogenation of the H-contaminated alloy transforms the internal friction maximum into a plateau and minimizes the pinning stage. The internal friction maximum is associated with a competition of two different temperature-dependent processes affecting the hydrogen concentration in the core regions of twin boundaries. The amplitude-dependent anelasticity of the R phase is also very sensitive to hydrogen content, its temperature dependence reflects the evolution of extended hydrogen atmospheres near twin boundaries.

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Sapozhnikov, K., Torrens-Serra, J., Cesari, E., van Humbeeck, J., & Kustov, S. (2017). Effect of hydrogen on the elastic and anelastic properties of the R phase in Ti50Ni46.1Fe3.9 alloy. Metals, 7(11). https://doi.org/10.3390/met7110493

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