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Shape Memory and Superelasticity

Erschienen in:

01.06.2015

Monitoring Tensile Fatigue of Superelastic NiTi Wire in Liquids by Electrochemical Potential

verfasst von: Jan Racek, Marc Stora, Petr Šittner, Luděk Heller, Jaromir Kopeček, Martin Petrenec

Erschienen in: Shape Memory and Superelasticity | Ausgabe 2/2015

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Abstract

Fatigue of superelastic NiTi wires was investigated by cyclic tension in simulated biofluid. The state of the surface of the fatigued NiTi wire was monitored by following the evolution of the electrochemical open circuit potential (OCP) together with macroscopic stresses and strains. The ceramic TiO₂ oxide layer on the NiTi wire surface cannot withstand the large transformation strain and fractures in the first cycle. Based on the analysis of the results of in situ OCP experiments and SEM observation of cracks, it is claimed that the cycled wire surface develops mechanochemical reactions at the NiTi/liquid interface leading to cumulative generation of hydrogen, uptake of the hydrogen by the NiTi matrix, local loss of the matrix strength, crack transfer into the NiTi matrix, accelerated crack growth, and ultimately to the brittle fracture of the wire. Fatigue degradation is thus claimed to originate from the mechanochemical processes occurring at the excessively deforming surface not from the accumulation of defects due to energy dissipative bulk deformation processes. Ironically, combination of the two exciting properties of NiTi—superelasticity due to martensitic transformation and biocompatibility due to the protective TiO₂ surface oxide layer—leads to excessive fatigue damage during cyclic mechanical loading in biofluids.

Vorheriger Artikel Nanostructured Ti–Ni Shape Memory Alloys Produced by Thermomechanical Processing

Nächster Artikel Fundamental Development on Utilizing the R-phase Transformation in NiTi Shape Memory Alloys

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Titel: Monitoring Tensile Fatigue of Superelastic NiTi Wire in Liquids by Electrochemical Potential
verfasst von: Jan Racek
Marc Stora
Petr Šittner
Luděk Heller
Jaromir Kopeček
Martin Petrenec
Publikationsdatum: 01.06.2015
Verlag: Springer International Publishing
Erschienen in: Shape Memory and Superelasticity / Ausgabe 2/2015
Print ISSN: 2199-384X
Elektronische ISSN: 2199-3858
DOI: https://doi.org/10.1007/s40830-015-0020-5

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