Quantitative analysis of the microstructure in NiTi wires by Synchrotron X-ray diffraction: An approach to the cause of the Two Way Shape Memory Effect

To understand the complex behaviour of the NiTi shape memory alloys, the use of advanced characterization techniques as Synchrotron X-ray diffraction, becomes more and more necessary. In this paper, this technique was performed in heat-treated, thermally cycled at zero stress and two-way memory trai...

Full description

Saved in:
Bibliographic Details
Published inJournal of alloys and compounds Vol. 712; pp. 833 - 847
Main Authors Urbina, C., Gispert-Guirado, F., Ferrando, F., De la Flor, S.
Format Journal Article
LanguageEnglish
Published Lausanne Elsevier B.V 25.07.2017
Elsevier BV
Subjects
Alloys
Austenite
Chemical compounds
Diffraction
Dislocation density
Heat treatment
Intermetallic compounds
Martensite
Martensitic transformations
Mathematical analysis
Metals and alloys
Microstrain
Microstructure
Nickel base alloys
Nickel compounds
Nickel titanides
Quantitative analysis
Rietveld method
Shape memory
Shape memory alloys
Synchrotron radiation
Titanium compounds
Training
X-ray diffraction
Metals and alloys
Shape memory
Synchrotron radiation
Online AccessGet full text

Cover

More Information
Summary:To understand the complex behaviour of the NiTi shape memory alloys, the use of advanced characterization techniques as Synchrotron X-ray diffraction, becomes more and more necessary. In this paper, this technique was performed in heat-treated, thermally cycled at zero stress and two-way memory trained NiTi wires to evaluate through microstrain and retained martensite which is the predominant micro-mechanism that cause the Two Way Shape Memory Effect. The microstructural effects in the structure of the Austenite by thermal and training methods were quantified separately for each NiTi sample, allowing us to calculate how much of the accumulated microstrain in the Austenite phase is due to the increment in density of dislocations and how much is consequence of the decrease in crystallite size. To achieve this, two different methodologies were used. The mean microstrain and shift index were calculated by analysing the whole diffractogram with the Rietveld method and the Double-Voigt Approach. The individual peak shift and the peak broadening of the Austenite phase were evaluated by the modified Williamson-Hall plot. The results show that as higher is the increase in microstrain by thermal and training procedures, higher is the two-way memory strain of the NiTi sample. The micromechanical results pointed out that there is a certain formation of retained martensite during two-way memory training, but is not the main cause of the two-way shape memory effect. What is more, it seems that an early formation of retained martensite during training may decrease the generation of two-way shape memory effect. Pre-training thermal procedures that minimize the formation of retained martensite and maximize the increase in microstrain are fundamental to improve the generation of the NiTi two-way memory strain by subsequent training. •First time that SXRD experiments were performed in two-way memory NiTi wires.•We calculate separately the dislocation density and the crystallite size.•The increase in microstrain is the main cause of the TWSME in NiTi SMA.•The formation of retained martensite may stop the growth of the TWSME.•Pre-training thermal cycling increases microstrain and reduces the retained martensite.
ISSN:0925-8388
1873-4669
DOI:10.1016/j.jallcom.2017.04.071