The Influence of Aging on Critical Transformation Stress Levels and Martensite Start Temperatures in NiTi: Part I—Aged Microstructure and Micro-Mechanical Modeling

Gall, Ken; Şehitoğlu, Hüseyin; Chumlyakov, Yuriy; Киреева, И. В.; Maier, Hans Jürgen

doi:10.1115/1.2815993

Cited by 92 publications

(39 citation statements)

References 27 publications

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“…Evaluation of Equation 2 yields decreases of 0.22 and 0.27 at.-% depending on the type of particles (TinNi|4 or Ti 3 Ni 4 ). A direct comparison of these results suggests that shifts in PTTs are associated with the precipitation of T^Ni^ Our results show that the method described in [13] can be experimentally validated. There is an interaction between martensitic phases and subgrain boundaries as has already been observed [9] and described [9,11] in the literature and which was again identified in the present study, Figure 4b.…”

Section: Precipitation Of Ti 3 Ni 4 Particles Was Documented Inmentioning

confidence: 62%

Influence of precipitation and dislocation substructure on phase transformation temperatures in a Ni-rich NiTi-shape memory alloy

et al. 2001

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Abstract. The present work studies the influence of different thermo mechanical treatments on phase transformation and creep of a Ti-50.7at%Ni shape memory alloy. Thermo-mechanically processed, solution annealed, tempered and pre-crept material states show different phase transformation behaviour. Precipitation of Ti 3 Ni 4 particles can rationalize a 20°C increase in phase transition temperatures. Changes of dislocation density and subgrain size also have a systematic but small effect on the martensitic transformation. There is a strong influence of small preloads on the shape of individual creep curves in the early stages of creep which is associated with the precipitation of Ti 3 Ni 4 .

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Section: Precipitation Of Ti 3 Ni 4 Particles Was Documented Inmentioning

confidence: 62%

Influence of precipitation and dislocation substructure on phase transformation temperatures in a Ni-rich NiTi-shape memory alloy

et al. 2001

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“…The introduction of Ti 3 Ni 4 precipitates in NiTi is known to favor the martensitic transformation and suppress dislocation motion. 47,48 Despite this knowledge, the effect of the precipitates on the overall stress-strain response of NiTi wire has not been systematically examined in prior work. In the present study, we show that precipitates have a marked influence on the overall shape of the stress-strain response in addition to causing material strengthening.…”

Section: Martensite Detwinning (Md) -Figure 12(c)mentioning

confidence: 98%

Tensile deformation of NiTi wires

Gall

Tyber

Brice

et al. 2005

J Biomedical Materials Res

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We examine the structure and properties of cold drawn Ti-50.1 at % Ni and Ti-50.9 at % Ni shape memory alloy wires. Wires with both compositions possess a strong <111> fiber texture in the wire drawing direction, a grain size on the order of micrometers, and a high dislocation density. The more Ni rich wires contain fine second phase precipitates, while the wires with lower Ni content are relatively free of precipitates. The wire stress-strain response depends strongly on composition through operant deformation mechanisms, and cannot be explained based solely on measured differences in the transformation temperatures. We provide fundamental connections between the material structure, deformation mechanisms, and resulting stress-strain responses. The results help clarify some inconsistencies and common misconceptions in the literature. Ramifications on materials selection and design for emerging biomedical applications of NiTi shape memory alloys are discussed.

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“…It has been reported by Gall et al [34,35] that the precipitation of coherent Ni4Ti3 particles after heat treatment can greatly influence the critical stress level required for martensitic transformation by the generation of strong local stress fields between the precipitates and the NiTi matrix. Such local stress fields as a consequence of the lattice parameter mismatch between the precipitates and the matrix create preferential nucleation sites for martensitic transformation, and hence lower the critical stress level to induce the transformation process [36].…”

Section: Discussionmentioning

confidence: 99%

“…However, it is worthwhile to note that size and coherency of the Ni4Ti3 precipitates are critical in affecting the mechanical and functional properties of the weldment [34][35][36].…”

Section: Discussionmentioning

confidence: 99%

Reduction of environmentally induced cracking of laser-welded shape memory NiTi wires via post-weld heat-treatment

Chan

Man

2013

Materials Science and Engineering: A

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In this study, the environmentally induced cracking behaviour of the NiTi weldment with and without post-weld heat-treatment (PWHT) in Hanks' solution at 37.5 °C at OCP were studied by tensile and cyclic slow-strain-rate tests (SSRT), and compared with those tested in oil (an inert environment). Our previous results in the tensile and cyclic SSRT showed that the weldment without PWHT showed high susceptibility to the hydrogen cracking, as evidenced by the degradation of tensile and super-elastic properties when testing in Hanks' solution. The weldment after PWHT was much less susceptible to hydrogen attack in Hanks' solution as no obvious degradation in the tensile and super-elastic properties was observed, and only a very small amount of micro-cracks were found in the fracture surface. The susceptibility to hydrogen cracking of the NiTi weldment could be alleviated by applying PWHT at the optimized temperature of 350 °C after laser welding.

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The Influence of Aging on Critical Transformation Stress Levels and Martensite Start Temperatures in NiTi: Part I—Aged Microstructure and Micro-Mechanical Modeling

Cited by 92 publications

References 27 publications

Influence of precipitation and dislocation substructure on phase transformation temperatures in a Ni-rich NiTi-shape memory alloy

Influence of precipitation and dislocation substructure on phase transformation temperatures in a Ni-rich NiTi-shape memory alloy

Tensile deformation of NiTi wires

Reduction of environmentally induced cracking of laser-welded shape memory NiTi wires via post-weld heat-treatment

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