Phase volume fractions and strain measurements in an ultrafine-grained NiTi shape-memory alloy during tensile loading

Young, Marcus L.; Wagner, Martin F.‐X.; Frenzel, Jan; Schmahl, Wolfgang W.; Eggeler, Gunther

doi:10.1016/j.actamat.2009.12.021

Cited by 149 publications

(103 citation statements)

References 68 publications

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“…Using similar initial microstructures, we compare two different types of samples during tensile testing, and we discuss how different surface morphologies, clamping conditions, and strain measurement techniques affect the thermo-mechanical response. We also compare the material's tendency for localized deformation (i.e., formation and growth of fully transformed martensite in distinct bands) in small-scale samples to the well-known bulk behavior of NiTi [8,9].…”

Section: Introductionmentioning

confidence: 99%

Challenges During Microstructural Analysis and Mechanical Testing of Small-Scale Pseudoelastic NiTi Structures

Hahn

Wagner

2016

Shap. Mem. Superelasticity

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Most investigations on NiTi-based shape memory alloys involve large-scale bulk material; knowledge about the martensitic transformation in small-scale NiTi structures is still limited. In this paper, we study the microstructures of thin NiTi layers and their mechanical properties, and we discuss typical challenges that arise when experiments are performed on small samples. A physical vapor deposition (PVD) process was used to deposit thin NiTi wires with a cross section of 15 9 15 lm 2 and dogbone-shaped samples 5 9 500 lm 2 . Microstructural properties were characterized by X-ray diffraction, electron backscatter diffraction, and scanning electron microscopy. Moreover, tensile tests were performed using optical strain measurements in order to observe martensite band formation during cyclic loading. The surfaces of the crystalline wires reflect the columnar growth of NiTi during deposition. The wires exhibit pseudoelastic material behavior during tensile testing. Fracture typically occurs along the columns because the column growth direction is perpendicular to the straining direction. Electropolishing removes these local stress raisers and hence increases fracture strains. Our results demonstrate that the pseudoelastic properties of the PVDprocessed materials agree well with those of conventional NiTi, and that they provide new opportunities to study the fundamentals of martensitic transformation in small-scale model systems.

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Section: Introductionmentioning

confidence: 99%

Challenges During Microstructural Analysis and Mechanical Testing of Small-Scale Pseudoelastic NiTi Structures

Hahn

Wagner

2016

Shap. Mem. Superelasticity

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“…Within Stage I, samples deform linear-elastically as strain increases up~0.5 pct strain for both quasi-static and dynamic compression. While both samples exhibited an elastic modulus of about 32 GPa which is within the range of elastic moduli values reported in the literature, [15,52,55] there does appear to be some slight deviation from linearity in the dynamic compression curve in Stage I. After about 0.8 pct, the onset of the stress plateau was observed (Stage II), where the stress in the specimen increases less prominently with increasing strain.…”

Section: Resultsmentioning

confidence: 68%

“…[12][13][14][15][16][17][18] The characteristic transformation temperatures for the austenite-to-martensite phase transformation as well as the mechanical response can be modified to meet application requirements through (i) thermo-mechanical processing, [19][20][21] (ii) slight variation from the equi-atomic NiTi chemical composition, [22,23] or (iii) addition of alloying elements. [24][25][26][27][28] This phase transformation generally involves an austenitic cubic B2 structure transforming to and from either a martensitic monoclinic B19 or orthorhombic B19¢ structure.…”

Section: Introductionmentioning

confidence: 99%

Influence of Dynamic Compression on Phase Transformation of Martensitic NiTi Shape Memory Alloys

Qiu

Young

Nie

2015

Metall Mater Trans A

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Shape memory alloys (SMAs) exhibit high damping capacity in both austenitic and martensitic phases, due to either a stress-induced martensite phase transformation or a stress-induced martensite variant reorientation, making them ideal candidates for vibration suppression devices to protect structural components from damage due to external forces. In this study, both quasi-static and dynamic compression was conducted on a martensitic NiTi SMA using a mechanical loading frame and on a Kolsky compression bar, respectively, to examine the relationship between microstructure and phase transformation characteristics of martensitic NiTi SMAs. Both endothermic and exothermic peaks disappear completely after experiencing deformation at a strain rate of 10 3 s À1 and to a strain of about 10 pct. The phase transformation peaks reappear after the deformed specimens were annealed at 873 K (600°C) for 30 minutes. As compared to samples from quasi-static loading, where a large amount of twinning is observed with a small amount of grain distortion and fracture, samples from dynamic loading show much less twinning with a larger amount of grain distortion and fracture.

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“…Representative responses are shown in Figure 4. Traditionally, effective Poisson's ratios (ν * A , ν * M ) have been assumed [8,9], though recent measurements of Poisson's ratios have been reported for NiTi [6,10,11].…”

Section: Effective Thermo-elastic Propertiesmentioning

confidence: 99%

Shape Memory Alloy Actuator Design: CASMART Collaborative Best Practices

Benafan

Brown

Calkins

et al. 2011

ASME 2011 Conference on Smart Materials, Adaptive Structures and Intelligent Systems, Volume 1

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Upon examination of shape memory alloy (SMA) actuation designs, there are many considerations and methodologies that are common to them all. A goal of CASMART's design working group is to compile the collective experiences of CASMART's member organizations into a single medium that engineers can then use to make the best decisions regarding SMA system design. In this paper, a review of recent work toward this goal is presented, spanning a wide range of design aspects including evaluation, properties, testing, modeling, alloy selection, fabrication, actuator processing, design optimization, controls, and system integration. We have documented each aspect, based on our collective experiences, so that the design engineer may access the tools and information needed to successfully design and develop SMA systems. Through comparison of several case studies, it is shown that there is not an obvious single, linear route a designer can adopt to navigate the path of concept to product. SMA engineering aspects will have different priorities and emphasis for different applications. INTRODUCTIONShape memory alloys (SMAs) have been a topic of significant research interest for over forty years. Microstructural complexities and their resulting thermomechanical properties have presented challenges in understanding how to integrate these materials into structural applications.Consequently, design of structural and mechanical systems involving SMA materials has been sparse and ad hoc. However, upon examination of a variety of system designs, there are many considerations and parameters that are common to them all. The Consortium for the Advancement of Shape Memory Alloy Research and Technology (CASMART) was established to foster sharing of technical knowledge about SMAs, to achieve new understanding of the materials, and to facilitate progress in applying that knowledge. The Design Working Group of CASMART strives to serve as a single location to capture the collective best practices, critical information and perspective necessary for designing systems involving SMA materials and actuators.The objective of this paper is to compile the experiences of the authors into a resource that can aid other engineers in SMA

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Phase volume fractions and strain measurements in an ultrafine-grained NiTi shape-memory alloy during tensile loading

Cited by 149 publications

References 68 publications

Challenges During Microstructural Analysis and Mechanical Testing of Small-Scale Pseudoelastic NiTi Structures

Challenges During Microstructural Analysis and Mechanical Testing of Small-Scale Pseudoelastic NiTi Structures

Influence of Dynamic Compression on Phase Transformation of Martensitic NiTi Shape Memory Alloys

Shape Memory Alloy Actuator Design: CASMART Collaborative Best Practices

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