Effects of Surface Pinning, Locking and Adaption of Twins on the Performance of Magnetic Shape-Memory Alloys

Chmielus, Markus; Müllner, Peter

doi:10.4028/www.scientific.net/msf.684.177

Cited by 11 publications

(6 citation statements)

References 75 publications

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“…The superelastic stress-strain curves in Fig.3a, 3b and 3c show serrated response, which is more pronounced during the forward transformation. Similar serrated stress strain behaviors were observed previously in other FeMnAlNi alloys as well as in magnetic SMAs such as NiMnGa [24,25]. Omori et al reported serrated stress-strain behavior in FeMnAlNi polycrystalline wires with a d/D ratio greater than one [19].…”

supporting

confidence: 79%

“…Serrated deformation behavior has also been observed in NiMnGa [24,25], however the serrations were linked to the surface roughness of the samples. The damaged surface layer resulting from spark plasma cutting or introduced via surface preparation can become stress concentrators, act as finely dispersed pinning sites for twin boundaries, and limits the ability of the martensite to coarsen.…”

mentioning

confidence: 88%

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Effects of cyclic heat treatment and aging on superelasticity in oligocrystalline Fe-Mn-Al-Ni shape memory alloy wires

Ozcan

Wang

et al. 2017

Scripta Materialia

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The effects of nano-precipitation on stress-induced martensitic transformation (SIM) in Fe 43.5 Mn 34 Al 15 Ni 7.5 shape memory alloy wires were investigated. It was shown that a large grain size to wire diameter ratio, i.e. an oligocrystalline structure, is necessary to obtain superelasticity. The critical stress for SIM and tensile strength at room temperature increase with aging time at 200°C without loss of superelasticity. A superelastic strain of 6.7%, with tunable transformation stress level as high as 600 MPa, and a low stress hysteresis, was obtained in the aged wires.

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supporting

confidence: 79%

mentioning

confidence: 88%

Effects of cyclic heat treatment and aging on superelasticity in oligocrystalline Fe-Mn-Al-Ni shape memory alloy wires

Ozcan

Wang

et al. 2017

Scripta Materialia

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“…When defects such as scratches are below 10 nm, the average switching field (and hence twinning stress) is lowered and twin nucleation occurs more easily [27]. When surface defects are much larger there is a tendency for dislocations to become pinned and interact with other passing dislocations [18,26]. Polishing with coarse slurry leads to a rougher surface and a stressed surface layer which allows for increased number of crack initiation points where dislocations will pile up and induce high stress concentration points.…”

Section: Single Crystalmentioning

confidence: 97%

“…Constraining the FSMA element inhibits twin reorientation locally within the constrained volume. Surface defects and residual stresses limit twin boundary motion and increases twinning stress [18]. Constrained samples exhibit reduced strain and prolonged fatigue life [19].…”

Section: Introductionmentioning

confidence: 99%

Fatigue life and fracture mechanics of unconstrained Ni–Mn–Ga single crystals in a rotating magnetic field

Lawrence

Lindquist

Ullakko

et al. 2016

Materials Science and Engineering: A

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a b s t r a c tFracture resistance and long fatigue life are required to commercialize Ni-Mn-Ga ferromagnetic shape memory alloys. While Ni-Mn-Ga achieves high fatigue life at low strains, there is little data on the fatigue life of samples that are actuated near the theoretical strain limit. Furthermore, constraints imposed by clamping samples impact their magneto-mechanical and fatigue properties. Here, 10 M Ni-MnGa single crystals were exposed to a rotating magnetic field while holding them with rubber O-rings so they were minimally constrained. Prior to testing, sample surfaces were prepared to various levels of finish. Fatigue life varied with some samples reaching more than 800,000 cyclic loads before fracturing and some samples failing after only 4000 cyclic loads. Long fatigue life and fracture resistance are achieved when avoiding crystal defects and surface imperfections. Short fatigue life was caused by high surface roughness and stress concentration at defects and notches.

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“…Surface damage stabilizes a fine twin structure, as shown by Chmielus et al [79] and Ezer et al [80]. 10M samples with fine twin structure, whether oriented or lamellar, exhibits good fatigue life [71,83]. In [76], Straka et al propose a phenomenological model, which describes the mechanism of reducing fatigue.…”

Section: Effect Of Surface Properties and Constraintsmentioning

confidence: 99%

Material Design, Processing, and Engineering Requirements for Magnetic Shape Memory Devices

Armstrong¹

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For magnetic shape memory (MSM) alloys, a magnetic field stimulates a shape change. We use the shape change to build devices such as micro-actuators, sensors, and microfluidic pumps. Currently, (as a novel technology,) devices suffer from some material and magnetic driver shortcomings. Here we address the issues related to operating temperature, repeatability, failure, and magnetic driver development. To increase the operating temperature of the MSM material, we alloyed Fe and Cu to Ni-Mn-Ga. We showed that the element-specific contribution to the valence electron density as parameter systematically determines the effect of each element on the variation of the martensite transformation temperature of the 10M phase. To stabilize the material, we developed a micro-shotpeening process that adds stresses to the material surface, thereby inducing a fine twin microstructure. The treatment allowed nearly full magnetic-field-induced strain, and extended fatigue life of the material from only one thousand cycles in the electropolished state to more than one million cycles in the peened state. We measured the effect of the peening process on material actuation when in MSM pump configuration. In the polished state, the deformation was stochastic, with a sharp-featured, faceted shrinkage. In the treated state, the deformation was smooth and repeatably swept along the surface akin to a wave. To actuate the MSM micropump without electromotor, we developed a linear electromagnetic actuation device and evaluated its effectiveness in the switching mechanism of the material. By compressing the magnetic field between opposing coils, we generated a strong magnetic field, which caused a localized region to switch at selected poles. In the next iteration of the drive, we inserted the MSM sample between two linear pole arrangements of high pitch density to approximate a moving vertical field. The incremental stepping of the vertical field between poles caused translation of the switched region. The results of this dissertation demonstrate the suitability of MSM alloys for high-precision, persistent, and reliable actuators such as micropumps.

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Effects of Surface Pinning, Locking and Adaption of Twins on the Performance of Magnetic Shape-Memory Alloys

Cited by 11 publications

References 75 publications

Effects of cyclic heat treatment and aging on superelasticity in oligocrystalline Fe-Mn-Al-Ni shape memory alloy wires

Effects of cyclic heat treatment and aging on superelasticity in oligocrystalline Fe-Mn-Al-Ni shape memory alloy wires

Fatigue life and fracture mechanics of unconstrained Ni–Mn–Ga single crystals in a rotating magnetic field

Material Design, Processing, and Engineering Requirements for Magnetic Shape Memory Devices

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