Improved magnetostriction in Galfenol alloys by aligning crystal growth direction along easy magnetization axis

Zhou, Chao; Liu, Yapeng; Chen, Kaiyun; Dai, Zhiyong; Ma, Tianyu; Wang, Yu; Ren, Shuai; Deng, Jianqiang; Zhang, Rui; Tian, Fanghua; Zhang, Yin; Zeng, Hao; Yang, Shengchun

doi:10.1038/s41598-020-77058-2

Cited by 10 publications

(3 citation statements)

References 38 publications

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“…As is common with milling processes, there is also a consistent reduction in the unit cell parameter with milling time. The initial unmilled lattice parameter of 2.905 Å is in excellent agreement with the literature, , reducing to 2.904 after 27 milling cycles (3.4 h). A consistent reduction in the crystallite size with the milling time is also observed.…”

Section: Resultssupporting

confidence: 89%

Creating High Aspect Ratio Magnetostrictive Flakes to Enhance Magnetoelectric Polymer Composites

Charles,

Rider,

Brown

et al. 2024

ACS Appl. Electron. Mater.

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Section: Resultssupporting

confidence: 89%

Creating High Aspect Ratio Magnetostrictive Flakes to Enhance Magnetoelectric Polymer Composites

Charles,

Rider,

Brown

et al. 2024

ACS Appl. Electron. Mater.

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“…5(c) that in the phase transition from the L2 1 austenite cubic structure to the 4O martensite orthorhombic structure, the (220) crystal plane is the habitual plane of the parent phase, and a re-stack arrangement is produced on this crystal plane during the phase transformation process. 32,33 Through experiments and calculations, it is found that the alloy will preferentially form the (220) surface during the DS process, which to a certain extent can reduce the energy barrier that needs to be overcome for the martensitic phase transition so that the phase transition is faster and more complete. This, in turn, increases the magnetic entropy change produced by the transition along the (220) direction, effectively improving the magnetocaloric effect of the martensitic phase transition.…”

Section: Resultsmentioning

confidence: 99%

Large magnetic entropy change in Ni–Mn–In–Sb alloys via directional solidification and calculated by first-principles calculations

Tian,

Cao,

Chen

et al. 2024

Journal of Applied Physics

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In this work, the magnetocaloric effect in Ni50Mn36In5Sb9 alloy was increased by more than 50% through directional solidification, and the magnetic entropy change increased to 36.2 J kg−1 K−1 under the field of 5 T. The calculated results of differential scanning calorimetry curves confirmed the enhanced entropy change, which also increased from 29.7 to 40.7 J kg−1 K−1. Moreover, first-principles calculations show that the surface formation energy along the L21 (220) plane is the lowest at room temperature, and it is easy to form and undergo martensitic transformation from the (220) crystal plane. Directional solidification causes the alloy to grow basically toward the (220) crystal plane, improve atomic ordering, reduce grain boundaries, and increase grain size. Thereby, the magnetic entropy change is enhanced.

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“…These materials represent an example of field-controllable functional polymers in which micron-sized magnetizable particles are embedded into a compliant polymer network, see [ 22 , 23 , 24 ] for a detailed characterization of MAEs. Since the strong coupling of magnetic and mechanical fields allows us to induce mechanical deformations that are significantly larger than magneto-strictive effects observed for single-phase materials [ 25 , 26 , 27 ], MAEs have attracted considerable research interest in the fields of micro-robots [ 28 ] and -pumps [ 29 ], as well as coating materials with variable shapes [ 30 ]. The ability to control their mechanical modulus using an external magnetic field also allows for technical applications in the areas of actuators and sensors [ 31 , 32 , 33 ], vibration absorbers [ 34 ], as well as prosthetic devices with tunable stiffness [ 35 ].…”

Section: Introductionmentioning

confidence: 99%

Benchmark for the Coupled Magneto-Mechanical Boundary Value Problem in Magneto-Active Elastomers

et al. 2021

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Within this contribution, a novel benchmark problem for the coupled magneto-mechanical boundary value problem in magneto-active elastomers is presented. Being derived from an experimental analysis of magnetically induced interactions in these materials, the problem under investigation allows us to validate different modeling strategies by means of a simple setup with only a few influencing factors. Here, results of a sharp-interface Lagrangian finite element framework and a diffuse-interface Eulerian approach based on the application of a spectral solver on a fixed grid are compared for the simplified two-dimensional as well as the general three-dimensional case. After influences of different boundary conditions and the sample size are analyzed, the results of both strategies are examined: for the material models under consideration, a good agreement of them is found, while all discrepancies can be ascribed to well-known effects described in the literature. Thus, the benchmark problem can be seen as a basis for future comparisons with both other modeling strategies and more elaborate material models.

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Improved magnetostriction in Galfenol alloys by aligning crystal growth direction along easy magnetization axis

Cited by 10 publications

References 38 publications

Creating High Aspect Ratio Magnetostrictive Flakes to Enhance Magnetoelectric Polymer Composites

Creating High Aspect Ratio Magnetostrictive Flakes to Enhance Magnetoelectric Polymer Composites

Large magnetic entropy change in Ni–Mn–In–Sb alloys via directional solidification and calculated by first-principles calculations

Benchmark for the Coupled Magneto-Mechanical Boundary Value Problem in Magneto-Active Elastomers

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