CONDENSED MATTER: ELECTRONIC STRUCTURE, ELECTRICAL, MAGNETIC, AND OPTICAL PROPERTIES |
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Elastic Modulus of Fe72.5Ga27.5 Magnetostrictive Alloy |
ZHU Xiao-Xi, LIU Jing-Hua, JIANG Cheng-Bao |
School of Materials Science and Engineering, Beihang University, Beijing 100083 |
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Cite this article: |
ZHU Xiao-Xi, LIU Jing-Hua, JIANG Cheng-Bao 2010 Chin. Phys. Lett. 27 067504 |
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Abstract The elastic modulus of Fe72.5Ga27.5 magnetostrictive alloy is determined by testing ac impedance resonance frequency and first-principle calculations. The observed elastic modulus is 90.2 GPa for a directionally solidified sample and 103.4 GPa for a water-quenched sample tested in a dc magnetic field of 32.7 mT without compressive pre-stress. The bulk modulus by first-principles calculation is 179.3 GPa which is basically consistent with the experimental result. The elastic modulus first increases and then decreases with increasing dc magnetic field, attributed to magnetostriction occurrence in the Fe72.5Ga27.5 alloy. The elastic modulus increases with increasing compressive pre-stress, resulting from the initial magnetic states change under the applied compressive pre-stress. The elastic modulus increases match well with the improved magnetostriction after quenching.
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Keywords:
75.50.Bb
75.90.+w
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Received: 14 October 2009
Published: 25 May 2010
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PACS: |
75.50.Bb
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(Fe and its alloys)
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75.90.+w
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(Other topics in magnetic properties and materials)
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