Tensile properties and microstructure of 2024 aluminum alloy subjected to the high magnetic field and external stressProject supported by the National Natural Science Foundation of China (Grant Nos. 51371091, 51174099, and 51001054) and the Industrial Center of Jiangsu University, China (Grant No. ZXJG201586)

In order to explore the dependence of plasticity of metallic material on a high magnetic field, the effects of the different magnetic induction intensities (H = 0 T, 0.5 T, 1 T, 3 T, and 5 T) and pulses number (N = 0, 10, 20, 30, 40, and 50) on tensile strength (σb) and elongation (δ) of 2024 alumin...

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Bibliographic Details
Published in:Chinese physics B 2016-10, Vol.25 (10)
Main Authors: Li, Gui-Rong, Xue, Fei, Wang, Hong-Ming, Zheng, Rui, Zhu, Yi, Chu, Qiang-Ze, Cheng, Jiang-Feng
Format: Article
Language:English
Subjects:
2024 aluminum alloy
elongation
magneto plasticity effect
tensile strength
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Summary:In order to explore the dependence of plasticity of metallic material on a high magnetic field, the effects of the different magnetic induction intensities (H = 0 T, 0.5 T, 1 T, 3 T, and 5 T) and pulses number (N = 0, 10, 20, 30, 40, and 50) on tensile strength (σb) and elongation (δ) of 2024 aluminum alloy are investigated in the synchronous presences of a high magnetic field and external stress. The results show that the magnetic field exerts apparent and positive effects on the tensile properties of the alloy. Especially under the optimized condition of H* = 1 T and N* = 30, the σb and δ are 410 MPa and 17% that are enhanced by 9.3% and 30.8% respectively in comparison to those of the untreated sample. The synchronous increases of tensile properties are attributed to the magneto-plasticity effect on a quantum scale. That is, the magnetic field will accelerate the state conversion of radical pair generated between the dislocation and obstacles from singlet to the triplet state. The bonding energy between them is meanwhile lowered and the moving flexibility of dislocations will be enhanced. At H* = 1 T and N* = 30, the dislocation density is enhanced by 1.28 times. The relevant minimum grain size is 266.1 nm, which is reduced by 35.2%. The grain refining is attributed to the dislocation accumulation and subsequent dynamic recrystallization. The (211) and (220) peak intensities are weakened. It is deduced that together with the recrystallization, the fine grains will transfer towards the slip plane and contribute to the slipping deformation.
ISSN:1674-1056
DOI:10.1088/1674-1056/25/10/106201