Effect of Ni Additions on the Microstructure, Mechanical Properties, and Electrical Conductivity of Al Alloy

Hyo-Sang Yoo; Yong-Ho Kim; Cheol-Woo Kim; Se-Weon Choi; Hyeon-Taek Son

Korean Journal of Materials Research, Vol.31, No.12, 672-676, December, 2021

DOI10.3740/MRSK.2021.31.12.672 Export Citation

Effect of Ni Additions on the Microstructure, Mechanical Properties, and Electrical Conductivity of Al Alloy

Hyo-Sang Yoo, Yong-Ho Kim, Cheol-Woo Kim, Se-Weon Choi, and Hyeon-Taek Son^†

Korea Institute of Industrial Technolog, Republic of Korea

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In this paper, the effect of Ni (0, 0.5 and 1.0 wt%) additions on the microstructure, mechanical properties and electrical conductivity of cast and extruded Al-MM-Sb alloy is studied using field emission scanning electron microscopy, and a universal tensile testing machine. Molten aluminum alloy is maintained at 750 °C and then poured into a mold at 200 °C. Aluminum alloys are hot-extruded into a rod that is 12 mm in diameter with a reduction ratio of 39:1 at 550 °C. The addition of Ni results in the formation of Al11RE3, AlSb and Al3Ni intermetallic compounds; the area fraction of these intermetallic compounds increases with increasing Ni contents. As the amount of Ni increases, the average grain sizes of the extruded Al alloy decrease to 1359, 536, and 153 μm, and the high-angle grain boundary fractions increase to 8, 20, and 34 %. As the Ni content increases from 0 to 1.0 wt%, the electrical conductivity is not significantly different, with values from 57.4 to 57.1 % IACS.

Keywords:aluminum;nickel;extrusion;mechanical property;electrical conductivity

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[2] Na SS, Kim YH, Son HT, Lee SH, Korean J. Mater. Res., 30(10), 542 (2020)

[3] Li D, Cui C, Wang X, Wang Q, Chen C, Liu S, Mater. Des., 90, 820 (2016)

[4] Medvedev AE, Murashkin MY, Enikeev NA, Valiev RZ, Hodgson PD, Lapovok R, J. Alloy. Compd., 745, 696 (2018)

[5] Jung CG, Hiroshi U, Son HT, Lee SH, Korean J. Mater. Res., 27(11), 597 (2017)

[6] Murashkin MY, Sabirov I, Medvedev AE, et al., Mater. Des., 90, 433 (2016)

[7] Zheng Q, Zhang L, Jiang H, Zhao J, He J, J. Mater. Sci. Tech., 47, 142 (2020)

[8] Mogucheva AA, Zyabkin DV, Kaibyshev RO, Met. Sci. Heat Treat., 53, 450 (2012)

[9] Nayak SS, Wollgarten M, Banhart J, Pabi SK, Murty BS, Mater. Sci. Eng. A-Struct. Mater. Prop. Microstruct. Process., 527, 2370 (2010)

[10] Ding W, Zhao X, Chen T, Zhang H, Liu X, Cheng Y, Lei D, J. Alloy. Compd., 830, 154685 (2020)

[11] Mao Z, Seidman DN, Wolverton C, Acta Mater., 59, 3659 (2011)

[12] Li C, Wang C, Yang ZZ, Ma PK, Ren MW, Wang HY, J. Alloy. Compd., 869, 159304 (2021)

[13] Akhil R, Nath OP, Arul S, Mater. Today: Proc., 24, 1042 (2020)

[14] Pan L, Zhang S, Yang Y, Gupta N, Yang C, Zhao Y, Hu Z, Metall. Mater. Trans. A, 51, 214 (2020)

[15] Jiang B, Wang H, Yi D, Tian Y, Shen F, Wang B, Liu H, Hu Z, Mater. Charact., 162, 110184 (2020)

[16] Cao Z, Kong G, Che C, Wang Y, Peng H, J. Rare Earths, 35, 1022 (2017)

[17] Robson JD, Henry DT, Davis B, Acta Mater., 57, 2739 (2009)

[18] Balakrishnan M, Dinaharan I, Kalaiselvan K, Palanivel R, J. Mater. Res. Technol., 9, 4356 (2020)