A novel high-strength Al-La-Mg-Mn alloy for selective laser melting

doi:10.1016/j.jmst.2022.07.046

Abstract

Abstract: Developing high-strength Al-(La, Ce) alloys for additive manufacturing (AM) would entail considerable economic benefits. In this work, a novel near-eutectic Al-La alloy containing 5.50 wt.% Mg and 0.60 wt.% Mn was designed and fabricated via selective laser melting (SLM). Submicron Al₁₁La₃ intermetallics with 3D continuous cellular-dendritic and granular morphologies were observed at the interior and boundary of the melt pool, respectively. Interestingly, these intermetallics are hierarchical and contained numerous Al₆Mn and Mg₂Si secondary nanoprecipitates. The as-fabricated alloy exhibited a tensile yield strength (YS) of 334 MPa and ultimate tensile strength (UTS) of 588 MPa at room temperature, which is the highest UTS reported for Al-(La, Ce) alloys with an appreciable failure strain of ∼6.4%. The 3D continuous cellular dendritic intermetallic and high Mg content afford significant strengthening and work hardening ability. In addition, the hierarchical feature of the intermetallics generated additional microcracks to coordinate the deformation.

Key words: Selective laser melting, Al-La alloys, 3D continuous structure, Hierarchical precipitate, High strength

Xinkui Zhang, Liejun Li, Zhi Wang, Hanlin Peng, Jixiang Gao, Zhengwu Peng. A novel high-strength Al-La-Mg-Mn alloy for selective laser melting[J]. J. Mater. Sci. Technol., 2023, 137: 205-214.

References

[1] T. DebRoy, H.L. Wei, J.S. Zuback, T. Mukherjee, J.W. Elmer, J.O. Milewski, A.M. Beese, A. Wilson-Heid, A. De, W. Zhang, Prog. Mater. Sci. 92 (2018) 112-224.
[2] N.T. Aboulkhair, M. Simonelli, L. Parry, I. Ashcroft, C. Tuck, R. Hague, Prog. Mater. Sci. 106 (2019) 100578.
[3] D. Herzog, V. Seyda, E. Wycisk, C. Emmelmann, Acta Mater. 117 (2016) 371-392.
[4] J.G. Kaufman, E.L. Rooy, Geauga, 2004.
[5] J.L. Zhang, B. Song, Q.S. Wei, D. Bourell, Y.S. Shi, J. Mater. Sci.Technol. 35 (2019) 270-284.
[6] J.R. Croteau, S. Griffiths, M.D. Rossell, C. Leinenbach, C. Kenel, V. Jansen, D.N. Seidman, D.C. Dunand, N.Q. Vo, Acta Mater. 153 (2018) 35-44.
[7] R.A. Michi, A. Plotkowski, A. Shyam, R.R. Dehoff, S.S. Babu, Int. Mater. Rev. 67 (2022) 298-345.
[8] S.K. Shaha, F. Czerwinski, W. Kasprzak, J. Friedman, D.L. Chen, Mater. Sci. Eng. A 652 (2016) 353-364.
[9] C.X. Zhao, Y. Li, J. Xu, Q. Luo, Y. Jiang, Q.L. Xiao, Q. Li, J. Mater. Sci.Technol. 94 (2021) 104-112.
[10] J. Xu, Y. Li, K. Ma, Y.N. Fu, E.Y. Guo, Z.N. Chen, Q.F. Gu, Y.X. Han, T.M. Wang, Q. Li, Scr. Mater. 187 (2020) 142-147.
[11] X.P. Li, X.J. Wang, M. Saunders, A. Suvorova, L.C. Zhang, Y.J. Liu, M.H. Fang, Z.H. Huang, T.B. Sercombe, Acta Mater. 95 (2015) 74-82.
[12] L. Thijs, K. Kempen, J.P. Kruth, J. Van Humbeeck, Acta Mater. 61 (2013) 1809-1819.
[13] K.G. Prashanth, S. Scudino, J. Eckert, Acta Mater. 126 (2017) 25-35.
[14] N.E. Uzan, R. Shneck, O. Yeheskel, N. Frage, Addit. Manuf. 24 (2018) 257-263.
[15] K. Knipling, D. Dunand, Scr. Mater. 59 (2008) 387-390.
[16] K.E. Knipling, D.N. Seidman, D.C. Dunand, Acta Mater. 59 (2011) 943-954.
[17] Z.G. Zhu, F.L. Ng, H.L. Seet, W.J. Lu, C.H. Liebscher, Z.Y. Rao, D. Raabe, S.M.L. Nai, Mater. Today 52 (2022) 90-101.
[18] Q.B. Jia, P. Rometsch, P. Kürnsteiner, Q. Chao, A.J. Huang, M. Weyland, L. Bour-geois, X.H. Wu, Acta Mater. 171 (2019) 108-118.
[19] S. Griffiths, J.R. Croteau, M.D. Rossell, R. Erni, A. De Luca, N.Q. Vo, D.C. Dunand, C. Leinenbach, Acta Mater. 188 (2020) 192-202.
[20] Z.C. Sims, O.R. Rios, D. Weiss, P.E.A.Turchi, A. Perron, J.R.I. Lee, T.T. Li, J.A. Ham-mons, M. Bagge-Hansen, T.M. Willey, K. An, Y. Chen, A.H. King, S.K. McCall, Mater. Horiz. 4 (2017) 1070-1078.
[21] R.T. Nguyen, D.D. Imholte, O.R. Rios, D. Weiss, Z. Sims, E. Stromme, S.K.McCall, Resour.Conserv. Recycl. 144 (2019) 340-349.
[22] L.Y. Wang, R.J. Qi, B. Ye, Y. Bai, R. Huang, H.Y. Jiang, W.J. Ding, Metall. Mater. Trans. A 51 (2020) 1972-1977.
[23] Y.T. Liu, Z.Y. Bian, Z. Chen, M.L. Wang, D. Chen, H.W. Wang, Mater. Charact. 155 (2019) 109821.
[24] D. Weiss, J. Mater. Eng.Perform. 28 (2019) 1903-1908.
[25] S. Bahl, K. Sisco, Y. Yang, F. Theska, S. Primig, L.F. Allard, R.A. Michi, C. Fancher, B. Stump, R. Dehoff, A. Shyam, A. Plotkowski, Addit. Manuf. 48 (2021) 102404.
[26] A. Plotkowski, K. Sisco, S. Bahl, A. Shyam, Y. Yang, L. Allard, P. Nandwana, A.M. Rossy, R.R. Dehoff, Acta Mater. 196 (2020) 595-608.
[27] L. Zhou, T. Huynh, S. Park, H. Hyer, A. Mehta, S.T. Song, Y.L. Bai, B. McWilliams, K. Cho, Y. Sohn, J. Mater. Sci. 55 (2020) 14611-14625.
[28] H.B. Henderson, J.A. Hammons, A.A. Baker, S.K.McCall, T.T. Li, A. Perron, Z.C. Sims, R.T. Ott, F. Meng, M.J. Thompson, D. Weiss, O. Rios, Mater. Des. 209 (2021) 109988.
[29] D.R. Manca, A.Y. Churyumov, A.V. Pozdniakov, A.S. Prosviryakov, D.K. Ryabov, A.Y. Krokhin, V.A. Korolev, D.K. Daubarayte, Met. Mater. Int. 25 (2018) 633-640.
[30] M. Zha, X.T. Meng, Z.Y. Yu, H.M. Zhang, H.L. Yin, Q.Q. Zhang, C. Wang, H.Y. Wang, Q.C. Jiang, Metall. Mater. Trans. A 50 (2019) 5264-5270.
[31] K. Sisco, A. Plotkowski, Y. Yang, D. Leonard, B. Stump, P. Nandwana, R.R. Dehoff, S.S. Babu, Sci. Rep. 11 (2021) 6953.
[32] Z.B. Liu, J.N. Sun, Z.G. Yan, Y.J. Lin, M.P. Liu, H.J. Roven, A.K. Dahle, Mater. Sci. Eng. A 806 (2021) 140806.
[33] Z. Wang, M.S. Xie, Y.Y. Li, W.W. Zhang, C. Yang, L. Kollo, J. Eckert, K.G. Prashanth, NPG Asia Mater. 12 (2020) 30.
[34] S. Bahl, A. Plotkowski, K. Sisco, D.N. Leonard, L.F. Allard, R.A. Michi, J.D. Poplawsky, R. Dehoff, A. Shyam, Acta Mater. 220 (2021) 117285.
[35] C. Zhang, Y.F. Wang, H.Y. Lv, H.Y. Gao, J. Wang, B.D. Sun, Mater. Sci. Eng. A 821 (2021) 141591.
[36] Z.C. Sims, D. Weiss, S.K. McCall, M.A. McGuire, R.T. Ott, T. Geer, O. Rios, P.A.E. Turchi, JOM 68 (2016) 1940-1947.
[37] R.A. Michi, K. Sisco, S. Bahl, Y. Yang, J.D. Poplawsky, L.F. Allard, R.R. Dehoff, A. Plotkowski, A. Shyam, Acta Mater. 227 (2022) 117699.
[38] D. Turnbull, B. Vonnegut, Ind. Eng. Chem. 44 (1952) 1292-1298.
[39] O. Ryen, B. Holmedal, E. Nes, E. Sjölander, H.E. Ekström, Metall. Mater. Trans. A 37 (2006) 1999-2006.
[40] N. Hansen, Scr. Mater. 51 (2004) 801-806.
[41] M. Zha, Y.J. Li, R.H. Mathiesen, R. Bjørge, H.J. Roven, Acta Mater. 84 (2015) 42-54.
[42] M. Zha, X.T. Meng, H.M. Zhang, X.H. Zhang, H.L. Jia, Y.J. Li, J.Y. Zhang, H.Y. Wang, Q.C. Jiang, J. Alloy. Compd. 728 (2017) 872-877.
[43] R. Kapoor, N. Kumar, R.S. Mishra, C.S. Huskamp, K.K. Sankaran, Mater. Sci. Eng. A 527 (2010) 5246-5254.
[44] J.F. Nie, B.C. Muddle, Acta Mater. 56 (2008) 3490-3501.
[45] N. Kamikawa, K. Sato, G. Miyamoto, M. Murayama, N. Sekido, K. Tsuzaki, T. Fu-ruhara, Acta Mater. 83 (2015) 383-396.
[46] C. Zhao, Z. Wang, D.X. Li, L. Kollo, Z.Q. Luo, W.W. Zhang, K.G. Prashanth, Int. J. Plast. 138 (2021) 102926.
[47] J.E. Campbell, R.P. Thompson, J. Dean, T.W. Clyne, Acta Mater. 168 (2019) 87-99.
[48] B.H. Lee, S.H. Kim, J.H. Park, H.W. Kim, J.C. Lee, Mater. Sci. Eng. A 657 (2016) 115-122.
[49] T. Morishige, T. Hirata, T. Uesugi, Y. Takigawa, M. Tsujikawa, K. Higashi, Scr. Mater. 64 (2011) 355-358.
[50] K.G. Prashanth, S. Scudino, H.J. Klauss, K.B. Surreddi, L. Löber, Z. Wang, A.K. Chaubey, U. Kühn, J. Eckert, Mater. Sci. Eng. A 590