A unified model for ductile-to-brittle transition in body-centered cubic metals

doi:10.1016/j.jmst.2022.08.038

Abstract

Abstract: Ductile-to-brittle transition (DBT) is a well-known phenomenon in body-centered-cubic (BCC) metals, intermetallics and semiconductor materials. A quantitative prediction of the DBT temperature, however, has so far remained intractable. Here, we propose a unified model based on the efficacy of dislocation multiplication as the controlling factor for DBT, with the dislocation source efficiency governed by the relative mobility of screw versus edge dislocations. The model successfully predicts the DBT temperature of iron, molybdenum and tungsten, and also covers the influence of grain size, initial dislocation density, and the multiplicity of dislocation sources. A comparison with experiments indicates that the model captures the key DBT features, providing new insight into the toughness of BCC metals.

Key words: Metals, DuctileBrittle, Dislocation, Mobility

Yu-Heng Zhang, En Ma, Jun Sun, Wei-Zhong Han. A unified model for ductile-to-brittle transition in body-centered cubic metals[J]. J. Mater. Sci. Technol., 2023, 141: 193-198.

References

[1] J.W. Christian, Metall. Trans. A 14 (1983) 1237-1256.
[2] S.G. Roberts, A.S. Booth, P.B. Hirsch, Mater. Sci. Eng. A 176 (1994) 91-98.
[3] C. St. John, Philos. Mag. 32 (1975) 1193-1212.
[4] E. Tarleton, S.G. Roberts, Philos. Mag. 89 (2009) 2759-2769.
[5] J.R. Rice, R. Thomson, Philos. Mag. 29 (1974) 73-97.
[6] P. Gumbsch, J. Riedle, A. Hartmaier, H.F. Fischmeister, Science 282 (1998) 1293-1295.
[7] V. Vitek, Philos. Mag. 84 (2004) 415-428.
[8] A. Seeger, Int. J. Mater. Res. 93 (2002) 760-777.
[9] D. Rodney, L. Ventelon, E. Clouet, L. Pizzagalli, F. Willaime, Acta Mater. 124 (2017) 633-659.
[10] Y. Lu, Y.H. Zhang, E. Ma, W.Z. Han, Proc. Natl. Acad. Sci. U. S. A. 118 (2021) e2110596118.
[11] Y.H. Zhang, W.Z. Han, Acta Mater. 220 (2021) 117332.
[12] C. Bonnekoh, J. Reiser, A. Hartmaier, S. Bonk, A. Hoffmann, M. Rieth, J. Mater. Sci. 55 (2020) 12314-12337.
[13] C. Bonnekoha, U. Jäntscha, J. Hoffmanna, H. Leistea, A. Hartmaierb, D. Weygandc, A. Hoffmannd, J. Reiser, Int. J. Refract. Met. Hard Mater. 78 (2019) 146-163.
[14] A .A .N. Németh, J.Reiser, D.E.J. Armstrong, M. Rieth, Int. J. Refract. Met. Hard Mater. 50 (2015) 9-15.
[15] X.F. Xie, Z.M. Xie, R. Liu, Q.F. Fang, C.S. Liu, W.Z. Han, X. Wu, Acta Mater. 228 (2022) 117765.
[16] Z.M. Xie, R. Liu, S. Miao, X.D. Yang, T. Zhang, X.P. Wang, Q.F. Fang, C.S. Liu, G.N. Luo, Y.Y. Lian, X. Liu, Sci. Rep. 5 (2015) 16014.
[17] P.B. Hirsch, S.G. Roberts, Philos. Mag. A 64 (1991) 55-80.
[18] M. Khantha, D.P. Pope, V. Vitek, Phys. Rev. Lett. 73 (1994) 6 84-6 87.
[19] D. Hull, D.J. Bacon, Oxford, 2011.
[20] D. Cereceda, M. Diehl, F. Roters, P. Shanthraj, D. Raabe, J.M. Perlado, J. Marian, GAMM-Mitt. 38 (2015) 213-227.
[21] G. Po, Y. Cui, D. Rivera, D. Cereceda, T.D. Swinburne, J. Marian, N. Ghoniem, Acta Mater. 119 (2016) 123-135.
[22] B. Chen, S. Li, H. Zong, X. Ding, J. Sun, E. Ma, Proc. Natl. Acad. Sci. U. S. A. 117 (2020) 16199.
[23] Y. Cui, G. Po, N. Ghoniem, Acta Mater. 108 (2016) 128-137.
[24] E. Kuramoto, Y. Aono, K. Kitajima, Scr. Metall. 13 (1979) 1039-1042.
[25] R. Gröger, V. Vitek, Acta Mater. 56 (2008) 5426-5439.
[26] D. Brunner, Mater. Trans. JIM 41 (20 0 0) 152-160.
[27] C.R. Weinberger, Acta Mater. 58 (2010) 6535-6541.
[28] F. Maresca, D. Dragoni, G. Csányi, N. Marzari, W.A.Curtin, npj Comput.Mater. 4 (2018) 69.
[29] J. Chang, W. Cai, V.V. Bulatov, S. Yip, Comput. Mater. Sci. 23 (2002) 111-115.
[30] C. Minnert, H. ur Rehman, K.Durst, J. Mater. Res. 36 (2021) 2397-2407.
[31] W.A. Spitzig, Metall. Trans. 3 (1972) 1183-1188.
[32] S. Queyreau, J. Marian, M.R. Gilbert, B.D. Wirth, Phys. Rev. B 84 (2011) 064106.
[33] S. Naamane, G. Monnet, B. Devincre, Int. J. Plast. 26 (2010) 84-92.
[34] B.B. He, B. Hu, H.W. Yen, G.J. Cheng, Z.K. Wang, H.W. Luo, M.X. Huang, Science 357 (2017) 1029-1032.
[35] T.B. Yu, N. Hansena, X.X. Huang, A. Godfrey, Mater. Res. Lett. 2 (2014) 160-165.
[36] Q. Wei, J. Mater. Sci. 42 (2007) 1709-1727.
[37] S. Cheng, A.D. Stoica, X.L. Wang, Y. Ren, J. Almer, J.A. Horton, C.T. Liu, B. Clausen, D.W. Brown, P.K. Liaw, L. Zuo, Phys. Rev. Lett. 103 (2009) 035502.
[38] Q. Wei, S. Cheng, K.T. Ramesh, E. Ma, Mater. Sci. Eng. A 381 (2004) 71-79.
[39] Lihua Wang, Yin Zhang, Zhi Zeng, Hao Zhou, Jian He, Pan Liu, Mingwei Chen, Jian Han, David J. Srolovitz, Jiao Teng, Yizhong Guo, Guo Yang, Deli Kong, En Ma, Yongli Hu, Baocai Yin, XiaoXu Huang, Ze Zhang, Ting Zhu, Xiaodong Han, Science 375 (2022) 1261-1265.
[40] R. Song, D. Ponge, D. Raabe, Acta Mater. 53 (2005) 4 881-4 892.
[41] S. Takaki, K. Kawasaki, Y. Kimura, J. Mater. Process.Technol. 117 (2001) 359-363.
[42] D. Farkas, B. Hyde, Nano Lett. 5 (2005) 2403-2407.
[43] K.J. Hemker, Science 304 (2004) 221-223.
[44] N. Tsuji, S. Okuno, Y. Koizumi, Y. Minamino, Mater. Trans. 7 (2004) 2272-2281.
[45] G. Liu, G.J. Zhang, F. Jiang, X.D. Ding, Y.J. Sun, J. Sun, E. Ma, Nat. Mater. 12 (2013) 344-350.
[46] M.S. Ding, J.P. Du, L. Wan, S. Ogata, L. Tian, E. Ma, W.Z. Han, J. Li, Z.W. Shan, Nano Lett. 16 (2016) 4118-4124.
[47] J.W. Zhang, I.J. Beyerlein, W.Z. Han, Phys. Rev. Lett. 122 (2019) 255501.
[48] L.L. Li, Y.Q. Su, I.J. Beyerlein, W.Z. Han, Sci. Adv. 6 (2020) eabb6658.
[49] R.Y. Zheng, W.R. Jian, I.J. Beyerlein, W.Z. Han, Nano Lett. 21 (2021) 5798-5804.
[50] J.T. Li, I.J. Beyerlein, W.Z. Han, Acta Mater. 226 (2022) 117656 .