High-Temperature Stability of Mg-1Al-12Y Alloy Containing LPSO Phase and Mechanism of Its Portevin-Le Chatelier (PLC) Effect

doi:10.1007/s40195-024-01663-7

Abstract

Abstract:

In this study, the high-temperature stability and the generation mechanism of the Portevin-Le Chatelier (PLC) effect in solid-solution Mg-1Al-12Y alloy with different heat treatment processes were investigated by adjusting the content of long-period stacking ordered (LPSO) phases. It was found that the content of LPSO phases in the alloys differed the most after heat treatment at 530 °C for 16 h and 24 h, with values of 13.56% and 3.93% respectively. Subsequently, high-temperature tensile experiments were conducted on these two alloys at temperatures of 150 °C, 200 °C, 250 °C, and 300 °C. The results showed that both alloys exhibited the PLC effect at temperatures ranging from 150 to 250 °C. However, at a temperature 300 °C, only the alloy with a greater concentration of LPSO phases exhibited the PLC effect, whereas the alloy with a lower proportion of LPSO phases did not exhibit this phenomenon. Additionally, both alloys exhibited remarkable high-temperature stability, with the alloy containing a greater percentage of LPSO phases also demonstrating superior strength. The underlying mechanism for this phenomenon lies in the exceptional high-temperature stability exhibited by the second phase within the alloy. Furthermore, the LPSO phase effectively obstructs the movement of dislocations, and it also undergoing kinking to facilitate plastic deformation of the alloy. The results indicate that the PLC effect can be suppressed by reducing dislocation pile-up at grain boundaries, which leads to a decrease in alloy plasticity but an increase in strength. The presence of the PLC effect in the WA121 alloy is attributed to the abundant dispersed second phase within the alloy, which initially hinders the movement of dislocations, leading to an increase in stress, and subsequently releases the dislocations, allowing them to continue their movement and thereby reducing in stress.

Key words: Magnesium alloy, Long-period stacking ordered (LPSO) phase, Portevin-Le Chatelier effect, High temperature

Qian-Long Ren, Shuai Yuan, Shi-Yu Luan, Jin-Hui Wang, Xiao-Wei Li, Xiao-Yu Liu. High-Temperature Stability of Mg-1Al-12Y Alloy Containing LPSO Phase and Mechanism of Its Portevin-Le Chatelier (PLC) Effect[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(6): 982-998.

Figures/Tables 18

Table 1 Different alloys with different heat-treatment processes

Sample No	Heat-treatment processes
W530-x (x = 8, 16, 24)	530 °C/x h (x = 8, 16, 24)	Quenched in water
W560-x (x = 8, 16, 24)	560 °C/x h (x = 8, 16, 24)	Quenched in water
F530-x (x = 8, 16, 24)	530 °C/x h (x = 8, 16, 24)	Cooled in furnace
F560-x (x = 8, 16, 24)	560 °C/x h (x = 8, 16, 24)	Cooled in furnace

Fig. 1 Schematic of heat treatment processes: a 530 °C, b 560 °C

Fig. 2 a OM, b SEM images showing the microstructures of WA121 alloy in the as-cast condition. EDS mapping of WA121 alloy in the as-cast condition: c, f point scan, d area scan, e line scan

Fig. 3 XRD patterns of the WA121 alloy with different heat treatment processes: a F alloy, b W alloy, c as-cast alloy

Fig. 4 OM images showing the microstructures of WA121 alloy in the different heat-treatment processes

Fig. 5 a Grain size of F alloy, b grain size of W alloy, c content of LPSO phase of F alloy, d content of LPSO phase of W alloy

Fig. 6 BF-TEM and selected area electron diffraction (SAED) patterns of a, b F530-16 alloy c, d F530-24 alloy

Fig. 7 Tensile curves of the WA121 alloy after different solution treatment processes at different temperatures

Fig. 8 Corresponding mechanical properties of WA121 alloy under high temperature for different solution processing methods: a F530-16 alloy, b F530-24 alloy

Fig. 9 SEM images of fracture surface morphology: a F530-16 alloy under tension at 250 °C; b F530-24 alloy under tension at 250 °C; c F530-16 alloy under tension at 300 °C; d F530-24 alloy under tension at 300 °C

Fig. 10 EBSD orientation map and GND diagrams near the fracture area of WA121 alloy: a, e F530-16-250, b, f F530-24-250, c, g F530-16-300, d, h F530-24-300

Table 2 Different samples exhibit distinct values of the dislocation density related to grain boundary slip

Sample	F530-16-250	F530-24-250	F530-16-300	F530-24-300
GNDs	0.6 × 10¹⁴	0.52 × 10¹⁴	0.75 × 10¹⁴	0.54 × 10¹⁴

Fig. 11 IGMA diagrams of grain size in different alloys; a, b F530-16-250 alloy, c, d F530-24-250 alloy, e, f F530-16-300 alloy, g, h F530-24-300 alloy

Fig. 12 Illustrates the schematic diagram of LPSO phase formation in WA121 alloy

Fig. 13 SEM images near the fracture surface after deformation for a F530-16 alloy and b F530-24 alloy at a tensile temperature of 250 °C, and for c F530-16 alloy and d F530-24 alloy at a tensile temperature of 300 °C

Fig. 14 SEM images of four different regions: a Region A, b Region B, c Region C, d Region D

Table 3 Parameter values and calculation results used to calculate the Orowan mechanism

Alloy	F530-16-250	F530-16-300	F530-24-250	F530-24-300
${d}_{{\text{p}}} \,(\mathrm{\mu m})$	0.3279	0.2876	0.3663	0.3396
f	0.1176	0.1032	0.0437	0.0418
$\Delta {\sigma }_{{\text{Orowan}}}\, ({\text{MPa}})$	69.5401	70.3910	31.6197	28.7465

Fig. 15 Schematic diagram of dislocation movement obstructed by the second phase

References 61

[1]	T.M. Pollock, Science 328, 5981 (2010)
[2]	J. Hwang, A. Zargaran, G. Park, O. Lee, B. Lee, N. Kim, J. Magnes. Alloy. 9, 2 (2021)
[3]	Q.H. Wang, B. Jiang, D.L. Chen, Z.Y. Jin, L.Y. Zhao, Q.S. Yang, G.S. Huang, F.S. Pan, J. Mater. Sci. 56, 12965 (2021)
[4]	Y.G. Jung, W.S. Yang, Y.J. Kim, S.K. Kim, Y.O. Yoon, H.K. Lim, D.H. Kim, J. Magnes. Alloy. 9, 5 (2021)
[5]	J.F. Nie, X. Gao, S.M. Zhu, Scr. Mater. 53, 9 (2005)
[6]	Z.Z. Jin, M. Zha, S.Q. Wang, S.C. Wang, C. Wang, H.L. Jia, H.Y. Wang, J. Magnes. Alloy. 10, 5 (2022)
[7]	S.Y. Luan, L. Zhang, L.J. Chen, W. Li, J.H. Wang, P.P. Jin, J. Mater. Res. Technol. 23, 6216 (2023)
[8]	H. Yokobayashi, K. Kishida, H. Inui, Yamasaki, M. Yamasaki, Kawamura, Y. Kawamura, Acta Mater. 59, 19 (2011).
[9]	T. Mayama, S. Agnew, K. Hagihara, K. Kamura, K. Shiraishi, M. Yamasaki, Y. Kawamura, Int. J. Plast. 154, 103294 (2022)
[10]	W. Yin, F. Briffod, T. Shiraiwa, M. Enoki, J. Magnes. Alloy. 10, 8 (2022)
[11]	G. Zhou, Y. Yang, L. Sun, J.W. Liu, H.J. Deng, C. Wen, G.B. Wei, B. Jiang, X.D. Peng, F.S. Pan, J. Mater. Res. Technol. 19, 4197 (2022)
[12]	S.Z. Wu, Y.Q. Chi, G. Garces, X.H. Zhou, H.G. Brokmeier, X.G. Qiao, M.Y. Zheng, J. Magnes. Alloy. (2023). https://doi.org/10.1016/j.jma.2023.01.013
[13]	S. Malopheyev, S. Mironov, R. Kaibyshev, Mater Charact 200, 112909 (2023)
[14]	F. Bakare, L. Jiang, T. Langan, M. Weiss, Thomas Dorin. Mater. Sci. Eng. A 875, 145108 (2023)
[15]	C.H. Wu, H. Li, T.J. Bian, C. Lei, L.W. Zhang, Mater Charact 184, 111694 (2022)
[16]	A.H. Cottrell, Philos. Mag. 44, 335 (1953)
[17]	A. Van Den Beukel, U.F. Kocks, Acta Metall. 30, 5 (1982)
[18]	R.H. Shi, J. Magnes. Alloy. 10, 9 (2021)
[19]	Y.W. Chen, M.D. Yu, J.Y. Wang, Q. Li, W.S. Zheng, J.B. Li, X.Q. Zeng, Mater. Des. 235, 112400 (2023)
[20]	W. Liu, Y.H. Zhao, Y.T. Zhang, C. Shuai, L.W. Chen, Z.Q. Huang, H. Hou, Int. J. Plast. 164, 103573 (2023)
[21]	L.D. Xu, S.J. Ding, X.C. Cai, Y. Wu, Z.J. Li, K.K. Wen, S.W. Xin, B.R. Sun, M.X. Huang, T.D. Shen, Corros. Sci. 208, 110624 (2022)
[22]	J.Q. Hao, J.S. Zhang, H.X. Wang, W.L. Cheng, Y. Bai, J. Mater. Res. Technol. 19, 1650 (2022)
[23]	G.L. Bi, N.M. Zhang, J. Jiang, Y.D. Li, T.J. Chen, W. Fu, X.R. Zhang, D.Q. Fang, X.D. Ding, J. Rare Earths 41, 3 (2023)
[24]	Y. Zhao, J.X. Zheng, X.D. Wang, X.Q. Zeng, B. Chen, J. Alloys Compd. 887, 161423 (2021)
[25]	Y.W. Yang, C.R. Ling, Y.G. Li, S.P. Peng, D.Q. Xie, L.D. Shen, Z.J. Tian, C.J. Shuai, J. Mater. Sci. Technol. 144, 1 (2023)
[26]	Z. Yang, T. Nakata, C. Xu, G. Wang, L. Geng, S. Kamado, J. Alloy. Compd. 934, 167906 (2023)
[27]	J.K. Kim, W.S. Ko, S. Sandlöbes, M. Heidelmann, B. Grabowski, D. Raabe, Acta Mater. 112, 171 (2016)
[28]	S. Yuan, J.H. Wang, X.Q. Li, H.B. Ma, L. Zhang, P.P. Jin, J. Magnes. Alloy. (2022). https://doi.org/10.1016/j.jma.2022.03.005
[29]	Y.W. Chen, Q. Li, Y.X. Li, W.S. Zheng, J.Y. Wang, X.Q. Zeng, J. Mater. Sci. Technol. 126, 80 (2022)
[30]	D. Qiu, M.X. Zhang, J.A. Taylor, P.M. Kelly, Acta Mater. 57, 10 (2009)
[31]	J.H. Wang, F.A. Wei, B. Shi, Y.L. Ding, P.P. Jin, Mater. Sci. Eng. A 765, 138288 (2019)
[32]	J.M. Meier, J. Caris, A.A. Luo, J. Magnes. Alloy. 10, 6 (2022)
[33]	H. Liu, H. Huang, J.P. Sun, C. Wang, J. Bai, A.B, Ma, X.H. Chen, Acta Metall. Sin. -Engl. Lett. 32, 269 (2019).
[34]	W.H. Wang, D. Wu, S.S.A. Shah, R.S. Chen, C.S. Lou, Mater. Sci. Eng. A 649, 214 (2016)
[35]	Y.Z. Shen, K.H. Oh, D.N. Lee, Scr. Mater. 51, 4 (2004)
[36]	S. Woo, R.S. Pei, T. Al-Samman, D. Letzig, S.B. Yi, J. Magnes. Alloy. 10, 1 (2022)
[37]	C. Ha, J. Bohlen, S. Yi, X. Zhou, H. Brokmeier, N. Schell, D. Letzig, K. Kainer, Mater. Sci. Eng. A 761, 138053 (2019)
[38]	T. Al-Samman, X. Li, Mater. Sci. Eng. A 528, 10 (2011)
[39]	I. Basu, T. Al-Samman, Acta Mater. 67, 116 (2014)
[40]	L. Wang, J. Teng, P. Liu, A. Hirata, E. Ma, Z. Zhang, M. Chen, X. Han, Nat. Commun. 5, 4402 (2014)
[41]	M. Wang, Z.S. Li, Y.B. Hu, Y.X. Dai, L. Fu, B. Jiang, F.S. Pan, J. Mater. Res. Technol. 24, 4685 (2023)
[42]	S. Woo, R.S. Pei, T. Al-Samman, D. Letzig, S.B. Yi, J. Magnes. Alloy. 11, 2 (2023)
[43]	Z. Zhang, J.H. Zhang, J.S. Xie, S.J. Liu, W. Fu, R.Z. Wu, Int. J. Plasticity. 162, 103548 (2023)
[44]	S. Yuan, J.H. Wang, L. Zhang, S.Y. Luan, P.P. Jin, J. Mater. Sci. Technol. 142, 152 (2023)
[45]	Z. Zhang, J.H. Zhang, W.K. Wang, S.J. Liu, B. Sun, J.S. Xie, T.X. Xiao, Scr. Mater. 221, 114963 (2022)
[46]	X.G. Sun, M. Nouri, Y. Wang, D.Y. Li, Wear 302, 1 (2013)
[47]	H.L. Chen, L. Lin, P.L. Mao, Z. Liu, J. Magnes. Alloy. 3, 3 (2015)
[48]	Y.X. Zhou, H.L. Wang, Q. Dong, J. Tan, X.H. Chen, B. Jiang, F.S. Pan, J. Eckert, Mater. Today Commun. 33, 104612 (2022)
[49]	H. Hao, X.T. Liu, C.F. Fang, X.G. Zhang, Mater. Sci. Eng. A 698, 27 (2017)
[50]	Z.W. Huang, Y.H. Zhao, H. Hou, P.D. Han, Physica B 407, 7 (2012)
[51]	Q.C. Zhu, X.Q. Shang, H. Zhang, X.X. Qi, Y.X. Li, X.Q. Zeng, Mater. Sci. Eng. A 831, 142166 (2022)
[52]	W. Liu, Y. Su, Y.T. Zhang, L.W. Chen, H. Hou, Y.H. Zhao, J. Magnes. Alloy. 11, 4 (2023)
[53]	N. Su, Q.C. Deng, Y.J. Wu, L.M. Peng, K. Yang, Q. Chen, Mater Charact 171, 110756 (2021)
[54]	W.L. Xu, J.M. Yu, L.C. Jia, G.Q. Wu, Z.M. Zhang, Mater Charact 178, 111215 (2021)
[55]	C. Zheng, S.F. Chen, R.X. Wang, S.H. Zhang, M. Cheng, Acta Metall. Sin. -Engl. Lett. 34, 248 (2021)
[56]	X.H. Shao, Z.Z. Peng, Q.Q. Jin, X.L. Ma, Acta Mater. 118, 177 (2016)
[57]	B. Li, J. Wu, B.G. Teng, Acta Metall. Sin. -Engl. Lett. 34, 1051 (2021)
[58]	C.Z. Li, H. Liu, Y.C. Xin, B. Guan, G.J. Huang, P.D. Wu, Q. Liu, J. Mater. Sci. Technol. 129, 135 (2022)
[59]	K. Hagihara, M. Yamasaki, Y. Kawamura, T. Nakano, Mater. Sci. Eng. A 763, 138163 (2019)
[60]	B.A. Szajewski, J.C. Crone, J. Knap, Materialia 11, 100671 (2020)
[61]	J. Wang, G.M. Zhu, L.Y. Wang, X.B. Zhang, M. Knezevic, X.Q. Zeng, Mater Charact 203, 113066 (2023)