Influence of Zn and Y on Hot Compression Behavior of Mg-Li-Zn-Y Alloy

doi:10.1007/s40195-025-01936-9

Abstract

Abstract:

Mg-8.5Li-5Zn-1Y (wt%) and Mg-8.5Li-7.5Zn-1.5Y (wt%) alloys were prepared by vacuum melting casting method. The thermal flow behavior of the alloys was systematically investigated by isothermal hot compression tests using the Gleeble-3500 thermal mechanical physical simulation system. The tests were conducted under the conditions of the temperature of 473-593 K and the strain rate of 0.001-1 s⁻¹. A modified parameter polynomial constitutive model and thermal processing diagram for the two alloys were constructed. The variation pattern of the unstable region under different Zn and Y contents was analyzed and the safe processing region was determined. The influence of different areas in processing map on dislocation configuration and deformation mechanism was clarified. The results indicate that the higher contents of Zn and Y reduce the instability zone. Processing in the unstable zone only results in < a > slip, while processing in the safe zone initiates < c + a > slip also. The higher contents of Zn and Y reduce the critical deformation temperature for the initiation of < c + a > slip.

Key words: Mg-Li, Flow stress, Processing map, Slip system

Di An, Ruizhi Wu, Xiang Wang, Legan Hou, Xiaochun Ma. Influence of Zn and Y on Hot Compression Behavior of Mg-Li-Zn-Y Alloy[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(12): 2134-2144.

Figures/Tables 11

Table 1 Chemical compositions of the experimental alloys (wt%)

Designation	Number	Li	Zn	Y	Mg
Mg-8.5Li-5Zn-1Y	S₁	8.46	5.04	0.96	Bal.
Mg-8.5Li-7.5Zn-1.5Y	S₂	8.43	7.53	1.44	Bal.

Fig. 1 True stress and strain curves of a-d as-cast S1 alloys and e-h as-cast S2 alloys

Fig. 2 Peak stresses of the S1 and S2 alloys under different deformation conditions

Fig. 3 Correlation between peak stress, strain rate, and temperature: a ${\text{ln}}\dot{\varepsilon } - {\text{ln}}\sigma$, b ${\text{ ln}}\dot{\varepsilon } - \sigma$, c ${\text{ ln}}\dot{\varepsilon } - {\text{ln}}\left[ {{\text{sinh}}\left( {\alpha \sigma_{\text{p}} } \right)} \right]$, d ${\text{ ln}}\left[ {{\text{sinh}}\left( {\alpha \sigma_{\text{p}} } \right)} \right] - 1000/T$

Fig. 4 Relations fitting between materials parameters and strains of the experimental alloys: a α; b n; c Q; d lnA

Table 2 The fifth-order polynomial function coefficients of S1 and S2 alloys

Alloy	α	Value	n	Value	Q	Value	lnA	Value
S₁	α₀	0.036	n₀	3.028	Q₀	109.97	lnA₀	20.60
	α₁	0.021	n₁	−1.065	Q₁	−264.83	lnA₁	−57.46
	α₂	−0.151	n₂	10.09	Q₂	1337.33	lnA₂	300.19
	α₃	0.31	n₃	−24.25	Q₃	−2545.49	lnA₃	−581.88
	α₄	−0.261	n₄	22.772	Q₄	2101.33	lnA₄	486.12
	α₅	0.078	n₅	−7.355	Q₅	−633.27	lnA₅	−147.74
S₂	α₀	0.03847	n₀	2.429	Q₀	104.39	lnA₀	18.90
	α₁	0.01392	n₁	4.442	Q₁	86.17	lnA₁	22.67
	α₂	−0.06854	n₂	−14.23	Q₂	−59.66	lnA₂	−18.85
	α₃	0.15051	n₃	23.772	Q₃	−54.35	lnA₃	−16.11
	α₄	−0.16116	n₄	−20.72	Q₄	−53.05	lnA₄	1.92
	α₅	0.06032	n₅	7.211	Q₅	78.62	lnA₅	10.67

Fig. 5 Comparison between the experimental and predicted flow stress: a S1 alloy; b S2 alloy

Fig. 6 Processing maps of S1 and S2 alloys under different strain conditions: a, b, c S1 alloy, ε = 0.4, 0.8, 1.2; d, e, f S2 alloy, ε = 0.4, 0.8, 1.2

Fig. 7 TEM microstructure of β-Li phase at T = 473 K and $ \dot{\varepsilon }$ = 10 s−1: a S1 alloy; b S2 alloy

Fig. 8 TEM dislocation configuration of S1 alloy: a, b T = 513 K, $ \dot{\varepsilon }$ = 1 s−1; c, d T = 553 K, $ \dot{\varepsilon }$ = 1 s−1; e, f T = 513 K, $ \dot{\varepsilon }$ = 0.01 s.−1

Fig. 9 TEM dislocation configuration of S2 alloy: a, b T = 513 K, $ \dot{\varepsilon }$ = 1 s−1; c, d T = 553 K, $ \dot{\varepsilon }$ = 1 s−1; e, f T = 513 K, $ \dot{\varepsilon }$ = 0.001 s−1

References 34

[1]	T.C. Xu, X.D. Peng, J. Qin, Y.F. Chen, Y. Yang, G.B. Wei, J. Alloys Compd. 639, 79 (2015) DOI URL
[2]	S. Jin, J. Zhou, R. Wu, X. Ma, M. Pang, Z. Yu, G. Wang, J. Zhang, B. Krit, S. Betsofen, N. Vitalii, B. Ruslan, M. Qiu, Y. Yang, J. Chen, Surf. Coat. Technol. 495, 131568 (2025) DOI URL
[3]	B.Y. Qian, R.Z. Wu, J.F. Sun, J.H. Zhang, L.G. Hou, X.C. Ma, Acta Metall. Sin.-Engl. Lett. 36, 215 (2023)
[4]	Y. Gan, L. Hu, L.X. Shi, Q. Chen, M.A. Li, L. Xiang, T. Zhou, Trans. Nonferrous Met. Soc. China 33, 1373 (2023)
[5]	B.Y. Qian, R.Z. Wu, J.F. Sun, J.H. Zhang, L.G. Hou, X.C. Ma, Acta Metall. Sin.-Engl. Lett. 36, 215 (2023)
[6]	G. Li, J. Zhang, R.Z. Wu, S. Liu, B. Song, Y. Jiao, Q. Yang, L. Hou, J. Alloys Compd. 777, 1375 (2019) DOI URL
[7]	J. Xu, B. Guan, Y. Xin, G. Huang, P. Dong, Q. Liu, J. Magnes. Alloy. 12, 1021 (2024) DOI URL
[8]	Z. Wei, H. Dong, J. Zhang, R.Z. Wu, Y. He, R. Bao, X. Zhang, J. Wang, Mater. Sci. Eng. A 890, 145842 (2024)
[9]	X. Cai, Z. Wang, X. Wang, Y. Qiao, D. Xu, J. Zhou, F. Xue, J. Mater. Eng. Perform. 31, 3054 (2021) DOI
[10]	X. Feng, H. Deng, X. Ma, Z. Yang, H. Zhang, Z. Yu, W. Liu, J. Wang, L. Hou, B. Qian, J. Sun, R. Wu, J. Magnes. Alloy. (2024). https://doi.org/10.1016/j.jma.2024.09.012
[11]	C. Xu, X. Feng, H. Deng, T. Zhong, C. Zou, R. Wu, Z. Yu, X. Ma, J. Alloys Compd. 1010, 178052 (2024) DOI URL
[12]	S. Jin, X. Ma, R. Wu, T. Li, J. Wang, B.L. Krit, L. Hou, J. Zhang, G. Wang, Int. J. Miner. Metall. Mater. 29, 1453 (2022)
[13]	G. Liu, W. Xie, A. Hadadzadeh, G. Wei, Z. Ma, J. Liu, Y. Yang, W. Xie, X. Peng, M. Wells, J. Alloys Compd. 766, 460 (2018) DOI URL
[14]	P.D. Huo, F. Li, Y. Wang, R. Wu, R. Gao, A. Zhang, Mater. Des. 219, 110696 (2022) DOI URL
[15]	Y. Zhou, Z. Chen, J. Ji, Z. Sun, J. Mater. Eng. Perform. 27, 4606 (2018) DOI
[16]	G. Singh, N. Nayan, S.V. Narayana Murty, M. Yadava, G. Bajargan, M. Mohan, Mater. Sci. Eng. A 844, 143169 (2022)
[17]	Z. Ma, G. Li, Z. Su, G. Wei, Y. Huang, N. Hort, A. Hadadzadeh, M.A. Wells, J. Mater. Res. Technol. 19, 3536 (2022) DOI URL
[18]	S.A. Askariani, S.M. Hasan Pishbin, J. Alloys Compd. 688, 1058 (2016) DOI URL
[19]	Q. Ji, Y. Wang, R. Wu, Z. Wei, X. Ma, J. Zhang, L. Hou, M. Zhang, Mater. Charact. 160, 110135 (2020) DOI URL
[20]	J. Wang, L. Xu, R. Wu, J. Feng, J. Zhang, L. Hou, M. Zhang, Acta Metall. Sin.-Engl. Lett. 33, 490 (2020)
[21]	X. Li, L. Ren, Q. Le, P. Jin, C. Cheng, T. Wang, P. Wang, X. Zhou, X. Chen, D. Li, J. Alloys Compd. 831, 154868 (2020) DOI URL
[22]	K.H. Fekete, D. Drozdenko, J. Čapek, K. Máthis, D. Tolnai, A. Stark, G. Garcés, P. Dobroň, J. Magnes. Alloy. 8, 199 (2020) DOI URL
[23]	N. Bayat-Tork, R. Mahmudi, M.M. Hoseini-Athar, J. Mater. Res. Technol. 9, 15346 (2020) DOI
[24]	M. Hao, W. Cheng, L. Wang, E. Mostaed, L. Bian, H. Wang, X. Niu, Mater. Sci. Eng. A 748, 418 (2019)
[25]	A. Malik, Y. Wang, C. Huanwu, F. Nazeer, B. Ahmed, M.A. Khan, W. Mingjun, Mater. Sci. Eng. A 771, 138649 (2020)
[26]	S.H. Lu, D. Wu, R.S. Chen, E.H. Han, J. Alloys Compd. 803, 277 (2019) DOI URL
[27]	P. Prakash, D. Toscano, S.K. Shaha, M.A. Wells, H. Jahed, B.W. Williams, Mater. Sci. Eng. A 794, 139923 (2020)
[28]	W. Xu, C. Yuan, H. Wu, Z. Yang, G. Yang, D. Shan, B. Guo, B.C. Jin, J. Mater. Res. Technol. 9, 7669 (2020) DOI URL
[29]	L. Zhang, J. Wang, Y. Zhu, B. Shi, P. Jin, Mater. Res. Express. 7, 096502 (2020) DOI
[30]	Z. Ma, F. Hu, Z. Wang, K. Fu, Z. Wei, J. Wang, W. Li,Materials 13, 3107 (2020)
[31]	M. Hao, W. Cheng, L. Wang, E. Mostaed, L. Bian, H. Wang, X. Niu, J. Magnes. Alloy. 8, 899 (2020) DOI URL
[32]	W. Cheng, M. Hao, L. Wang, H. Yu, H. Wang, Mater. Sci. Eng. A 789, 139606 (2020)
[33]	W. Cheng, Y. Bai, S. Ma, L. Wang, H. Wang, H. Yu, J. Mater. Sci. Technol. 35, 1198 (2019) DOI
[34]	D. An, B. Qian, R. Wu, X. Wang, L. Hou, X. Ma, J. Zhang, J.Rare Earths 42, 2341 (2024)