Effect of Tip Content on the Work Hardening and Softening Behavior of Mg-Zn-Ca Alloy

doi:10.1007/s40195-023-01557-0

Abstract

Abstract:

The Ti_p/ZX60 composites with different Ti_p contents were prepared by semi-solid stirring casting. After extrusion, the microstructure, work hardening and softening behavior of the Ti_p/ZX60 composites were analyzed compared with the ZX60 (Mg-6Zn-0.2Ca) alloy. The results showed that the addition of Ti_p could not only promote the nucleation of dynamic recrystallized (DRXed) grains, but also be propitious to the refinement of DRXed grains. With increasing Ti_p content, the size of DRXed grains decreased accompanied with increasing volume fraction of DRXed grains. As the Ti_p content increased to 15 vol.%, the average size and volume fraction of DRXed grains reached to ~ 0.32 μm and 93.2%, respectively. Besides, both the strength and elongation were improved by the addition of Ti_p. With increasing content of Ti_p, a substantial increase in the strength was achieved with little change in the elongation. However, the elongation decreased sharply when the Ti_p content further increased to 15 vol.%. The addition of Ti_p led to an increase in the work hardening rate, which gradually increased with increasing Ti_p content. However, the softening rate did not demonstrate the same tendency with increasing Ti_p content. Unlike the conventional ceramic particles, the Ti_p can be deformed in coordination with the matrix alloy, which imparted a higher softening rate to the matrix alloy. Even though the softening rate improved as the Ti_p content increased from 5 to 10 vol.%, it dropped deeply as the Ti_p content increased to 15 vol.% owing to the fracture of Ti_p during extrusion.

Key words: Titanium particle content, Particle reinforced magnesium matrix composites, Work hardening, Softening behavior, Mechanical properties

Jin-Kai Zhang, Cui-Ju Wang, Yi-Dan Fan, Chao Xu, Kai-Bo Nie, Kun-Kun Deng. Effect of Ti_p Content on the Work Hardening and Softening Behavior of Mg-Zn-Ca Alloy[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(3): 551-560.

Figures/Tables 10

Fig. 1 OM micrographs of the as-cast ZX60 alloy and Tip/ZX60 composites with different Tip contents: a, e ZX60 alloy, b, f 5 vol.% Tip/ZX60, c, g 10 vol.% Tip/ZX60, d, h 15 vol.% Tip/ZX60

Fig. 2 SEM images and aspect ratio distributions of the as-extruded Tip/ZX60 composites with different Tip contents: a, d 5 vol.% Tip/ZX60, b, e 10 vol.% Tip/ZX60, c, f 15 vol.% Tip/ZX60

Fig. 3 OM micrographs of the as-extruded ZX60 alloy and Tip/ZX60 composites with different Tip contents: a, e ZX60 alloy, b, f 5 vol.% Tip/ZX60, c, g 10 vol.% Tip/ZX60, d, h 15 vol.% Tip/ZX60

Fig. 4 TEM images of the as-extruded Tip/Mg-6Zn-0.2Ca composite: a fine DRXed grains around Tip, b dispersed MgZn2 phases

Fig. 5 SEM images and corresponding EDS results of the as-extruded ZX60 alloy and Tip/ZX60 composites with different Tip contents: a, e ZX60 alloy, b, f 5 vol.% Tip/ZX60, c, g 10 vol.% Tip/ZX60, d, h 15 vol.% Tip/ZX60

Fig. 6 X-ray diffraction patterns of the as-extruded ZX60 alloy and Tip/ZX60 composites with different Tip contents

Fig. 7 Mechanical properties of the as-extruded ZX60 alloy and Tip/ZX60 composites with different Tip contents

Fig. 8 a Strain hardening rate curves, b, c the plot of $\theta (\sigma -{\sigma }_{0.2})\mathrm{ vs}. (\sigma -{\sigma }_{0.2})$ of the as-extruded ZX60 alloy and Tip/ZX60 composites. d k1/k and k2 values influenced by Tip content

Table 1 Parameter values of strain hardening behavior of the ZX60 and Tip/ZX60 composite

Materials	k	k₁	k₂	R²
ZX60	2657	5598	361	96.2
5 vol.% Ti_p/ZX60	2713	8871	455	98.7
10 vol.% Ti_p/ZX60	5871	14,850	470	98.8
15 vol.% Ti_p/ZX60	542	26,832	437	99.9

Fig. 9 a Cyclic stress relaxation curves, b, e the plot of $\mathrm{ln}(\mathrm{d}{\varepsilon }_{\mathrm{p}}/\mathrm{d}t) \mathrm{vs}. \mathrm{ln}(\sigma )$, c the stress relaxation curves of cycle 1, d the variation of $\Delta {\sigma }_{\mathrm{p}}$, f the relaxation rate of the as-extruded ZX60 alloy and Tip/ZX60 composites

References 53

[1]	Y. Fan, K. Deng, C. Wang, K. Nie, Q. Shi, Mater. Sci. Eng. A 833, 142336 (2022)
[2]	Y. Liu, K. Deng, X. Zhang, C. Wang, K. Nie, W. Gan, Q. Shi, Mater. Sci. Eng. A 856, 143997 (2022)
[3]	L. Zhang, K. Su, K. Deng, K. Nie, C. Wang, W. Liang, Mech. Mater. 150, 103599 (2020)
[4]	J.F. Nie, Scr. Mater. 48, 981 (2003)
[5]	X. Qian, Z. Dong, B. Jiang, B. Lei, H. Yang, C. He, L. Liu, C. Wang, M. Yuan, H. Yang, B. Yang, C. Zheng, F. Pan, Mater. Des. 224, 111322 (2022)
[6]	H. Somekawa, A. Singh, T. Mukai, Scr. Mater. 60, 411 (2009)
[7]	L. Geng, B.P. Zhang, A.B. Li, C.C. Dong, Mater. Lett. 63, 557 (2009)
[8]	J. Luo, H. Yan, N. Zheng, R.S. Chen, Acta Metall. Sin. -Engl. Lett. 29, 205 (2016)
[9]	C.J. Bettles, M.A. Gibson, K. Venkatesan, Scr. Mater. 51, 193 (2004)
[10]	T. Ying, M. Yu, Y. Chen, H. Zhang, J. Wang, X. Zeng, Acta Metall. Sin. -Engl. Lett. 35, 1973 (2022)
[11]	K.B. Nie, Z.H. Zhu, P. Munroe, K.K. Deng, J.G. Han, Acta Metall. Sin. -Engl. Lett. 33, 922 (2020)
[12]	L.G. Hou, R.Z. Wu, X.D. Wang, J.H. Zhang, M.L. Zhang, A.P. Dong, B.D. Sun, J. Alloys Compd. 695, 2820 (2017)
[13]	Y. Zhu, P. Jin, P. Zhao, J. Wang, L. Han, W. Fei, Mater. Sci. Eng. A 573, 148 (2013)
[14]	Y.H. Chen, X.Y. Gao, K.B. Nie, Y.N. Li, K.K. Deng, Mater. Sci. Eng. A 847, 143273 (2022)
[15]	Q. Shi, C. Wang, K. Deng, K. Nie, Y. Wu, W. Gan, W. Liang, J. Mater. Sci. Technol. 60, 8 (2021)
[16]	K. Nie, Y. Guo, K. Deng, X. Kang, J. Alloys Compd. 792, 267 (2019)
[17]	H. Li, K. Nie, Z. Liu, A. Yang, K. Deng, JOM 74, 4226 (2022)
[18]	A. Meher, M.M. Mahapatra, P. Samal, P.R. Vundavilli, J. Magnes, Alloys 8, 780 (2020)
[19]	W.Q. Liu, X.S. Hu, X.J. Wang, K. Wu, M.Y. Zheng, Mater. Des. 93, 194 (2016)
[20]	M. Shen, J. Jia, T. Ying, N. He, J. Alloys Compd. 791, 452 (2019)
[21]	S. Sankaranarayanan, S. Jayalakshmi, M. Gupta, Mater. Des. 37, 274 (2012)
[22]	S. Hasszn, O.O. Nasirudeen, N. Al-Aqeeli, N. Saheb, F. Patel, M.M.A. Baig, J. Alloys Compd. 646, 333 (2015)
[23]	Q. Nguyen, M. Gupta, Mater. Sci. Eng. A 527, 1411 (2010)
[24]	G. Garces, J. Medina, P. Perez, A. Stark, N. Schell, P. Adeva, J. Magnes. Alloys (2022).
[25]	J. Chen, C. Bao, W. Chen, L. Zhang, J. Liu, J. Mater. Sci. Technol. 33, 668 (2017)
[26]	R. Chen, G.D. Zhang, S. J. T. U. S. 200030 R. J Wu, H. Sekine, Acta Metall. Sin. -Engl. Lett. 10, 22 (1997).
[27]	J.H. Zhang, K.B. Nie, K.K. Deng, J.G. Han, J.Y. Yi, Compos. Commun. 27, 100847 (2021)
[28]	B. Tang, J.B. Li, J.L. Ye, H. Luo, Y.T. Wang, B. Guan, Y.F. Lu, X.H. Chen, K.H. Zheng, F.S. Pan, Acta Metall. Sin. -Engl. Lett. 35, 1935 (2022)
[29]	H. Yang, X. Chen, G. Huang, J. Song, J. She, J. Tan, K. Zheng, Y. Jin, B. Jiang, F. Pan, J. Magnes, Alloys 10, 2311 (2022)
[30]	J. Ye, X. Chen, H. Luo, J. Zhao, J. Li, J. Tan, H. Yang, B. Feng, K. Zheng, F. Pan, J. Magnes, Alloys 10, 2266 (2022)
[31]	M. Akbari, S. Rajabi, K. Shirvanimoghaddam, H. Baharvandi, J. Compos. Mater. 49, 3665 (2015)
[32]	X. Wang, X. Wang, X. Hu, K. Wu, J. Magnes, Alloys 8, 421 (2020)
[33]	J.W. Cha, S.H. Park, J. Magnes. Alloys (2022) In Press https://doi.org/10.1016/j.jma.2022.10.003.
[34]	Y. Guo, X. He, Y. Dai, H. Xiang, Q. Zang, F. Shi, X. Dong, Z. Zhang, Mater. Sci. Eng. A 860, 144329 (2022)
[35]	X. Wang, H. Liu, X. Tang, Y. Wang, M. Guo, L. Zhuang, Mater. Sci. Eng. A 844, 143154 (2022)
[36]	Y. Ren, N. ul H. Tariq, H. Liu, X. Cui, J. Wang, T. Xiong, Mater. Today Commun. 33, 104553 (2022).
[37]	K.K. Deng, K. Wu, Y.W. Wu, K.B. Nie, M.Y. Zheng, J. Alloys Compd. 504, 542 (2010)
[38]	Q. Shi, K. Deng, K. Nie, W. Zhang, M. Cao, W. Liang, J. Mater. Eng. Perform. 29, 1356 (2020)
[39]	X.J. Wang, X.S. Hu, K.B. Nie, K.K. Deng, K. Wu, M.Y. Zheng, Mater. Sci. Eng. A 545, 38 (2012)
[40]	J.D. Robson, D.T. Henry, B. Davis, Acta Mater. 57, 2739 (2009)
[41]	Q. Shi, C. Wang, K. Deng, K. Nie, M. Cao, W. Gan, W. Liang, Mater. Sci. Eng. A 772, 138827 (2020)
[42]	C. Zhao, X. Chen, J. Wang, T. Tu, Y. Dai, K.S. Shin, F. Pan, Adv. Eng. Mater. 21, 1801062 (2019)
[43]	D. Zhang, D. Zhang, F. Bu, X. Li, B. Li, T. Yan, K. Guan, Q. Yang, X. Liu, J. Meng, J. Alloys Compd. 728, 404 (2017)
[44]	H. Conrad, S. Feuerstein, L. Rice, Mater. Sci. Eng. 2, 157 (1967)
[45]	A.D. Rollett, U.F. Kocks, Solid State Phenom. 35-36, 1 (1993)
[46]	P. Lukáč, J. Balík, Key Eng. Mater. 97-98, 307 (1994)
[47]	C. Zhao, Z. Li, J. Shi, X. Chen, T. Tu, Z. Luo, R. Cheng, A. Atrens, F. Pan, J. Magnes, Alloys 7, 672 (2019)
[48]	X. Yang, Y. Wang, G. Wang, H. Zhai, L. Dai, T. Zhang, Acta Mater. 108, 252 (2016)
[49]	P. Lukáč, Z. Trojanová, Key Eng. Mater. 465, 101 (2011)
[50]	J.A. Valle, F. Carreño, O.A. Ruano, Acta Mater. 54, 4247 (2006)
[51]	J. Koike, R. Ohyama, T. Kobayashi, M. Suzuki, K. Maruyama, Mater. Trans. 44, 445 (2003)
[52]	M. Hou, K. Deng, C. Wang, K. Nie, Q. Shi, Mater. Sci. Eng. A 856, 143970 (2022)
[53]	T. Ungár, M. Zehetbauer, Scr. Mater. 35, 1467 (1996)