Hot Deformation Behavior and Microstructures Evolution of GNP-Reinforced Fine-Grained Mg Composites

doi:10.1007/s40195-023-01524-9

Abstract

Abstract:

Graphene nanoplates (GNPs)-reinforced magnesium matrix composites have been attracted great attention. However, knowledge is lack for the hot deformation behavior of GNP-reinforced magnesium (GNPs/Mg) composite. In this study, the fine-grained GNPs/Mg composite was fabricated by powder metallurgy process followed by extrusion. The hot deformation behavior, microstructure evolution and dynamic recrystallization (DRX) mechanism of fine-grained GNPs/Mg composite were investigated by hot compression test and electron back-scatter diffraction (EBSD). The hot compression tests of the composite were conducted at temperatures between 423 and 573 K with the strain rates from 0.001 to 1 s^-1. The strain compensated power law equation was established to describe the hot deformation behavior of the composites. The stress exponent and activation energy of the composite are 7.76 and 83.23 kJ/mol, respectively, suggesting that the deformation mechanism is grain boundary slip controlled dislocation climb creep. The abnormally high stress exponent and activation energy are unattainable in the composite due to the fine grain size of the composites and the absence of Zener pinning and Orowan effects of GNPs reinforcement. The grain size increases with the decrease in Zener-Hollomn (Z) parameter, which can be well fitted by power-law relationship. With the increase in grain size and decrease in Z parameter, the geometrically necessary dislocation density decreases, which shows the approximately power-law relationship. A random and weak texture was formed after hot compression. The discontinuous dynamic recrystallization and continuous dynamic recrystallization mechanism dominated the DRX behavior at 473 K/0.001 s^-1 and 573 K/0.001 s^-1, respectively.

Key words: GNPs, Mg composite, Hot deformation behavior, Constitutive equations, Microstructure evolution, Dynamic recrystallization

Hengrui Hu, Jiayu Qin, Yunpeng Zhu, Jinhui Wang, Xiaoqiang Li, Peipeng Jin. Hot Deformation Behavior and Microstructures Evolution of GNP-Reinforced Fine-Grained Mg Composites[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(3): 407-424.

Figures/Tables 19

Fig. 1 Microstructures of the pure Mg powder and GNPs: a SEM image of pure Mg powder, b TEM image of GNPs (inset: the XRD pattern of GNPs), c SEM image of GNPs/Mg composite powder (inset: the XRD pattern of GNPs/Mg composite powder)

Fig. 2 EBSD and TEM maps of the extruded GNPs/Mg composites: a band contrast map (inset: grain size distribution map), b TEM image, c inverse pole figures

Fig.3 True stress-strain curves of composites compressed at different temperatures: a 0.001 s-1, b 0.01 s-1, c 0.1 s-1, d 1 s-1

Fig. 4 True stress-strain and corresponding strain hardening rate curves: a 423 K, 0.001 s-1, b 423 K, 1 s-1

Fig. 5 Linear relationship fitting curves based on the power law: a ln$\dot{\varepsilon }$ versus lnσs, b lnσs versus 1000/T, c lnZ versus lnσs, d comparison of predicted and measured steady-state flow stresses

Fig. 6 Linear relationship fitting based on the exponent law: a ln$\dot{\varepsilon }$versus σs, b σs versus 1000/T, c lnZ versus σs, d comparison of calculated and measured steady-state flow stresses

Fig. 7 Linear relationship fitting based on the hyperbolic sine law: a ln$\dot{\varepsilon }$versus ln(sinh(ασs)), b ln(sinh(ασs)) versus 1000/T, c lnZ versus ln(sinh(ασs)), d comparison of calculated and measured steady-state flow stresses

Fig. 8 Variation of a n, b Q and c lnA with true strain

Fig. 9 Comparison between the predicted and experimental flow stress curves at strain rates of: a 0.001 s-1, b 0.01 s-1, c 0.1 s-1, d 1 s-1

Fig. 10 Deform-3D simulation of the strain distribution of the composite compressed at 200 °C, 1 s-1

Fig. 11 Microstructures and grain size distribution of GNPs/Mg composites compressed at different strain rates and temperatures a-h and the grain size evolution as the function with Z parameter i

Fig. 12 Local misorientation of compressed GNPs/Mg composites at different strains and temperatures a-g, and the GND evolution as the function with Z parameter h, the i, j, k is high magnification of a, d, g enclosed by the box, respectively

Fig. 13 GOS maps of the compressed composites: a-d 573 K, 0.001 s-1, e-h 423 K, 0.001 s-1

Fig. 14 Inverse pole figures of the compressed composites

Fig. 15 Schematic diagram for the distribution of the reinforcement a particles, b GNPs in matrix alloys

Fig. 16 Liner plots of σs versus $\dot{\varepsilon }$1/8

Fig. 17 Relationship between average GND density and grain size of compressed GNPs/Mg composites

Fig. 18 DDRX behavior of the grains in samples compressed at 473 K/0.001 s-1: a invers pole figure map, b (0001) pole figure

Fig. 19 CDRX behavior of the grains in samples compressed at 573 K/0.001 s-1 (a-d): a invers pole figure map, b local misorientation map, c line profiles of misorientation angle along the arrows AB and CD in a and b, d (0001) pole figure

References 39

[1]	X.J. Wang, D.K. Xu, R.Z. Wu, X.B. Chen, Q.M. Peng, L. Jin, Y.C. Xin, Z.Q. Zhang, Y. Liu, X.H. Chen, J. Mater. Sci. Technol. 34, 245 (2018)
[2]	M. Wang, Y. Zhao, L.D. Wang, Y.P. Zhu, X.J. Wang, J. Sheng, Z.Y. Yang, H.L. Shi, Z.D. Shi, W.D. Fei, Carbon 139, 954 (2018)
[3]	Q.H. Yuan, G.H. Zhou, L. Liao, Y. Liu, L. Luo, Carbon 127, 177 (2018)
[4]	L.L. Meng, X.S. Hu, X.J. Wang, C.L. Zhang, H.L. Shi, Y.Y. Xiang, N.J. Liu, K. Wu, Mater. Sci. Eng. A 733, 414 (2018)
[5]	Y.P. Zhu, P.P. Jin, P.T. Zhao, J.H. Wang, L. Han, W.D. Fei, Mater. Sci. Eng. A 573, 148 (2013)
[6]	P. Xiao, Y.M. Gao, F.X. Xu, S.S. Yang, Y.F. Li, B. Li, S.Y. Zhao, J. Alloys Compd. 798, 1 (2019)
[7]	M.Y. Zhou, X.H. Liu, H.F. Yue, S.C. Liu, L.B. Ren, Y. Xin, L.L. Lyu, Y.L. Zhao, G.F. Quan, M. Gupta, J. Alloys Compd. 868, 159098 (2021)
[8]	Q.M. Yang, Y.C. Lin, J.Z. Guo, C. Wang, Z.J. Chen, K.G. Chen, J.C. Zhu, J. Alloys Compd. 910, 164909 (2022)
[9]	H. Wu, S.P. Wen, H. Huang, X.L. Wu, K.Y. Gao, W. Wang, Z.R. Nie, Mater. Sci. Eng. A 651, 415 (2016)
[10]	J.C. Shao, B.L. Xiao, Q.Z. Wang, Z.Y. Ma, Y. Liu, K. Yang, Mater. Sci. Eng. A 527, 7865 (2010)
[11]	A. Sarkar, M. J.N.V. Prasad, S. V.S.N. Murty, Mater. Charact. 160, 110112 (2020)
[12]	Y.P. Zhu, P.P. Jin, W.D. Fei, S.C. Xu, J.H. Wang, Mater. Sci. Eng. A 684, 205 (2017)
[13]	J.H. Zheng, C. Pruncu, K. Zhang, K.L. Zheng, J. Jiang, Mater. Sci. Eng. A 814, 141158 (2021)
[14]	J.Y. Qin, X.Q. Li, P.P. Jin, J.H. Wang, Y.P. Zhu, Acta Metall. Sin. 55, 1537 (2019)
[15]	M.R. Barnett, M.D. Nave, A. Ghaderi, Acta Mater. 60, 1433 (2012)
[16]	X.M. Chen, Y.C. Lin, D.X. Wen, J.L. Zhang, M. He, Mater. Des. 57, 568 (2014)
[17]	O. Muránsky, M.R. Barnett, V. Luzin, S. Vogel, Mater. Sci. Eng. A 527, 1383 (2010)
[18]	S.H. Park, H.S. Kim, J.H. Bae, C.D. Yim, B.S. You, Scr. Mater. 69, 250 (2013)
[19]	Y.C. Lin, X.M. Chen, Mater. Des. 32, 1733 (2011)
[20]	J. Liu, Z.S. Cui, C.X. Li, Comput. Mater. Sci 41, 375 (2008)
[21]	J.Q. Li, J. Liu, Z.S. Cui, Mater. Des. 56, 889 (2014)
[22]	M.R.G. Garcés, P.A.P. Pérez, Compos. Sci. Technol. 67, 632 (2007)
[23]	L. Chen, W.Y. Sun, J. Lin, G.Q. Zhao, G.C. Wang, Results Phys. 12, 784 (2019)
[24]	Y.P. Zhu, J.Y. Qin, J.H. Wang, P.P. Jin, Adv. Eng. Mater. 24, 2100905 (2021)
[25]	H. Gao, Y. Huang, W.D. Nix, J.W. Hutchinson, J. Mech. Phys. Solids 47, 1239 (1999)
[26]	J.C. Li, X.D. Wu, B. Liao, L.F. Cao, Mater. Today Commun. 29, 102810 (2021)
[27]	X.Y. Yang, H. Miura, T. Sakai, Mater. Trans. 44, 197 (2003)
[28]	T. Al-Samman, G. Gottstein, Mater. Sci. Eng. A 490, 411 (2008)
[29]	K.K. Deng, C.J. Wang, K.B. Nie, X.J. Wang, Acta Metall. Sin. -Engl. Lett. 32, 413 (2019)
[30]	K.B. Nie, Z.H. Zhu, K.K. Deng, T. Wang, J.G. Han, Nanomaterials 9, 57 (2019)
[31]	R.Q. Lu, Z.M. Xu, F. Jiang, S.W. Xu, D.F. Fu, H. Zhang, J. Teng, J. Magnesium Alloys (2021). https://doi.org/10.1016/j.jma.2021.08.001
[32]	T.G. Nieh, J. Wadsworth, O. Sherby, Superplasticity in metals and ceramics (Cambridge University Press, New York, 1997)
[33]	X.J. Wang, X.S. Hu, K. Wu, K.K. Deng, W.M. Gan, C.Y. Wang, M.Y. Zheng, Mater. Sci. Eng. A 492, 481 (2008)
[34]	L.Q. Zhan, G.J. Xue, J.L. Yang, W.C. Zhang, X.Y. Jiao, G. Wang, G.F. Wang, Mater. Sci. Eng. A 846, 143314 (2022)
[35]	J.Y. Zhang, B. Wang, H. Wang, Mater. Charact. 162, 110190 (2020)
[36]	A. Hadadzadeh, M.A. Wells, S.K. Shaha, H. Jahed, B.W. Williams, J. Alloys Compd. 702, 274 (2017)
[37]	O. Sitdikov, R. Kaibyshev, Mater. Trans. 42, 1928 (2001)
[38]	M.G. Jiang, C. Xu, H. Yan, G.H. Fan, T. Nakata, C.S. Lao, R.S. Chen, S. Kamado, E.H. Han, B.H. Lu, Acta Mater. 157, 53 (2018)
[39]	W.L. Cheng, Y. Bai, S.C. Ma, L.F. Wang, H.X. Wang, H. Yu, J. Mater. Sci. Technol. 35, 1198 (2019)