Achieving Twin Strengthening in Bulk Aluminum via Adding Nanoparticles Combined with Tailoring Hot Pressing Temperature

doi:10.1007/s40195-024-01771-4

Abstract

Abstract:

It is extremely difficult to strengthen bulk aluminum (Al) by twins, due to its high stacking fault energy under standard loading conditions. In this study, a simple yet effective solution was proposed for introducing twins to strengthen bulk Al. The method involves the addition of nanoparticles with high volume fraction combined with the tailoring of sintering temperature toward the melting point of Al during hot pressing. Sintering temperature plays an important role in forming twins in bulk Al containing high content nanoparticles. The twin content increases with increasing sintering temperature in the range of 590-640 °C. At sintering temperature of 640 °C, the twin content reaches 17%, enabling the significant improvement in the yield strength of the bulk Al from 251 to 400 MPa, compared with the sample with few or no twins. The twin strengthening may serve as a major strengthening mechanism for bulk Al, and its strengthening contribution is comparable to the dominant Orowan strengthening resulting from the added nanoparticles.

Key words: Bulk Al, Twins, Nanoparticle, Sintering temperature, Strength, Strengthening mechanism

Ke Zhao, Zhongying Duan, Jinling Liu, Linan An. Achieving Twin Strengthening in Bulk Aluminum via Adding Nanoparticles Combined with Tailoring Hot Pressing Temperature[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(12): 2083-2093.

Figures/Tables 9

Fig. 1 a-c SEM images and d XRD patterns of the samples sintered at different temperatures

Fig. 2 a1-a3 IPF maps of the samples sintered at 590, 620, and 640 °C, respectively; b1-b3 grain size distribution corresponding to a1, a2, and a3, respectively; b4 the average grain size as a function of sintering temperature

Fig. 3 Grain boundaries character distribution of the samples sintered at a 590, b 620, and c 640 °C, LAGB, HAGB, and TB are represented by lime green line, black line, and pink line, respectively; d the comparison of the fraction of LAGB, HAGB, and TB in the samples

Fig. 4 TEM images of the sample sintered at 590 °C: a a typical bright-field TEM image; b a higher magnification bright-field TEM image showing the nanoparticles and dislocations marked with white arrows and blue arrows, respectively

Fig. 5 TEM images of the sample sintered at 640 °C: a a typical bright-field TEM image; b the electron diffraction pattern corresponding to the area in a marked by white circle; c a typical Al2O3 particle distributed in Al matrix; d the interface between Al2O3 particle and Al matrix, the inset is FFT for the area marked with white square

Fig. 6 TEM images of the sample sintered at 640 °C: a TEM image of a typical twin at grain corner, the TBs are indicated by green arrows, the inset shows the entire grain containing numerous dislocations; b an enlarged view of the twin in a, the SFs are marked with ellipses; c the electron diffraction pattern corresponding to the region marked with black square in b; d the high resolution TEM images of TB and SFs on different {111} planes in b; e IFFT image of the region marked with white square in b, the dislocations are indicated by ⊥; f TEM image of another typical twin crossing the entire grain, the TB and dislocations are marked with green arrow and blue arrows, respectively; g the electron diffraction pattern corresponding to the twinned grain in f

Fig. 7 Distributions of recrystallized, substructured and deformed grains in the samples sintered at a 590, b 620, and c 640 °C. The LAGBs, HAGBs, and TBs are represented by lime green line, black line, and pink line, respectively; d comparison of the fraction of the recrystallized, substructured and deformed grains in samples; e1-e3 an enlarged view of the sample sintered at 640 °C, the twins formed in substructured regions are indicated by black arrows, and the twins formed in recrystallized regions are indicated by white arrows

Fig. 8 a Engineering and b true stress-strain curves of the samples sintered at different temperatures

Fig. 9 Contribution of strengthening mechanisms to the yield strength increment of the samples sintered at different temperatures

References 43

[1]	T. Cai, Z.J. Zhang, P. Zhang, J.B. Yang, Z.F. Zhang, J. Appl. Phys. 116, 163512 (2014)
[2]	W.Z. Han, G.M. Cheng, S.X. Li, S.D. Wu, Z.F. Zhang, Phys. Rev. Lett. 101, 115505 (2008)
[3]	F. Zhao, L. Wang, D. Fan, B.X. Bie, X.M. Zhou, T. Suo, Y.L. Li, M.W. Chen, C.L. Liu, M.H. Zhu, S.N. Luo, Phys. Rev. Lett. 116, 075501 (2016)
[4]	X.Z. Liao, F. Zhou, E.J. Lavernia, D.W. He, Y.T. Zhu, Appl. Phys. Lett. 83, 5062 (2003)
[5]	S.B. Jin, K. Zhang, R. Bjørge, N.R. Tao, K. Marthinsen, K. Lu, Y.J. Li, Appl. Phys. Lett. 107, 091901 (2015)
[6]	M.W. Chen, E. Ma, K.J. Hemker, H.W. Sheng, Y.M. Wang, X.M. Cheng,Science 300, 1275 (2003)
[7]	L.D. Rafailovic, C. Gammer, C. Ebner, C. Rentenberger, A.Z. Jovanovic, I.A. Pasti, N.V. Skorodumova, H.P. Karnthaler, Sci. Adv. 5, eaax3894 (2019)
[8]	Q. Li, J. Cho, S.C. Xue, X. Sun, Y.F. Zhang, Z.X. Shang, H.Y. Wang, X.H. Zhang, Acta Mater. 165, 142 (2019)
[9]	T. Cai, Z.J. Zhang, J.B. Yang, Z.F. Zhang, Acta Metall. Sin. -Engl. Lett. 29, 647 (2016)
[10]	Y. Qi, R.K. Mishra, Phys. Rev. B 75, 224105 (2007)
[11]	L.H. Liu, J.H. Chen, T.W. Fan, Z.R. Liu, Y. Zhang, D.W. Yuan, Comput. Mater. Sci. 108, 136 (2015)
[12]	Z.Q. Shi, P.Y. Li, L.H. Liu, J.B. Li, X.F. Peng, T.W. Fan, Mater. Res. Express 6, 1065b9 (2019)
[13]	Y. Liu, M.P. Liu, X.F. Chen, Y. Cao, H.J. Roven, M. Murashkin, R.Z. Valiev, H. Zhou, Scr. Mater. 159, 137 (2019)
[14]	M.P. Liu, H.J. Roven, M. Murashkin, R.Z. Valiev, Mater. Sci. Eng. A 503, 122 (2009)
[15]	L.H. Liu, J.H. Chen, T.W. Fan, S.L. Shang, Q.Q. Shao, D.W. Yuan, Y. Dai, J. Mater. Sci. Technol. 35, 2625 (2019)
[16]	D. Gong, Y.F. Cao, X.B. Deng, L.T. Jiang, Compos. Commun. 32, 101188 (2022)
[17]	Y.M. Wu, C. Zhou, R. Wu, L.X. Sun, C.Y. Lu, Y.Z. Xiao, Z.X. Su, M.Y. Gong, K.S. Ming, K. Liu, C. Gu, W.S. Yang, J. Wang, G.H. Wu, Compos. Pt. B 250, 110458 (2023)
[18]	B.S. Guo, M. Song, X.M. Zhang, Y.Z. Liu, X. Cen, B. Chen, W. Li, Compos. Pt. B 211, 108646 (2021)
[19]	Y. Li, Y.J. Lin, Y.H. Xiong, J.M. Schoenung, E.J. Lavernia, Scr. Mater. 64, 133 (2011)
[20]	K. Zhao, X.X. Zhu, J.L. Liu, Y.J. Wang, B. Chen, Q.M. Wei, L.N. An, Compos. Commun. 25, 100753 (2021)
[21]	D.S. Zhou, F. Qiu, H.Y. Wang, Q.C. Jiang, Acta Metall. Sin. -Engl. Lett. 27, 798 (2014)
[22]	X.Z. Liao, S.G. Srinivasan, Y.H. Zhao, M.I. Baskes, Y.T. Zhu, F. Zhou, E.J. Lavernia, H.F. Xu, Appl. Phys. Lett. 84, 3564 (2004)
[23]	X.Y. Song, R. Markus, J.X. Zhang, Acta Metall. Sin. 40, 1009 (2004)
[24]	Z. Chen, G.A. Sun, Y. Wu, M.H. Mathon, A. Borbely, D. Chen, G. Ji, M.L. Wang, S.Y. Zhong, H.W. Wang, Mater. Des. 116, 577 (2017)
[25]	L. Wang, F. Qiu, Q.L. Zhao, H.Y. Wang, Q.C. Jiang, Mater. Charact. 125, 7 (2017)
[26]	C.D. Wu, G.Q. Luo, J. Zhang, Q. Shen, Z.H. Gan, J. Liu, L.M. Zhang, Powder Technol. 339, 809 (2018)
[27]	K.T. Kashyap, Bull. Mater. Sci. 24, 643 (2001)
[28]	S.J. Abraham, I. Dinaharan, J.D.R. Selvam, E.T. Akinlabi, Acta Metall. Sin. -Engl. Lett. 32, 52 (2019)
[29]	L. Wang, F. Qiu, Q.L. Zhao, M. Zha, Q.C. Jiang, Sci. Rep. 7, 4540 (2017) DOI PMID
[30]	Q.F. Wu, Z.J. Wang, F. He, Z.S. Yang, J.J. Li, J.C. Wang, J. Mater. Sci. Technol. 128, 71 (2022)
[31]	M.M. Wang, M. Knezevic, H.Y. Gao, J. Wang, M.D. Kang, B.D. Sun, Mater. Charact. 179, 111322 (2021)
[32]	B. Li, B.Y. Cao, K.T. Ramesh, E. Ma, Acta Mater. 57, 4500 (2009)
[33]	X. Zhang, B. Grabowski, F. Körmann, A.V. Ruban, Y.L. Gong, R.C. Reed, T. Hickel, J. Neugebauer, Phys. Rev. B 98, 224106 (2018)
[34]	X.H. Yang, S. Ni, M. Song, Mater. Sci. Eng. A 641, 189 (2015)
[35]	S. Mahajan, C.S. Pande, M.A. Imam, B.B. Rath, Acta Mater. 45, 2633 (1997)
[36]	R.L. Higginson, M. Aindow, P.S. Bate, Phil. Mag. Lett. 72, 193 (1995)
[37]	A.B. Li, G.S. Wang, X.X. Zhang, Y.Q. Li, X. Gao, H. Sun, M.F. Qian, X.P. Cui, L. Geng, G.H. Fan, Mater. Sci. Eng. A 745, 10 (2019)
[38]	K. Zhao, Z.Y. Duan, J.L. Liu, G.Z. Kang, L.N. An, Acta Metall. Sin. -Engl. Lett. 35, 915 (2022)
[39]	X.X. Xiong, S.J. Yu, P. Wang, J.F. Qi, H.C. Li, X.L. Wang, M. Ryan, D. Bhaduri, R. Setchi, Acta Metall. Sin. -Engl. Lett. 37, 67 (2024)
[40]	A. Sanaty-Zadeh, Mater. Sci. Eng. A 531, 112 (2012)
[41]	L.H. Dai, Z. Ling, Y.L. Bai, Compos. Sci. Technol. 61, 1057 (2001)
[42]	A. Kelly, R.B. Nicholson, Strengthening Methods in Crystals (Elsevier, Amsterdam, 1971), p.9
[43]	J. Wang, X.H. Zhang, MRS Bull. 41, 274 (2016)