A Composite Structure of Al-Mg-Sc Alloy Prepared by Wire Arc-Directed Energy Deposition with Interlayer Friction Stir Processing

doi:10.1007/s40195-025-01905-2

Abstract

Abstract:

Interlayer friction stir processing (FSP) has been proved to be an effective method of enhancing the mechanical properties of wire arc-directed energy deposited (WA-DED) samples. However, the original deposition structure was still retained in the FSP-WA-DED component besides the processed zone (PZ), thus forming a composite structure. Considering the material utilization and practical service process of the deposited component, more attention should be paid on this special composite structure, but the relevant investigation has not been carried out. In this study, an Al-Mg-Sc alloy was prepared by WA-DED with interlayer FSP treatment, and the composite structure was firstly investigated. Almost all of the pores were eliminated under the pressure effect from the tool shoulder. The grains were further refined with an average size of about 1.2 μm in the PZ. Though no severe plastic deformation was involved in the retained WA-DED deposition zone, comparable tensile properties with the PZ sample were obtained in the composite structure. Low ultimate tensile strength (UTS) of 289 MPa and elongation of 3.2% were achieved in the WA-DED sample. After interlayer FSP treatment, the UTS and elongation of the PZ samples were significantly increased to 443 MPa and 16.3%, while those in the composite structure remained at relatively high levels of 410 MPa and 13.5%, respectively. Meanwhile, a high fatigue strength of 180 and 130 MPa was obtained in the PZ and composite structure samples, which was clearly higher than that of the WA-DED sample (100 MPa). It is concluded that the defects in traditional WA-DED process can be eliminated in the composite structure after interlayer FSP treatment, resulting in enhanced tensile and fatigue properties, which provides an effective method of improving the mechanical properties of the WA-DED sample.

Key words: Wire arc-directed energy deposition, Al-Mg-Sc alloys, Friction stir processing, Composite structure, Mechanical property

Y. P. Cui, X. P. Guo, P. Xue, R. Z. Xu, X. M. Guo, D. R. Ni, Z. Y. Ma. A Composite Structure of Al-Mg-Sc Alloy Prepared by Wire Arc-Directed Energy Deposition with Interlayer Friction Stir Processing[J]. Acta Metallurgica Sinica (English Letters), 2025, 38(10): 1794-1808.

Figures/Tables 18

Table 1 Chemical compositions of the feed wire (wt%)

Wire	Mg	Mn	Sc	Zr	Ti	Si	Fe	Al
Al-Mg-Sc	6.31	0.67	0.29	0.23	0.13	0.005	0.067	Bal.

Table 2 Deposition parameters of the WA-DED process under CMT mode

Wire feed speed (m/min)	Voltage (V)	Current (A)	Deposition speed of the path (m/min)	Deposition speed of corners (m/min)
6.8	10.5	117	1.26	0.84

Fig. 1 Schematic diagrams of the deposition paths of a WA-DED, b wide WA-DED, c assisted interlayer FSP processes

Fig. 2 Schematic diagrams of a sample locations, b, d tensile specimen dimensions, c, e fatigue specimen dimensions from FSP-WA-DED sample

Fig. 3 a Macrostructure of WA-DED sample, typical morphologies of pores in b remelt zone, c molten pool zone, d microstructure in the molten pool zone of WA-DED sample, e macrostructure of FSP-WA-DED sample, microstructures of f PZ, g SAZ, h TMAZ

Fig. 4 a EBSD inverse pole figure (IPF) map, b grain size distribution of WA-DED component

Fig. 5 EBSD sampling locations in the FSP-WA-DED sample

Fig. 6 EBSD IPF maps and grain size distributions of a, b PZ, c, d TMAZ in FSP-WA-DED sample

Fig. 7 EBSD IPF maps and grain size distributions of a, b SAZ, c, d WA-DED deposition zone in FSP-WA-DED sample

Fig. 8 Misorientation angle distributions in a WA-DED sample; b PZ, c TMAZ, d SAZ, and e deposition zone of the FSP-WA-DED sample

Fig. 9 Industrial CT images and pore statistic results a, b CT images of WA-DED sample, c statistic result of pores in WA-DED sample, d, e CT images of FSP-WA-DED sample, f statistic result of pores in FSP-WA-DED sample

Fig. 10 BSE images and phase statistic results of a, c WA-DED sample, b, d PZ in FSP-WA-DED sample

Table 3 EDS spot scanning results for second phases in Fig. 10 (at.%)

Spot	Al	Mg	Sc	Zr	Ti
A1	76.1	3.3	10.2	4.7	3.1
A2	81.7	2.6	7.6	3.1	2.3
B1	83.4	2.9	5.3	3.1	2.8
B2	79.2	3.1	9.4	3.7	1.9

Fig. 11 Tensile properties of the WA-DED and FSP-WA-DED samples: a engineering stress-strain curves, b tensile strength and elongation of various samples

Fig. 12 Typical morphologies of fracture surfaces after tensile tests in a, b WA-DED sample, c, d PZ sample, e, f composite structure sample

Fig. 13 Stress-fatigue life (S-N) curves of various samples after aging

Fig. 14 Typical morphologies of fatigue surfaces in various samples: a, b WA-DED sample at the maximum stresses of 120 MPa, c, d PZ sample at the maximum stresses of 200 MPa, and e composite structure sample at the maximum stresses of 140 MPa

Fig. 15 Fatigue crack propagation paths of a WA-DED sample, b PZ sample, c composite structure sample

References 46

[1]	Q. Li, X.R. Li, B.X. Dong, X.L. Zhang, S.L. Shu, F. Qiu, L.C. Zhang, Z.H. Zhang, Acta Metall. Sin.-Engl. Lett. 37, 29 (2024)
[2]	Z. Liu, P. Zhang, S. Li, D. Wu, Z. Yu, Int. J. Miner. Metall. Mater. 27, 783 (2020)
[3]	J. Hu, T. Sun, F. Cao, Y. Shen, Z. Yang, C. Guo, Acta Metall. Sin.-Engl. Lett. 37, 793 (2024)
[4]	Y. Guo, Q. Han, J. Hu, X. Yang, P. Mao, J. Wang, S. Sun, Z. He, J. Lu, C. Liu, Acta Metall. Sin.-Engl. Lett. 35, 475 (2022)
[5]	Y. Wei, F. Liu, F. Liu, D. Yu, Q. You, C. Huang, Z. Wang, W. Jiang, X. Lin, X. Hu, J. Mater. Res. Technol. 24, 3477 (2023)
[6]	X. Cai, Y. Hou, W. Zhang, Z. Fan, Y. Gao, J. Wang, H. Sun, Z. Zhang, W. Yang, Int. J. Miner. Metall. Mater. 31, 737 (2024)
[7]	X. Fang, K. Li, M. Ma, C. Liu, Y. Zhang, J. Zhou, Z. Li, J. Shang, K. Huang, B. Lu, Virtual Phys. Prototyp. 19, e2370956 (2024)
[8]	G. Zhu, B. Kang, M.L. Zhu, F.Z. Xuan, Mater. Sci. Eng. A 904, 146707 (2024)
[9]	R. Xu, R. Li, T. Yuan, H. Zhu, P. Li, Acta Metall. Sin.-Engl. Lett. 35, 411 (2022)
[10]	S. Wu, C. Yang, P. Zhang, H. Xue, Y. Gao, Y. Wang, R. Wang, J. Zhang, G. Liu, J. Sun, Int. J. Miner. Metall. Mater. 31, 1098 (2024)
[11]	Z. Li, F. Jiang, L. Liu, Y. Wang, Mater. Sci. Technol. 39, 1961 (2023)
[12]	S. Aguado Montero, J. Vázquez, C. Navarro, J. Domínguez, Int. J. Fatigue 181,108146 (2024).
[13]	Z. Qin, N. Kang, F. Zhang, Z. Wang, Q. Wang, J. Chen, X. Lin, W. Huang, Int. J. Fract. 235, 129 (2022)
[14]	X. Guo, D. Ni, H. Li, P. Xue, R. Xu, Z. Pan, S. Zhou, Z. Ma, J. Mater. Process. Technol. 322, 118173 (2023)
[15]	Z. Qin, X. Ma, J. Li, Y. Zhao, Z. Zhang, C. Shan, H. Liu, Y. Qi, Y. Xie, X. Meng, Y. Huang, J. Manuf. Process. 124, 1459 (2024)
[16]	C. He, J. Wei, Y. Li, Z. Zhang, N. Tian, G. Qin, L. Zuo, J. Mater. Sci. Technol. 133, 183 (2023)
[17]	G. Xie, R. Duan, Y. Wang, Z. Luo, G. Wang, Int. J. Miner. Metall. Mater. 30, 724 (2023)
[18]	J. Wei, C. He, Y. Zhao, M. Qie, G. Qin, L. Zuo, Mater. Sci. Eng. A 868, 144794 (2023)
[19]	X.S. Feng, S.B. Li, L.N. Tang, H.M. Wang, Acta Metall. Sin.-Engl. Lett. 33, 30 (2020)
[20]	P. Chen, W. Chen, J. Chen, Z. Chen, Y. Tang, G. Liu, B. Huang, Z. Zhang, Acta Metall. Sin.-Engl. Lett. 37, 855 (2024)
[21]	Y. Shen, J. Wang, B. Wang, P. Xue, F. Liu, D. Ni, B. Xiao, Z. Ma, Int. J. Miner. Metall. Mater. 31, 2498 (2024)
[22]	M. Wu, B. Li, Mater. Chem. Phys. 329, 130046 (2025)
[23]	A. Yadollahi, N. Shamsaei, Int. J. Fatigue 98,14 (2017)
[24]	E.M. Ryan, T.J. Sabin, J.F. Watts, M.J. Whiting, J. Mater. Process. Technol. 262, 577 (2018)
[25]	M. Bergant, N.O. Larrosa, A. Yawny, M. Madia, Eng. Fract. Mech. 289, 109467 (2023)
[26]	G.B. Teng, C.Y. Liu, Z.Y. Ma, W.B. Zhou, L.L. Wei, Y. Chen, J. Li, Y.F. Mo, Mater. Sci. Eng. A 713, 61 (2018)
[27]	R. Fonda, J. Bingert, Metall. Mater. Trans. Phys. Metall. Mater. Sci. 35, 1487 (2004)
[28]	J.Q. Su, T.W. Nelson, C.J. Sterling, Mater. Sci. Eng. A 405, 277 (2005)
[29]	M. Narimani, B. Lotfi, Z. Sadeghian, Mater. Sci. Eng. A 673, 436 (2016)
[30]	X. Luo, H. Liu, L. Kang, J. Lin, D. Zhang, D. Li, D. Chen, Acta Metall. Sin.-Engl. Lett. 35, 757 (2022)
[31]	H. Liu, R. Hou, C. Wu, R. Xie, S. Chen, Int. J. Miner. Metall. Mater. 32, 425 (2025)
[32]	A. Adetunla, E. Akinlabi, T.C. Jen, J. Mater. Res. Technol. 29, 5721 (2024)
[33]	K.T. Son, C.H. Cho, M.G. Kim, J.W. Lee, Int. J. Miner. Metall. Mater. 31, 1900 (2024)
[34]	S. Fan, Z. Li, W. Xiao, P. Yan, J. Feng, Q. Jiang, J. Ma, Y. Gong, J. Mater. Sci. Technol. 188, 202 (2024)
[35]	J. Jiang, F. Jiang, M. Zhang, Z. Tang, M. Tong, J. Alloys Compd. 831, 154856 (2020)
[36]	B. Liu, S. Lu, R. Bao, J. Wang, L. Shi, Theor. Appl. Fract. Mech. 132, 104492 (2024)
[37]	M.M. El Rayes, E.A. El Danaf, M.S. Soliman, Mater. Des. 32, 1916 (2011)
[38]	F. Girault, L. Toualbi, Q. Barres, E. Charkaluk, Mater. Sci. Eng. A 927, 147979 (2025)
[39]	M. Wu, D. Xiao, S. Yuan, S. Tang, Z. Li, X. Yin, L. Huang, W. Liu, Mater. Charact. 205, 113349 (2023)
[40]	Z.Y. Zhou, Z.Y. Jiang, Q.Y. Zheng, Y. Li, Z.P. Yuan, C. Ding, Z.Y. Piao, Tribol. Int. 194, 109448 (2024)
[41]	G. Rajan, S. Mula, J. Manuf. Process. 106, 19 (2023)
[42]	M.M. El-Sayed, A.Y. Shash, M. Abd-Rabou, M.G. ElSherbiny, J. Adv. Join. Process. 3, 100059 (2021)
[43]	X. Hou, L. Zhao, S. Ren, Y. Peng, C. Ma, Z. Tian, X. Qu, Addit. Manuf. 88, 104260 (2024)
[44]	T. Inamura, N. Takezawa, T. Miura, K. Yamada, CIRP Ann. 54, 507 (2005)
[45]	X.H. An, S.D. Wu, Z.G. Wang, Z.F. Zhang, Acta Mater. 74, 200 (2014)
[46]	B.S. Gong, Z.J. Zhang, Z. Qu, J.P. Hou, H.J. Yang, X.H. Shao, Z.F. Zhang, Int. J. Fatigue 156,106682 (2022)