Fracture toughness of titanium alloys fabricated by high-power laser-directed energy deposition: Fractal analysis and prediction model

doi:10.1016/j.jmst.2024.12.027

Abstract

Abstract: Laser additive-manufactured (AM) metallic components typically have superior uniaxial tensile strength to their conventional processing counterparts. However, the strength and toughness trade-off for most AM-fabricated metallic parts remains unsolved. Generally, the heat treatment processes can enhance the elongation and toughness of as-deposited AM samples. In this work, the fracture toughness of high-power (7600 W) laser directed energy deposition Ti-6Al-4V (Ti64) + heat treatment (short as Ti64 DED-HT) samples, were studied using fracture property tests. Combining electron backscatter diffraction (EBSD), confocal laser scanning microscope, and fractal geometry theory, we investigated their fracture mechanism and proposed a new prediction model between plane-strain fracture toughness (K_Ic) and conventional tensile properties. The results show that the plane-strain fracture toughness value in four states (two scanning speeds and two directions) is 81.3 ± 0.7 MPa m^1/2, higher than that of the wrought counterparts (∼65 MPa m^1/2). This high plane-strain fracture toughness results from the combination of relatively fine columnar β grains and coarse α laths of the deposited parts after a specific heat-treated process. Combined with a confocal laser scanning microscope and fractal geometry analysis theory, we found that the rough surface profile leads to high fractal dimension values. In addition, we proposed a modified analytical prediction model, which can effectively predict the plane-strain fracture toughness value of AM Ti64 titanium alloys. These findings provide a guideline for obtaining a high strength-toughness and reliably predicting its K_Ic value in AM titanium alloys.

Key words: Additive manufacturing, Laser-directed energy deposition, Fracture toughness, Titanium alloy, Fractal analysis

Yongming Ren, Yuanshuai Cao, Yongqin Liu, Ziqi Jie, Zengyun Jian, Man Zhu, Shixing Huang, Meng Wang, Yinghui Zhou, Xin Lin, Weidong Huang. Fracture toughness of titanium alloys fabricated by high-power laser-directed energy deposition: Fractal analysis and prediction model[J]. J. Mater. Sci. Technol., 2025, 228: 54-74.

References

[1] R.O. Ritchie, Nat. Mater. 10(2011) 817-822.
[2] R.O. Ritchie, Philos. Trans. A 379 (2021) 20200437.
[3] T.H. Becker, P. Kumar, U. Ramamurty, Acta Mater. 219(2021) 117240.
[4] D. Banerjee, J.C. Williams, Acta Mater. 61(2013) 844-879.
[5] B. Blakey-Milner, P. Gradl, G. Snedden, M. Brooks, J. Pitot, E. Lopez, M. Leary, F. Berto, A.d. Plessis, Mater. Des. 209 (2021) 110008.
[6] H.L. Wei, T. Mukherjee, W. Zhang, J.S. Zuback, G.L. Knapp, A. De, T. DebRoy, Prog. Mater. Sci. 116(2021) 100703.
[7] J.J. Lewandowski, M. Seiﬁ, Ann. Rev. Mater. Res. 46(2016) 151-186.
[8] Y. Kok, X.P. Tan, P. Wang, M.L.S.Nai, N.H. Loh, E. Liu, S.B. Tor, Mater. Des. 139(2018) 565-586.
[9] S.H. Li, P. Kumar, S. Chandra, U. Ramamurty, Int. Mater. Rev. 68(2023) 605-647.
[10] H.Y. Ma, J.C. Wang, P. Qin, Y.J. Liu, L.Y. Chen, L.Q. Wang, L.C. Zhang, J Mater. Sci.Technol. 183(2024) 32-62.
[11] Z. Qu, Z.J. Zhang, R. Liu, L. Xu, Y.N. Zhang, X.T. Li, Z.K. Zhao, Q.Q. Duan, S.G. Wang, S.J. Li, Y.J. Ma, X.H. Shao, R. Yang, J. Eckert, R.O. Ritchie, Z.F. Zhang, Nature 626 (2024) 999-1004.
[12] P. Kumar, S. Huang, D.H. Cook, K. Chen, U. Ramamurty, X. Tan, R.O. Ritchie, Nat. Commun. 24(2024) 841.
[13] X.K. Zhu, Int. J. Press. Vessel Pip. 139-140(2016) 173-183.
[14] G. Niu, H.S. Zurob, R.D.K.Misra, Q. Tang, Z.Zhang, M. Nguyen, L. Wang, H. Wu, Y. Zou, Acta Mater. 226(2022) 117642.
[15] X. Liu, S. Zhang, H. Feng, J. Wang, P. Jiang, H. Li, F. Yuan, X. Wu, Acta Mater. 255(2023) 119079.
[16] Y. Zhou, X. Lin, Z. Jian, S. Huang, Y. Ren, Y. Wu, X. Yang, W. Shao, Mater. Sci. Eng. A 881 (2023) 145420.
[17] D.H. Cook, P. Kumar, M.I. Payne, C.H. Belcher, P. Borges, W. Wang, F. Walsh, Z. Li, A. Devaraj, M. Zhang, M. Asta, A.M. Minor, E.J. Lavernia, D. Apelian, R.O. Ritchie, Science 384 (2024) 178-184.
[18] D. Liu, Q. Yu, S. Kabra, M. Jiang, P. Forna-Kreutzer, R. Zhang, M. Payne, F. Walsh, B. Gludovatz, M. Asta, A.M. Minor, E.P. George, R.O. Ritchie, Science 378 (2022) 978-983.
[19] P. Kumar, M. Michalek, D.H. Cook, H. Sheng, K.B. Lau, P. Wang, M. Zhang, A. M. Minor, U. Ramamurty, R.O. Ritchie, Acta Mater. 258(2023) 119249.
[20] W.F. Hosford, Mechanical Behavior of Materials, Cambridge University Press, 2005.
[21] E399-12, Standard Test Method for Linear-Elastic Plane-Strain Fracture Tough- ness KIc of Metallic Materials, ASTM International, West Conshohocken, United States, 2012, pp. 1-33.
[22] M.J. Paul, J.J. Kruzic, U. Ramamurty, B. Gludovatz, Acta Mater. 276(2024) 120061.
[23] S. Shrestha, J. El Rassi, M. Kannan, G. Morscher, A.L. Gyekenyesi, O.E. Scott-E-muakpor, Mater. Sci. Eng. A 823 (2021) 141701.
[24] P. Edwards, M. Ramulu, Fatigue Fract. Eng. Mater. Struct. 38(2015) 1228-1236.
[25] V. Cain, L. Thijs, J. Van Humbeeck, B. Van Hooreweder, R. Knutsen, Addit. Manuf. 5(2015) 68-76.
[26] Y. Xiao, G. Qian, J. Sun, F. Berto, J.A.F.Correia, Y. Hong, Theo. App. Fract. Mech. 125(2023) 103931.
[27] P. Edwards, A. O'Conner, M. Ramulu, J. Manuf. Sci.Eng. 135(2013) 061016.
[28] M. Seiﬁ, M. Dahar, R. Aman, O. Harrysson, J. Beuth, J.J. Lewandowski, JOM 67 (2015) 597-607.
[29] P. Kumar, O. Prakash, U. Ramamurty, Acta Mater. 154(2018) 246-260.
[30] H. Lu, W. Deng, K. Luo, Y. Chen, J. Wang, J. Lu, Addit. Manuf. 63(2023) 103416.
[31] G. Zhang, X. Lu, J. Li, J. Chen, X. Lin, M. Wang, H. Tan, W. Huang, Addit. Manuf. 55(2022) 102865.
[32] A. Xue, X. Lin, L. Wang, X. Lu, L. Yuan, H. Ding, W. Huang, Mater. Res. Lett. 11(2023) 60-68.
[33] R. Sabban, S. Bahl, K. Chatterjee, S. Suwas, Acta Mater. 162(2019) 239-254.
[34] Y.M. Ren, X. Lin, X. Fu, H. Tan, J. Chen, W.D. Huang, Acta Mater. 132(2017) 82-95.
[35] P. Kumar, U. Ramamurty, Acta Mater. 169(2019) 45-59.
[36] B.B. Mandelbrot, D.E. Passoja, P.J. Alvin, Nature 308 (1984) 721-722.
[37] V.Y. Milman, N.A. Stelmashenko, R. Blumenfeld, Prog. Mater. Sci. 38(1994) 425-474.
[38] Y. Su, W. Lei, Int. J. Fract. 106(2000) 41-46.
[39] E. Hornbogen, Int. Mater. Rev. 34(1989) 277-296.
[40] C.W. Lung, J. Jiang, E.K. Tian, C.H. Zhang, Phy. Rev. E 60 (1999) 5121-5125.
[41] R.E. Willford, Scr. Mater. 22(1988) 197-200.
[42] I.J. Wietecha-Reiman, A. Segall, X. Zhao, T.A. Palmer, Int. J Fatigue 166 (2023) 107232.
[43] H. Fu, W. Wang, X. Chen, G. Pia, J. Li, Appl. Surf. Sci. 470(2019) 870-881.
[44] K.K. Ray, G. Mandal, Acta Mater. 40(1992) 463-469.
[45] R.H. Dauskardt, F. Haubensakt, R.O. Ritchie, Acta Mater. 38(1990) 143-159.
[46] D. Dumont, A. Deschamps, Y. Brechet, Acta Mater. 52(2004) 2529-2540.
[47] Y.M. Ren, X. Lin, H.O. Yang, H. Tan, J. Chen, Z.Y. Jian, J.Q. Li, W.D. Huang, J Mater. Sci.Technol. 83(2021) 18-33.
[48] M. Gao, B.A. Sun, C.C. Yuan, J. Ma, W.H. Wang, Acta Mater. 60(2012) 6952-6960.
[49] B.A. Sun, W.H. Wang, App. Phys. Lett. 98(2011) 201902.
[50] C. Leyens, M. Peters, Weinheim, 2003.
[51] ASM International, Metals Handbook, vol. 19, 1996.
[52] B. Van Hooreweder, D. Moens, R. Boonen, J.P. Kruth, P. Sas, Adv. Eng. Mater. 14(2011) 92-97.
[53] F. Bridier, P. Villechaise, J. Mendez, Acta Mater. 53(2005) 555-567.
[54] S. Kobayashi, R. Kobayashi, T. Watanabe, Acta Mater. 102(2016) 397-405.
[55] A.W. Thompson, M.F. Ashby, Scr. Mater. 18(1984) 127-130.
[56] G.T. Hahn, Metall. Mater. Trans. A 15 (1984) 947-959.
[57] G.C. Garrett, J.F. Knott, Metall. Mater. Trans. A 4 (1978) 1187.
[58] G.T. Hahn, A.R.Rosenﬁeld, in: Sources of Fracture toughness: The relation Be- tween KIc and the Ordinary Tensile Properties of metals, Applications related Phenomena in Titanium alloys, ASTM STP 432, American Society for Testing and Materials, 1968, pp. 5-32.
[59] J.M. Kraft, Appl. Mater. Res. 3(1964) 88.
[60] B.Q. Li, A.P. Reynolds, J Mater. Sci. 33(1998) 5849-5853.
[61] A.K. Vasudqvan, R.D. Doherty, Acta Mater. 35(1987) 1193-1219.
[62] R.O. Ritchie, A.W. Thompson, Metall. Mater. Trans. A 16 (1985) 233-248.