Microstructure Evolution and Nanomechanical Behavior of Micro-Area in Molten Pool of Selective Laser Melting (CoCrNi)82Al9Ti9 High-Entropy Alloy

doi:10.1007/s40195-024-01684-2

Abstract

Abstract:

In this work, the phase evolution mechanism and nanomechanical properties of (CoCrNi)₈₂Al₉Ti₉ high-entropy alloy (HEA) prepared by selective laser melting (SLM) in the molten pool were studied. This HEA contains multiple primary elements and undergoes high-temperature gradient and rapid cooling during SLM. This leads to significant inhomogeneity of nano-scale microstructure characteristics and instability of properties. After optimizing process parameters, the microstructure evolution at the optimal parameter volume energy density of 440 J/mm³ was studied. A phase transition from BCC to FCC occurred in the melt micro-zone. Remelting the micro-area of the melt pool results in a temperature rise and the combustion-induced loss of Al elements. Moreover, the Ni element content increases significantly outside the melt pool. This process enhances the phase stability of FCC and facilitates phase transitions. Additionally, rapid cooling leads to the formation of distinctive ultrafine equiaxial crystals inside the melt pool, accompanied by the generation of intracrystalline needle-like nano-scale phases. Outside the melt pool, the accumulation of energy results in the formation of coarse dendrites. Therefore, the nano-hardness inside the molten pool is remarkably high at 11.79 GPa, while the outside the molten pool is reduced to 9.58 GPa. And the fracture toughness outside the melt pool also decreased. Comparing with inside the melt pool, the residual stress outside the melt pool changed from compressive to tensile stress and decreased from 603.28 to 322.84 MPa.

Key words: High-entropy alloys, Selective laser melting, Microstructure evolution, Nanoindentation

Hong-Wei Zhang, Li-Wei Lan, Zhe-Yu Yang, Chang-Chun Li, Wen-Xian Wang. Microstructure Evolution and Nanomechanical Behavior of Micro-Area in Molten Pool of Selective Laser Melting (CoCrNi)₈₂Al₉Ti₉ High-Entropy Alloy[J]. Acta Metallurgica Sinica (English Letters), 2024, 37(6): 1019-1033.

Figures/Tables 14

Fig. 1 (CoCrNi)82Al9Ti9 HEAs raw material powder: a SEM diagram; b local amplification; c particle size distribution; d XRD patterns

Table 1 Chemical compositions of (CoCrNi)82Al9Ti9 powder (at.%)

Element	Al	Co	Cr	Ni	Ti
Requested	9.00	27.33	27.33	27.33	9.00
Tested	9.04	27.27	27.37	27.37	8.95

Table 2 SLM processing parameters for preparing the samples

Layer thickness, t (μm)	Hatching space, h (μm)	Laser power, P (W)	Scanning speed, v (mm/s)	VED (J/mm³)
30	70	300	376	380
			357	400
			340	420
			325	440
			311	460
			298	480

Fig. 2 a Schematic diagram of the scanning strategy for SLM; b macroscopic morphology of different VEDs; c density and densification of different VEDs

Table 3 Valence electrons of elements in alloys

Element	Al	Co	Cr	Ni	Ti
Valence electrons	3	9	6	10	4

Fig. 3 a XRD patterns of SLM-ed sample at VED 440 J/mm3; b local magnification

Fig. 4 SEM images of SLM-ed (CoCrNi)82Al9Ti9 HEAs sample at VED 440 J/mm3: a, b X-Z plane of melt pool micro-area; c, d X-Y plane of melt pool micro-area

Fig. 5 Pole figure and Z-inverse pole figure corresponding to different phases of the SLM sample

Fig. 6 Melt pool in the X-Z plane of the SLM-ed (CoCrNi)82Al9Ti9 HEA: a IPF; b average grain size; c phase diagram; d grain boundary orientation map; e KAM distribution; f crystal type

Fig. 7 a Schematic diagram of the location of the selected point; b load displacement curve of molten pool line under different loads; c load displacement curves of melt pool micro-area at different positions under 60-mN load; d nano-hardness and modulus of different positions

Fig. 8 a SLM diagram of nano-scale intragranular needle-like microstructure inside the molten pool; b relationship between temperature and equilibrium vapor pressure for five elements. Inset shows the histogram of the elemental content of the EDS point sweep at different locations; c SLM diagram of intragranular dendrites of equiaxed crystal microstructure outside the molten pool

Table 4 Recommended coefficients for elemental vapor pressure [48]

Element	A	B	C	D	Temperature range (K)	RMSE
Al	12,210	− 27.06	10.09	1.16	1200-3370	0.062
Ti	26,910	28.53	− 6.305	0.413	1600-4190	0.080
Cr	21,790	15.86	− 2.420	− 0.024	1400-3525	0.010
Co	25,540	35.6	− 8.461	0.652	1500-3750	0.043
Ni	− 4552	− 165.9	51.135	− 4.476	1500-3525	0.055

Fig. 9 a Schematic of the energy method; b fracture toughness of nano-mechanics properties at different locations of molten pool

Fig. 10 a Schematic of the indentation method; b residual stress of nano-mechanics properties at different locations of molten pool

References 59

[1]	J.W. Yeh, S.K. Chen, S.J. Lin, J.Y. Gan, T.S. Chin, T.T. Shun, C.H. Tsau, S.Y. Chang, Adv. Eng. Mater. 6, 299 (2004)
[2]	K. Han, J. Lu, V. Toplosky, R. Niu, R. Goddard, Y. Xin, R. Walsh, I. Dixon, V. Pantsyrny, IEEE Trans. Appl. Supercond. 30, 1 (2020)
[3]	K. Han, V. Toplosky, N. Min, Y. Xin, R. Walsh, J. Lu, IEEE Trans. Appl. Supercond. 29, 1 (2019)
[4]	D.B. Miracle, O.N. Senkov, Acta Mater. 122, 448 (2017)
[5]	Y.L. Wang, K.C. Chan, Mater. Sci. Eng. A 876, 145164 (2023)
[6]	Y. Cunhong, H. Hua, Q. Jiaqing, Z. Baochao, A. Xulong, Y. Yanliang, J. Mater. Res. Technol. 25, 1761 (2023)
[7]	P. Fu, H. Su, Z. Li, P. Dai, Q. Tang, J. Alloys Compd. 921, 166141 (2022)
[8]	O.N. Senkov, J.D. Miller, D.B. Miracle, C. Woodward, Nat. Commun. 6, 6529 (2015) DOI PMID
[9]	R.K. Mishra, Adv. Mater. Process. Technol. 38, 1 (2023)
[10]	K. Han, V. Toplosky, N. Min, J. Lu, Y. Xin, R. Walsh, IEEE Trans. Appl. Supercond. 28, 1 (2018)
[11]	K.R. Lim, K.S. Lee, J.S. Lee, J.Y. Kim, H.J. Chang, Y.S. Na, J. Alloy. Compd. 728, 1235 (2017)
[12]	K. Yashiro, M. Naito, Y. Tomita, Int. J. Mech. Sci. 44, 1845 (2002)
[13]	C. Sha, Z. Zhou, Z. Xie, P. Munroe, Surf. Coat. Technol. 440, 128479 (2022)
[14]	X. Huang, L. Huang, H. Peng, Y. Liu, B. Liu, S. Li, Scr. Mater. 200, 113898 (2021)
[15]	J. Joseph, N. Stanford, P. Hodgson, D.M. Fabijanic, J. Alloys Compd. 726, 885 (2017)
[16]	M. Löbel, T. Lindner, T. Mehner, T. Lampke, Entropy 20, 505 (2018)
[17]	W. Xiong, A.X.Y. Guo, S. Zhan, C.T. Liu, S.C. Cao, J. Mater. Sci. Technol. 142, 196 (2023)
[18]	S.A. Adekanye, R.M. Mahamood, E.T. Akinlabi, M.G. Owolabi, Mater. Technol. 51, 709 (2017)
[19]	E.M. Sefene, J. Manuf. Syst. 63, 250 (2022)
[20]	L.L. Zubia, C. Garay-Reyes, M. Rascón-Sánchez, I. Estrada, J. Flores-De-los-Ríos, R. Martínez-Sánchez, A. Caro-Duran, M. Maldonado-Orozco, P. Guerrero-Seáñez, M. Ruiz-Esparza-Rodriguez, Microsc. Microanal. 26, 2938 (2020)
[21]	D. Beckers, N. Ellendt, U. Fritsching, V. Uhlenwinkel, Adv. Powder Technol. 31, 300 (2020)
[22]	S. Liu, D. Wan, S. Guan, Y. Fu, X. Ren, Z. Zhang, J. He, Mater. Sci. Eng. A 823, 141737 (2021)
[23]	F. Yin, X. Zhang, F. Chen, S. Hu, K. Ming, J. Zhao, L. Xie, Y. Liu, L. Hua, J. Wang, Mater. Des. 227, 111771 (2023)
[24]	J.H. Zhu, P.K. Liaw, C.T. Liu, Mater. Sci. Eng. A 239-240, 260 (1997)
[25]	C.T. Liu, Int. Met. Rev. 29, 168 (1984)
[26]	S. Guo, C. Ng, J. Lu, C.T. Liu, J. Appl. Phys. 109, 103505 (2011)
[27]	S. Guo, C.T. Liu, Prog. Nat. Sci. Mater. Int. 21, 433 (2011)
[28]	Y. Zhang, Y.J. Zhou, Mater. Sci. Forum 561-565, 1337 (2007)
[29]	X. Yang, Y. Zhang, Mater. Chem. Phys. 132, 233 (2012)
[30]	K. Han, A.C. Lawson, J.T. Wood, J.D. Embury, R.B. Von Dreele, J.W. Richardson, Philos. Mag. 84, 2579 (2004)
[31]	K. Han, K. Yu-Zhang, H. Kung, J.D. Embury, B.J. Daniels, B.M. Clemens, Philos. Mag. A 82, 1633 (2002)
[32]	C.W. Sinclair, G. Saada, J.D. Embury, Philos. Mag. 86, 4081 (2006)
[33]	Y. Yu, P. Shi, K. Feng, J. Liu, J. Cheng, Z. Qiao, J. Yang, J. Li, W. Liu, Acta Metall. Sin. (Engl. Lett.) 33, 1077 (2020)
[34]	T. Yang, S. Xia, S. Liu, C. Wang, S. Liu, Y. Zhang, J. Xue, S. Yan, Y. Wang, Mater. Sci. Eng. A 648, 15 (2015)
[35]	Y. Huang, Z. Xie, W. Li, H. Chen, B. Liu, B. Wang, J. Alloys Compd. 927, 167011 (2022)
[36]	K. Wei, Z. Wang, F. Li, H. Zhang, X. Zeng, J. Alloys Compd. 774, 1024 (2019)
[37]	Y. Ren, H. Wu, B. Liu, Y. Liu, S. Guo, Z.B. Jiao, I. Baker, J. Mater. Sci. Technol. 131, 221 (2022)
[38]	L. Han, L.P.H. Jeurgens, C. Cancellieri, J. Wang, Y. Xu, Y. Huang, Y. Liu, Z. Wang, Acta Mater. 200, 857 (2020)
[39]	L. Lan, W. Wang, Z. Cui, X. Hao, D. Qiu, J. Mater. Sci. Technol. 129, 228 (2022)
[40]	M. Moradi, A. Hasani, Z. Pourmand, J. Lawrence, Opt. Laser Technol. 144, 107380 (2021)
[41]	V. Mazánová, M. Heczko, J. Polák, Int. J. Fatigue 158, 106721 (2022)
[42]	W. Le, Z. Chen, S. Naseem, K. Yan, Y. Zhao, H. Zhang, Q. Lv, Vacuum 209, 111799 (2023)
[43]	X. Wen, C. Wang, Y. Gong, W. Liu, Chin. J. Mech. Eng. Addit. Manuf. Front. 2, 100069 (2023)
[44]	W. Zhao, R. Liu, J. Yan, X. Wang, H. Zhang, W. Wang, J. Mater. Res. Technol. 21, 2156 (2022)
[45]	X. Zhou, Y. Chen, Y. Jiang, Y. Li, Mater. Res. Express 6, 1265i7 (2020)
[46]	Y. Yin, J. Zhang, Y. Ma, J. Huo, K. Zhao, X. Meng, Q. Han, J. Yin, IEEE Access 8, 62714 (2020)
[47]	P. Agrawal, S. Thapliyal, P. Agrawal, A. Dhal, R.S. Haridas, S. Gupta, R.S. Mishra, Mater. Sci. Eng. A 872, 144938 (2023)
[48]	B. Mondal, T. Mukherjee, N.W. Finch, A. Saha, M.Z. Gao, T.A. Palmer, T. DebRoy, Materials 16, 50 (2023)
[49]	L. Lan, W. Wang, Z. Cui, X. Hao, Acta Metall. Sin. (Engl. Lett.) 36, 1465 (2023)
[50]	Y. Wang, R. Li, P. Niu, Z. Zhang, T. Yuan, J. Yuan, K. Li, Intermetallics 120, 106746 (2020)
[51]	X. Sun, H. Zhang, S. Lu, X. Ding, Y. Wang, L. Vitos, Acta Mater. 140, 366 (2017)
[52]	Y. Chen, X. Zhang, C.J. Williams, G. Brewster, P. Xiao, Materialia 20, 101267 (2021)
[53]	Y. Sun, G. Dou, K. Wu, P. Chen, T. Zhang, G. Peng, Int. J. Mech. Sci. 244, 108053 (2023)
[54]	W.C. Oliver, G.M. Pharr, J. Mater. Res. 7, 1564 (1992)
[55]	T. Zhang, Y. Feng, R. Yang, P. Jiang, Scr. Mater. 62, 199 (2010)
[56]	Y.T. Cheng, C.M. Cheng, Appl. Phys. Lett. 73, 614 (1998)
[57]	M. Kulka, N. Makuch, A. Piasecki, Surf. Coat. Technol. 325, 515 (2017)
[58]	Z.H. Xu, X. Li, Philos. Mag. 86, 2835 (2006)
[59]	A. Gouldstone, N. Chollacoop, M. Dao, J. Li, A.M. Minor, Y.L. Shen, Acta Mater. 55, 4015 (2007)

Microstructure Evolution and Nanomechanical Behavior of Micro-Area in Molten Pool of Selective Laser Melting (CoCrNi)₈₂Al₉Ti₉ High-Entropy Alloy

RichHTML

PDF (PC)

Knowledge

Abstract

Cite this article

share this article

Figures/Tables 14

References 59

Related Articles 15

Recommended Articles

Metrics

Comments

[1]	Lei Chen, Gang Qin, Yao Chen, Qi Wang, Liang Wang, Yanqing Su, Ruirun Chen. Machine learning-assisted design of lightweight refractory high-entropy alloys: A comprehensive review [J]. Metals Advances, 2026, 40(2): 26-47.
[2]	Hao Cheng, Cheng-Lei Wang, Xiao-Du Li, Li Pan, Chao-Jie Liang, Wei-Jie Liu. Machine Learning-Based High Entropy Alloys-Algorithms and Workflow: A Review [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(9): 1453-1480.
[3]	Yuanyuan Feng, Jianchao Pang, Xiaoyuan Teng, Chenglu Zou, Jingjing Liang, Yuping Zhu, Shouxin Li, Jinguo Li, Zhefeng Zhang. Quasi-in-situ EBSD Study on the Microstructure and Tensile Properties of Selective Laser Melted Inconel 718 Alloy Processed by Different Heat Treatments [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(9): 1499-1512.
[4]	B. M. Shi, Y. T. Pang, B. H. Shan, B. B. Wang, Y. Liu, P. Xue, J. F. Zhang, Y. N. Zan, Q. Z. Wang, B. L. Xiao, Z. Y. Ma. Microstructure Evolution and Fracture Behavior of (B₄C+Al₂O₃)/Al Friction Stir Welded Joints [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(9): 1513-1526.
[5]	Meisa Zhou, Kun-Ming Pan, Xiao-Ye Zhou, Shulong Ye, Shaojie Du, Hong-Hui Wu. Surface Wear Behavior of Nanograined NbMoTaW Refractory High-Entropy Alloys via Nano-scratching Simulations [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(6): 946-960.
[6]	X. W. Shang, Z. G. Lu, R. P. Guo, L. Xu. Influence of Hot Isostatic Pressing Temperature on Microstructure and Mechanical Properties of Ti-6.5Al-3.5Mo-1.5Zr-0.3Si Alloy [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(4): 627-641.
[7]	Jingxiang Xu, Yuyan Yang, Ruiyang Huang, Xinwei Yuan, Huakang Bian, Zhenhua Chu, Yang Wang, Yanhua Lei. Enhancing the Corrosion Resistance of FeNiCoCrW_0.2Al_0.1 High-Entropy Alloy in 3.5 wt% NaCl Solution by Bilayer Passivation [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(3): 407-418.
[8]	Ji-Peng Yang, Hai-Feng Zhang, Hong-Chao Ji, Nan Jia. Molecular Dynamics Simulations of Micromechanical Behaviours for AlCoCrFeNi_2.1 High Entropy Alloy during Nanoindentation [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(2): 218-232.
[9]	Liang Liang, Huifang Pang, Renguo Guan, Wenbo Du, Minqiang Gao, Jin Zhang, Huan Ma. Electromagnetic Wave Absorption Performance of FeCoCrAl_0.4V_x High-Entropy Alloys by Adjusting the Amount of V Content [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(12): 2217-2227.
[10]	Qi-Mei Tian, Fu Xiao, Ya Yang, Yuan-Biao Tan, Song Xiang, Xuan-Ming Ji, Fei Zhao, Hui Yang. Achieving an Extraordinary Strength-Ductility Synchronization in TA15 Titanium Alloy via Tailoring a Tri-modal Microstructure [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(12): 2228-2242.
[11]	Ang Yin, Wenbo Li, Chengxi Wang, Vincent Ji, Chuanhai Jiang. Microstructure Evolution and Residual Stress Redistribution in Selective Laser Melted TA15 Titanium Alloy Under Severe Shot Peening Treatment [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(11): 1953-1964.
[12]	Rashad A. Al-Hammadi, Rui Zhang, Chuanyong Cui, Xipeng Tao, Yizhou Zhou. Deformation Mechanism and Fracture Behavior of a Coarse-Grain Ni-Co-Based Superalloy During Superplasticity [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(11): 2024-2034.
[13]	Yao-Zong Mao, Ya-Hui Zhang, De-Chun Ren, Diao-Feng Li, Hai-Bin Ji, Hai-Chang Jiang, Chun-Guang Bai. Effect of Process Parameters on the Microstructure and Properties of Ti15Zr5Cu Alloy Fabricated via Selective Laser Melting [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(10): 1699-1710.
[14]	Lihua Zhu, Bing Wei, Kaiqi Wang, Changjie Zhou, Hongjun Ji. Optimizing Selective Laser Melting of a High-Alloyed Ni-Based Superalloy: Achieving Crack-Free Fabrication with Enhanced Microstructure and Mechanical Properties [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(10): 1719-1734.
[15]	Jian Zang, Jianrong Liu, Qingjiang Wang, Haibing Tan, Bohua Zhang, Xiaolin Dong, Zibo Zhao. Microstructure and Texture Evolution of Ti65 Alloy during Thermomechanical Processing [J]. Acta Metallurgica Sinica (English Letters), 2025, 38(1): 107-120.