Unique Duplex Microstructure and Porosity Effect on Mechanical Properties of AlCoCrFeNi2.1 Eutectic High-Entropy Alloys Processed by Selective Laser Melting

doi:10.1007/s40195-023-01551-6

Abstract

Abstract:

Selective laser melting (SLM) was performed on AlCoCrFeNi_2.1 eutectic high-entropy alloys (EHEAs), and the unique duplex microstructure and porosity were investigated as well as the negative effect on mechanical properties. SLM printed AlCoCrFeNi_2.1 EHEAs is composed of face-centered cubic and BCC/B2 phases, and the surface texture of samples perpendicular to and parallel to the building direction is different. From the bottom of the molten pool to the inside, the structure changes from dendrites to columnar crystals and then to cellular crystals, the distribution of elements in and around the molten pool is uniform, and there is no element segregation. The surface hardness of as-printed AlCoCrFeNi_2.1 EHEAs is higher than that of as-cast ones due to the grain refinement strengthening, and there is anisotropy in different surface hardness, the highest hardness is 580 HV (X-Y plane) and 560 HV (X-Z plane). The reduction of bearing area and tip stress concentration caused by pores have adverse effects on the tensile strength and elongation of the alloy, the ultimate tensile strength increased from 1060 to 1289 MPa.

Key words: Selective laser melting, Eutectic high-entropy alloys, Metallurgical porosity, Microstructure evolution, Grains and interfaces

Liwei Lan, Wenxian Wang, Zeqin Cui, Xiaohu Hao. Unique Duplex Microstructure and Porosity Effect on Mechanical Properties of AlCoCrFeNi_2.1 Eutectic High-Entropy Alloys Processed by Selective Laser Melting[J]. Acta Metallurgica Sinica (English Letters), 2023, 36(9): 1465-1481.

Figures/Tables 16

Fig. 1 a Scanning strategy of the SLM process; b SLM printed AlCoCrFeNi2.1 EHEAs bulk morphology; c specimen size for tensile test at room temperature

Table 1 SLM processing parameters for preparing the samples and the corresponding VEDs

VED	31.7	35.3	36.6	38	39.7	43	47.6	53	55	68	79.4	95	102	109.9	119	142
P	100	100	100	100	100	100	150	100	150	100	150	100	150	150	150	150
v	1500	1350	1300	1250	1200	1100	1500	900	1300	700	900	500	700	650	600	500
t								30
h								0.07

Fig. 2 Micromorphology a, particle size distribution b, internal defects c, microstructure d of AlCoCrFeNi2.1 raw powder

Fig. 3 a Density as a function of volumetric energy density (VED); b three stages corresponding to the influence of SLM parameters on molding quality

Fig. 4 Micropore aggregation morphology and average volume of different VED samples detected by XCT: a VED 36.6; b VED 68; c VED 95; d VED 109.9; e VED 119; f average defect volume of different VED formed specimens. Red and blue points represent pores with sizes larger and less than 100 μm

Fig. 5 Macromorphologies of a1, b1, c1, d1, e1, X-Y plane, a2, b2, c2, d2, e2 X-Z plane, f roughness statistics of different VED samples

Fig. 6 3D morphological features of the a X-Y plane, b X-Z plane of SLM-printed samples

Fig. 7 a Variation of relative density and porosity at different VED; b fitting functions of X-Y and X-Z plane roughness and porosity

Fig. 8 XRD patterns of SLM-processed AlCoCrFeNi2.1 HEAs samples taken from the plane perpendicular a, a1, parallel b, b1 to the build direction; c the strongest diffraction peak for different surfaces; d phase content statistics of different sections of different VED specimens

Fig. 9 PF corresponding to different plane and phase of SLM samples VED 109.9

Fig. 10 Orientation difference angle distribution map of X-Y plane a, X-Z plane d of VED 109.9 J/mm3 sample; the histogram of grain boundary orientation difference angle distribution in X-Y plane b, X-Z plane e; KAM maps computed from the raw EBSD data of X-Y plane c, X-Z plane f

Fig. 11 a TEM Characterization of X-Z section of VED109.9 specimen; b-d bight-field TEM images of different structures with corresponding SAED patterns; e SEM image of B2 phase particles; f macroscopic morphology of molten pool and element energy spectrum analysis

Fig. 12 a Microhardness values of different surfaces of the tested samples; b the stress-strain curves of tensile tests and tensile strengths and elongation c; d porosity as a function of tensile strength and elongation; nano-indentation morphology of molten pool e and nano-hardness distribution cloud map f

Fig. 13 a-c Macroscopic fracture morphologies corresponding to three stages of AM printed alloys. d-f Fracture micromorphology and local magnification of VED109.9 sample

Fig. 14 Interaction of laser and powder, and two cases of spheroidization: a large size spheroidization; b flat spread micro-bumps

Table 2 Thermophysical parameters of AlCoCrFeNi2.1 EHEAs

	\({\eta }_{\mathrm{l}}\)(MPa·s)	\({\rho }_{\mathrm{l}} (\)g/cm³)	\({\rho }_{\mathrm{g}} (\)g/cm³)	\(g\)(m/s²)
Parameter	2.96-3.38	6.06-6.14	1.257 × 10^-3	10

References 60

[1]	E.P. George, D. Raabe, R.O. Ritchie, Nat. Rev. Mater. 4, 515 (2019) DOI
[2]	M.C. Gao, J. Qiao, Metals 8, 108 (2018)
[3]	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) DOI URL
[4]	J.Y. He, H. Wang, H.L. Huang, X.D. Xu, M.W. Chen, Y. Wu, X.J. Liu, T.G. Nieh, K. An, Z.P. Lu, Acta. Mater. 102, 187 (2016) DOI URL
[5]	Z. Lei, X. Liu, Y. Wu, H. Wang, S. Jiang, S. Wang, X. Hui, Y. Wu, B. Gault, P. Kontis, D. Raabe, L. Gu, Q. Zhang, H. Chen, H. Wang, J. Liu, K. An, Q. Zeng, T.G. Nieh, Z. Lu, Nature 563, 546 (2018)
[6]	J.G. Gigax, O. El-Atwani, Q. McCulloch, B. Aytuna, M. Efe, S. Fensin, S.A. Maloy, N. Li, Scr. Mater. 178, 508 (2020) DOI URL
[7]	M. Wang, Y. Lu, G. Zhang, H. Cui, D. Xu, N. Wei, T. Li, Vacuum 184, 109905 (2021)
[8]	Y. Lu, Y. Dong, S. Guo, L. Jiang, H. Kang, T. Wang, B. Wen, Z. Wang, J. Jie, Z. Cao, H. Ruan, T. Li, Sci. Rep.-UK 4, 6200 (2014)
[9]	P. Shi, W. Ren, T. Zheng, Z. Ren, X. Hou, J. Peng, P. Hu, Y. Gao, Y. Zhong, P.K. Liaw, Nat. Commun. 10, 489 (2019) DOI
[10]	J. Miao, H. Liang, A. Zhang, J. He, J. Meng, Y. Lu, Tribol. Int. 153, 106599 (2021) DOI URL
[11]	M. Wang, Y. Lu, T. Wang, C. Zhang, Z. Cao, T. Li, P.K. Liaw, Scr. Mater. 204, 114132 (2021) DOI URL
[12]	Y. Lu, Y. Dong, H. Jiang, Z. Wang, Z. Cao, S. Guo, T. Wang, T. Li, P.K. Liaw, Scr. Mater. 187, 202 (2020) DOI URL
[13]	J. Hou, M. Zhang, S. Ma, K. Peter, Y. Liaw, J.Q. Zhang, Mater. Sci. Eng. A 707, 593 (2017)
[14]	J.X. Hou, J. Fan, H.J. Yang, Z. Wang, J.W. Qiao, Int. J. Min. Met. Mater. 27, 1363 (2020) DOI
[15]	D. Karlsson, A. Marshal, F. Johansson, M. Schuisky, M. Sahlberg, J.M. Schneider, U. Jansson, J. Alloys Compd. 784, 195 (2019) DOI URL
[16]	R. Li, Y. Shi, J. Liu, H. Yao, W. Zhang, Powder Metall. Met. Ceram. 48, 186 (2009) DOI URL
[17]	D. Sun, D. Gu, K. Lin, J. Ma, W. Chen, J. Huang, X. Sun, M. Chu, Powder. Technol. 342, 371 (2019) DOI URL
[18]	Y. Wang, R. Li, P. Niu, Z. Zhang, T. Yuan, J. Yuan, K. Li, Intermetallics 120, 106746 (2020)
[19]	S. Luo, H. Wang, Z. Gao, Y. Wu, H. Wang, Mater. Des. 212, 110264 (2021) DOI URL
[20]	K.H. Leitz, P. Singer, A. Plankensteiner, B. Tabernig, H. Kestler, L.S. Sigl, Met. Powder Rep. 72, 331 (2017) DOI URL
[21]	S. Qu, J. Ding, J. Fu, M. Fu, B. Zhang, X. Song, Addit. Manuf. 48, 102417 (2021)
[22]	J. Yin, H. Zhu, L. Ke, W. Lei, C. Dai, D. Zuo, Comp. Mater. Sci. 53, 333 (2012) DOI URL
[23]	F. Li, Z. Wang, X. Zeng, Mater. Lett. 199, 79 (2017) DOI URL
[24]	C. Xue, Y. Zhang, P. Mao, C. Liu, Y. Guo, F. Qian, C. Zhang, K. Liu, M. Zhang, S. Tang, J. Wang, Addit. Manuf. 43, 102019 (2021)
[25]	B.J. Sun, Shanghai Jiaotong Univ. 31, 40 (1997)
[26]	Y. Wang, R. Li, T. Yuan, L. Zou, M. Wang, H. Yang, Mater. Charact. 180, 111397 (2021) DOI URL
[27]	P. Chen, S. Li, Y. Zhou, M. Yan, M.M. Attallah, J. Mater. Sci. Technol. 43, 40 (2020) DOI
[28]	P.F. Jiang, C.H. Zhang, S. Zhang, J.B. Zhang, J. Chen, H.T. Chen, Opt. Laser. Technol. 140, 107055 (2021) DOI URL
[29]	J. Suryawanshi, K.G. Prashanth, S. Scudino, J. Eckert, O. Prakash, U. Ramamurty, Aata. Mater. 115, 285 (2016)
[30]	X. Cui, S. Zhang, C. Wang, C.H. Zhang, J. Chen, J.B. Zhang, Mater. Sci. Eng. A 791, 139738 (2020)
[31]	S.C.V. Lim, K.V. Yang, Y. Yang, Y. Cheng, A. Huang, X. Wu, C.H.J. Davies, Mater. Sci. Eng. A 651, 524 (2016)
[32]	W. Li, J. Liu, Y. Zhou, S. Li, S. Wen, Q. Wei, C. Yan, Y. Shi, J. Alloys Compd. 688, 626 (2016) DOI URL
[33]	P.F. Jiang, C.H. Zhang, S. Zhang, J.B. Zhang, J. Chen, Y. Liu, J. Mater. Res. Technol. 9, 11702 (2020) DOI URL
[34]	R.E. Napolitano, R.J. Schaefer, J. Mater. Sci. 35, 1641 (2000) DOI URL
[35]	J. Hou, M. Zhang, H. Yang, J. Qiao, Metals 7, 111 (2017)
[36]	J. Zhang, S. Li, Q. Wei, Y. Shi, L. Wang, J. Guo, Rare Metal. 39, 961 (2015)
[37]	K.V. Yang, Y. Shi, F. Palm, X. Wu, P. Rometsch, Scr. Mater. 145, 113 (2018) DOI URL
[38]	H. Hu. (2007) The Principle of Metal Solidification. Machinery Industry Press
[39]	W. Shifeng, L. Shuai, W. Qingsong, C. Yan, Z. Sheng, S. Yusheng, J. Mater. Process. Technol. 214, 2660 (2014) DOI URL
[40]	S.M. Thompson, L. Bian, N. Shamsaei, A. Yadollahi, Addit. Manuf. 8, 36 (2015)
[41]	H.S. Roh, Int. J. Heat. Mass. Tran. 68, 391 (2014) DOI URL
[42]	X.K. Lan, J.M. Khodadadi, Int. J. Heat. Mass. Tran. 44, 953 (2001) DOI URL
[43]	R.J. Vikram, B.S. Murty, D. Fabijanic, S. Suwas, J. Alloys Compd. 827, 154034 (2020) DOI URL
[44]	Y. Zhang, E. Lordan, K. Dou, S. Wang, Z. Fan, J. Manuf. Process. 56, 500 (2020) DOI URL
[45]	J. Lee, J. Choe, J. Park, J.H. Yu, S. Kim, I.D. Jung, H. Sung, Mater. Charact. 155, 109817 (2019) DOI URL
[46]	D. Gu, Y. Shen, Mater. Des. 30, 2903 (2009) DOI URL
[47]	Y. Chen, H. Yue, X. Wang, Mater. Sci. Eng. A 713, 195 (2018)
[48]	S. Huang, L. Zhang, D. Li, W. Zhang, W. Zhu, Surf. Coat. Technol. 381, 125123 (2020) DOI URL
[49]	X. Zhou, X. Liu, D. Zhang, Z. Shen, W. Liu, J. Mater. Process. Technol. 222, 33 (2015) DOI URL
[50]	S. Schiaffino, A.A. Sonin, Phys. Fluids 9, 2217 (1997)
[51]	C. Teng, D. Pal, H. Gong, K. Zeng, K. Briggs, N. Patil, B. Stucker, Addit. Manuf. 14, 137 (2017)
[52]	M. Xia, D. Gu, G. Yu, D. Dai, H. Chen, Q. Shi, Int. J. Mach. Tools Manuf. 116, 96 (2017) DOI URL
[53]	R. D. Blevins, Applied Fluid Dynamics Handbook, (New York, 1984).
[54]	C. Panwisawas, C.L. Qiu, Y. Sovani, J.W. Brooks, M.M. Attallah, H.C. Basoalto, Scr. Mater. 105, 14 (2015) DOI URL
[55]	N.T. Aboulkhair, N.M. Everitt, I. Ashcroft, C. Tuck, Addit. Manuf. 1-4, 77 (2014)
[56]	L.E. Scriven, C.V. Sternling, Nature 187, 186 (1960)
[57]	R. Hidalgo, J.A. Esnaola, I. Llavori, M. Larrañaga, I. Hurtado, N. Herrero-Dorca, Int. J. Fatigue 125, 468 (2019)
[58]	J. Hou, X. Shi, J. Qiao, Y. Zhang, P.K. Liaw, Y. Wu, Mater. Des. 180, 107910 (2019) DOI URL
[59]	S. Önder, N. Saklakoğlu, A. Sever, Mater. Charact. 196, 112571 (2023) DOI URL
[60]	P.J. Withers, H.K.D.H. Bhadeshia, Mater. Sci. Technol.-Lond. 17, 366 (2001) DOI URL