[2] Yang H Q, Wang Z Y, Xiao C B et al. Microstructure and mechanical properties of alloy GH22 as insulate plates against heat in industrial gas turbine[J]. Journal of Materials Engineering, 38, 15-19(2010).

[3] Ma M M, Wang Z M, Wang D Z et al. Control of shape and performance for direct laser fabrication of precision large-scale metal parts with 316L stainless steel[J]. Optics & Laser Technology, 45, 209-216(2013).

[4] Tomus D, Jarvis T, Wu X et al. Controlling the microstructure of hastelloy-X components manufactured by selective laser melting[J]. Physics Procedia, 41, 823-827(2013).

[5] Tomus D, Rometsch P A, Heilmaier M et al. Effect of minor alloying elements on crack-formation characteristics of Hastelloy-X manufactured by selective laser melting[J]. Additive Manufacturing, 16, 65-72(2017).

[6] Harrison N J, Todd I, Mumtaz K. Reduction of micro-cracking in nickel superalloys processed by selective laser melting: a fundamental alloy design approach[J]. Acta Materialia, 94, 59-68(2015).

[7] Li Y, Xu H J, Li K et al. Effect of volumetric energy density on microstructure and properties of Hastelloy X alloy manufactured by selective laser melting[J]. Materials for Mechanical Engineering, 44, 38-43(2020).

[8] Xu H J, Li Y, Qi H et al. Effect of hot isostatic pressing process on stress-rupture property of Hastelloy X alloy by selective laser melting[J]. Materials for Mechanical Engineering, 42, 53-57,63(2018).

[9] Xue J Q, Chen X H, Lei L M. Effects of microstructure on mechanical properties of GH3536 alloy fabricated by selective laser melting[J]. Laser & Optoelectronics Progress, 56, 141401(2019).

[10] Hou H P, Liang Y C, He Y L et al. Microstructural evolution and tensile property of Hastelloy-X alloys produced by selective laser melting[J]. Chinese Journal of Lasers, 44, 0202007(2017).

[11] Zheng Y L, He Y L, Chen X H et al. Elevated-temperature tensile properties and fracture behavior of GH3536 alloy formed via selective laser melting[J]. Chinese Journal of Lasers, 47, 0802008(2020).

[12] Zhang Y Z, Hou H P, Peng S et al. Anisotropy of microstructure and mechanical properties of Hastelloy X alloy produced by selective laser melting[J]. Journal of Aeronautical Materials, 38, 50-56(2018).

[13] Chen X J, Zhao G R, Dong D D et al. Microstructure and mechanical properties of Inconel625 superalloy fabricated by selective laser melting[J]. Chinese Journal of Lasers, 46, 1202002(2019).

[14] Pan A Q, Zhang H, Wang Z M. Process parameters and microstructure of Ni-based single crystal superalloy processed by selective laser melting[J]. Chinese Journal of Lasers, 46, 1102007(2019).

[15] Qiu C L, Chen H X, Liu Q et al. On the solidification behaviour and cracking origin of a nickel-based superalloy during selective laser melting[J]. Materials Characterization, 148, 330-344(2019).

[16] Zhang X Q, Chen H B, Xu L M et al. Cracking mechanism and susceptibility of laser melting deposited Inconel 738 superalloy[J]. Materials & Design, 183, 108105(2019).

[17] Saeidi K, Gao X, Zhong Y et al. Hardened austenite steel with columnar sub-grain structure formed by laser melting[J]. Materials Science and Engineering A, 625, 221-229(2015).

[18] Wang Z M, Guan K, Gao M et al. The microstructure and mechanical properties of deposited-IN718 by selective laser melting[J]. Journal of Alloys and Compounds, 513, 518-523(2012).

[19] Zong X W, Liu W J, Zhang S Z et al. Microstructure and crystal orientation of nickel-based superalloy GH3536 by selective laser melting[J]. Rare Metal Materials and Engineering, 49, 3182-3188(2020).

[20] Sakthivel T, Laha K, Nandagopal M et al. Effect of temperature and strain rate on serrated flow behaviour of Hastelloy X[J]. Materials Science and Engineering: A, 534, 580-587(2012).

[21] Zhao J C, Larsen M, Ravikumar V. Phase precipitation and time-temperature-transformation diagram of Hastelloy X[J]. Materials Science and Engineering A, 293, 112-119(2000).

[22] Ghasemi A, Kolagar A M, Pouranvari M. Microstructure-performance relationships in gas tungsten arc welded Hastelloy X nickel-based superalloy[J]. Materials Science and Engineering A, 793, 139861(2020).

[23] Pourbabak S, Montero-Sistiaga M L, Schryvers D et al. Microscopic investigation of as built and hot isostatic pressed Hastelloy X processed by selective laser melting[J]. Materials Characterization, 153, 366-371(2019).

[24] Qin L Y, Wu J B, Wang W et al. Microstructures and fatigue properties of Ti-6Al-2Mo-2Sn-2Zr-2Cr-2V titanium alloy fabricated using laser deposition manufacturing[J]. Chinese Journal of Lasers, 47, 1002008(2020).

[25] Hu D Y, Mao J X, Song J et al. Experimental investigation of grain size effect on fatigue crack growth rate in turbine disc superalloy GH4169 under different temperatures[J]. Materials Science and Engineering A, 669, 318-331(2016).

[26] Jiang R, Everitt S, Lewandowski M et al. Grain size effects in a Ni-based turbine disc alloy in the time and cycle dependent crack growth regimes[J]. International Journal of Fatigue, 62, 217-227(2014).