[1]	C. Luke Nelson, Selective laser melting of nickel superalloys for high temperature applications, Thesis for Doctor of Philosophy Degree, University of Birmingham, 2013.
[2]	Y.L. Hu, Y.L. Li, S.Y. Zhang, X. Lin, Z.H. Wang, W.D. Huang, Effect of solution temperature on static recrystallization and ductility of Inconel 625 superalloy fabricated by directed energy deposition, Materials Science and Engineering: A. 772 (2020) 138711. https://doi.org/10.1016/j.msea.2019.138711.
[3]	N.J. Harrison, Selective laser melting of nickel superalloys: solidification, microstructure and material response, Thesis for Doctor of Philosophy Degree, University of Sheffield, 2016. http://etheses.whiterose.ac.uk/17033/ (accessed April 22, 2020).
[4]	I. Gurrappa, I.V.S. Yashwanth, I. Mounika, H. Murakami, S. Kuroda, The importance of hot corrosion and its effective prevention for enhanced efficiency of gas turbines, (2014).
[5]	E. Akca, A. Gürsel, A review on superalloys and IN718 nickel-based Inconel superalloy, Periodicals of Engineering and Natural Sciences. 3 (2015) 15–27.
[6]	M. Ashabul Anam, Microstructure and mechanical properties of selective laser melted superalloy Inconel 625, Thesis for Doctor of Philosophy in Industrial Engineering, University of Louisville, 2018.
[7]	M.D. Sangid, T.A. Book, D. Naragani, J. Rotella, P. Ravi, P. Kenesei, J.-S. Park, H. Sharma, J. Almer, X. Xiao, Role of heat treatment and build orientation in the microstructure sensitive deformation characteristics of IN718 produced via SLM additive manufacturing, Additive Manufacturing. 22 (2018) 479–496.
[8]	D.F. Paulonis, J.J. Schirra, Alloy 718 at Pratt & Whitney-Historical perspective and future challenges, Superalloys. 718 (2001) 13–23.
[9]	A. Thomas, M. El-Wahabi, J. Cabrera, J. Prado, High temperature deformation of Inconel 718, Journal of Materials Processing Technology. 177 (2006) 469–472.
[10]	D. Keiser, H. Brown, Review of the physical metallurgy of Alloy 718, 1976.
[11]	D. Deng, Additively manufactured Inconel 718: microstructures and mechanical properties, Licentiate Thesis Degree, Linköping University, 2018.
[12]	W.M. Tucho, P. Cuvillier, A. Sjolyst-Kverneland, V. Hansen, Microstructure and hardness studies of Inconel 718 manufactured by selective laser melting before and after solution heat treatment, Materials Science and Engineering: A. 689 (2017) 220–232.
[13]	X. Li, J. Shi, C. Wang, G. Cao, A. Russell, Z. Zhou, C. Li, G. Chen, Effect of heat treatment on microstructure evolution of Inconel 718 alloy fabricated by selective laser melting, Journal of Alloys and Compounds. (2018).
[14]	N.C. Ferreri, S.C. Vogel, M. Knezevic, Determining volume fractions of γ, γ′, γ″, δ, and MC-carbide phases in Inconel 718 as a function of its processing history using an advanced neutron diffraction procedure, Materials Science and Engineering: A. 781 (2020) 139228. https://doi.org/10.1016/j.msea.2020.139228.
[15]	G. Cao, T. Sun, C. Wang, X. Li, M. Liu, Z. Zhang, P. Hu, A.M. Russell, R. Schneider, D. Gerthsen, Investigations of γ′, γ ″and δ precipitates in heat-treated Inconel 718 alloy fabricated by selective laser melting, Materials Characterization. 136 (2018) 398–406.
[16]	H. Eiselstein, Metallurgy of a Columbium-Hardened Nickel-Chromium-Iron Alloy, Advances in the Technology of Stainless Steels and Related Alloys. (1965). https://doi.org/10.1520/STP43733S.
[17]	Y. Desvallées, M. Bouzidi, F. Bois, N. Beaude, Delta phase in Inconel 718: mechanical properties and forging process requirements, Superalloys. 718 (1994) 281–291.
[18]	H. Zhang, S. Zhang, M. Cheng, Z. Li, Deformation characteristics of δ phase in the delta-processed Inconel 718 alloy, Materials Characterization. 61 (2010) 49–53.
[19]	S. Li, J. Zhuang, J. Yang, X. Xie, The effect of phase on crack propagation under creep and fatigue conditions in alloy 718, Superalloys. 718 (1994) 625–706.
[20]	M.J. Donachie, S.J. Donachie, Superalloys: A Technical Guide, 2nd Edition, ASM International, 2002.
[21]	M. Sundararaman, P. Mukhopadhyay, S. Banerjee, Carbide precipitation in nickel base superalloys 718 and 625 and their effect on mechanical properties, Superalloys. 718 (1997) 625–706.
[22]	C.T. Sims, A contemporary view of nickel-base superalloys, The Journal of The Minerals, Metals & Materials Society. 18 (1966) 1119–1130. https://doi.org/10.1007/BF03378505.
[23]	F. Zupanič, T. Bončina, A. Križman, F. Tichelaar, Structure of continuously cast Ni-based superalloy Inconel 713C, Journal of Alloys and Compounds. 329 (2001) 290–297.
[24]	D. Zhang, Z. Feng, C. Wang, W. Wang, Z. Liu, W. Niu, Comparison of microstructures and mechanical properties of Inconel 718 alloy processed by selective laser melting and casting, Materials Science and Engineering: A. 724 (2018) 357–367.
[25]	P. Liu, J. Hu, S. Sun, K. Feng, Y. Zhang, M. Cao, Microstructural evolution and phase transformation of Inconel 718 alloys fabricated by selective laser melting under different heat treatment, Journal of Manufacturing Processes. 39 (2019) 226–232.
[26]	D. Zhang, W. Niu, X. Cao, Z. Liu, Effect of standard heat treatment on the microstructure and mechanical properties of selective laser melting manufactured Inconel 718 superalloy, Materials Science and Engineering: A. 644 (2015) 32–40.
[27]	P. G.D., What Is Wrought Metal?, (n.d.). https://www.hunker.com/13412365/what-is-wrought-metal.
[28]	E. Hosseini, V. Popovich, A review of mechanical properties of additively manufactured Inconel 718, Additive Manufacturing. 30 (2019) 100877.
[29]	R. Seede, Microstructural analysis and mechanical properties evaluation of heat treated selective laser melted Inconel 718, Thesis for Master of Science Degree, Masdar Institute of Science and Technology, 2017.
[30]	W.E. Frazier, Metal additive manufacturing: A review, Journal of Materials Engineering and Performance. 23 (2014) 1917–1928. https://doi.org/10.1007/s11665-014-0958-z.
[31]	L. Yang, K. Hsu, B. Baughman, D. Godfrey, F. Medina, M. Menon, S. Wiener, Additive manufacturing of metals: the technology, materials, design and production, Springer, 2017.
[32]	E.C. Santos, M. Shiomi, K. Osakada, T. Laoui, Rapid manufacturing of metal components by laser forming, International Journal of Machine Tools and Manufacture. 46 (2006) 1459–1468. https://doi.org/10.1016/j.ijmachtools.2005.09.005.
[33]	S. Bremen, W. Meiners, A. Diatlov, Selective laser melting: a manufacturing technology for the future, Laser Technik Journal. 9 (2012) 33–38.
[34]	J. Strößner, M. Terock, U. Glatzel, Mechanical and microstructural investigation of nickel‐based superalloy IN718 manufactured by selective laser melting (SLM), Advanced Engineering Materials. 17 (2015) 1099–1105.
[35]	T. Trosch, J. Strößner, R. Völkl, U. Glatzel, Microstructure and mechanical properties of selective laser melted Inconel 718 compared to forging and casting, Materials Letters. 164 (2016) 428–431.
[36]	M. Monzón, Z. Ortega, A. Martínez, F. Ortega, Standardization in additive manufacturing: activities carried out by international organizations and projects, The International Journal of Advanced Manufacturing Technology. 76 (2015) 1111–1121.
[37]	I. Gibson, D. Rosen, B. Stucker, Additive Manufacturing Technologies: 3D Printing, Rapid Prototyping, and Direct Digital Manufacturing, 2nd ed., Springer-Verlag, New York, 2015. https://doi.org/10.1007/978-1-4939-2113-3.
[38]	Laser Additive Manufacturing (AM): Classification, Processing Philosophy, and Metallurgical Mechanisms | SpringerLink, (n.d.). https://link.springer.com/chapter/10.1007/978-3-662-46089-4_2 (accessed April 8, 2020).
[39]	I. Gibson, D.W. Rosen, B. Stucker, Powder Bed Fusion Processes, in: I. Gibson, D.W. Rosen, B. Stucker (Eds.), Additive Manufacturing Technologies: Rapid Prototyping to Direct Digital Manufacturing, Springer US, Boston, MA, 2010: pp. 120–159. https://doi.org/10.1007/978-1-4419-1120-9_5.
[40]	M. Brandt, Laser Additive Manufacturing: Materials, Design, Technologies, and Applications, Woodhead Publishing, 2016.
[41]	J.-P. Choi, G.-H. Shin, S. Yang, D.-Y. Yang, J.-S. Lee, M. Brochu, J.-H. Yu, Densification and microstructural investigation of Inconel 718 parts fabricated by selective laser melting, Powder Technology. 310 (2017) 60–66. https://doi.org/10.1016/j.powtec.2017.01.030.
[42]	C.Y. Yap, C.K. Chua, Z.L. Dong, Z.H. Liu, D.Q. Zhang, L.E. Loh, S.L. Sing, Review of selective laser melting: Materials and applications, Applied Physics Reviews. 2 (2015) 041101.
[43]	K. Guan, Z. Wang, M. Gao, X. Li, X. Zeng, Effects of processing parameters on tensile properties of selective laser melted 304 stainless steel, Materials & Design. 50 (2013) 581–586. https://doi.org/10.1016/j.matdes.2013.03.056.
[44]	M. Shiomi, K. Osakada, K. Nakamura, T. Yamashita, F. Abe, Residual Stress within Metallic Model Made by Selective Laser Melting Process, CIRP Annals. 53 (2004) 195–198. https://doi.org/10.1016/S0007-8506(07)60677-5.
[45]	A. Mostafa, I. Picazo Rubio, V. Brailovski, M. Jahazi, M. Medraj, Structure, texture and phases in 3D printed IN718 alloy subjected to homogenization and HIP treatments, Metals. 7 (2017) 196.
[46]	E. Chlebus, K. Gruber, B. Kuźnicka, J. Kurzac, T. Kurzynowski, Effect of heat treatment on the microstructure and mechanical properties of Inconel 718 processed by selective laser melting, Materials Science and Engineering: A. 639 (2015) 647–655.
[47]	X. Wang, X. Gong, K. Chou, Review on powder-bed laser additive manufacturing of Inconel 718 parts, Journal of Engineering Manufacture. 231 (2017) 1890–1903.
[48]	C. Li, Z. Liu, X. Fang, Y. Guo, Residual stress in metal additive manufacturing, Procedia CIRP. 71 (2018) 348–353.
[49]	B.E. Carroll, T.A. Palmer, A.M. Beese, Anisotropic tensile behavior of Ti–6Al–4V components fabricated with directed energy deposition additive manufacturing, Acta Materialia. 87 (2015) 309–320.
[50]	R. Seede, A. Mostafa, V. Brailovski, M. Jahazi, M. Medraj, Microstructural and microhardness evolution from homogenization and hot isostatic pressing on selective laser melted Inconel 718: structure, texture, and phases, Journal of Manufacturing and Materials Processing. 2 (2018) 30.
[51]	I. Picazo Rubio, Selective laser melting of Inconel 718: Microstructure and mechanical properties, Thesis for Master of Science Degree, Masdar Institute of Science and Technology, 2016.
[52]	M. Ni, C. Chen, X. Wang, P. Wang, R. Li, X. Zhang, K. Zhou, Anisotropic tensile behavior of in situ precipitation strengthened Inconel 718 fabricated by additive manufacturing, Materials Science and Engineering: A. 701 (2017) 344–351.
[53]	D. Deng, R.L. Peng, H. Brodin, J. Moverare, Microstructure and mechanical properties of Inconel 718 produced by selective laser melting: Sample orientation dependence and effects of post heat treatments, Materials Science and Engineering: A. 713 (2018) 294–306.
[54]	F. Zhang, L.E. Levine, A.J. Allen, M.R. Stoudt, G. Lindwall, E.A. Lass, M.E. Williams, Y. Idell, C.E. Campbell, Effect of heat treatment on the microstructural evolution of a nickel-based superalloy additive-manufactured by laser powder bed fusion, Acta Materialia. 152 (2018) 200–214.
[55]	T. DebRoy, H. Wei, J. Zuback, T. Mukherjee, J. Elmer, J. Milewski, A.M. Beese, A. Wilson-Heid, A. De, W. Zhang, Additive manufacturing of metallic components–process, structure and properties, Progress in Materials Science. 92 (2018) 112–224.
[56]	B. Song, X. Zhao, S. Li, C. Han, Q. Wei, S. Wen, J. Liu, Y. Shi, Differences in microstructure and properties between selective laser melting and traditional manufacturing for fabrication of metal parts: A review, Frontiers of Mechanical Engineering. 10 (2015) 111–125.
[57]	Q. Jia, D. Gu, Selective laser melting additive manufacturing of Inconel 718 superalloy parts: Densification, microstructure and properties, Journal of Alloys and Compounds. 585 (2014) 713–721.
[58]	J. Schneider, B. Lund, M. Fullen, Effect of heat treatment variations on the mechanical properties of Inconel 718 selective laser melted specimens, Additive Manufacturing. 21 (2018) 248–254.
[59]	V. Petkov, Alloy 718 manufactured by AM Selective Laser Melting, Materials Engineering, master’s level, Luleå University of Technology, 2018.
[60]	A. Maamoun, Selective laser melting and post-processing for lightweight metallic optical components, Thesis for Doctor of Philosophy Degree, McMaster University, 2019. https://macsphere.mcmaster.ca/handle/11375/24032 (accessed April 15, 2020).
[61]	S. Moorthy, Modeling and characterization of mechanical properties in laser powder bed fusion additive manufactured Inconel 718, Thesis for Master of Science Degree (Mechanical Engineering), Colorado School of Mines, 2018. 
[62]	Y. Gao, D. Zhang, M. Cao, R. Chen, Z. Feng, Effect of δ phase on high temperature mechanical performances of Inconel 718 fabricated with SLM process, Materials Science and Engineering: A. 767 (2019) 138327.
[63]	J.-R. Zhao, F.-Y. Hung, T.-S. Lui, Microstructure and tensile fracture behavior of three-stage heat treated Inconel 718 alloy produced via laser powder bed fusion process, Journal of Materials Research and Technology. (2020). https://doi.org/10.1016/j.jmrt.2020.01.030.
[64]	E. Yasa, Manufacturing by combining selective laser melting and selective laser erosion/laser re-melting, CIRP Annals-Manufacturing Technology. 60 (2011) 263–266.
[65]	S.A.E. Aerospace, Aerospace Material Specification: AMS 5662, in: SAE International, 2009.
[66]	S.A.E. Aerospace, Aerospace Material Specification: AMS 5383, in: SAE International, 2012.
[67]	L. Zhou, A. Mehta, B. McWilliams, K. Cho, Y. Sohn, Microstructure, precipitates and mechanical properties of powder bed fused Inconel 718 before and after heat treatment, Journal of Materials Science & Technology. 35 (2019) 1153–1164.
[68]	K. Amato, S. Gaytan, L. Murr, E. Martinez, P. Shindo, J. Hernandez, S. Collins, F. Medina, Microstructures and mechanical behavior of Inconel 718 fabricated by selective laser melting, Acta Materialia. 60 (2012) 2229–2239.
[69]	M. Calandri, S. Yin, B. Aldwell, F. Calignano, R. Lupoi, D. Ugues, Texture and microstructural features at different length scales in Inconel 718 produced by selective laser melting, Materials. 12 (2019) 1293.
[70]	B. Vrancken, L. Thijs, J.-P. Kruth, J. Van Humbeeck, Heat treatment of Ti6Al4V produced by selective laser melting: microstructure and mechanical properties, Journal of Alloys and Compounds. 541 (2012) 177–185.
[71]	A. Riemer, S. Leuders, M. Thöne, H. Richard, T. Tröster, T. Niendorf, On the fatigue crack growth behavior in 316L stainless steel manufactured by selective laser melting, Engineering Fracture Mechanics. 120 (2014) 15–25.
[72]	A. Kreitcberg, V. Brailovski, S. Turenne, Effect of heat treatment and hot isostatic pressing on the microstructure and mechanical properties of Inconel 625 alloy processed by laser powder bed fusion, Materials Science and Engineering: A. 689 (2017) 1–10.
[73]	M. Saadati, A.K. Edalat Nobarzad, M. Jahazi, On the hot cracking of HSLA steel welds: Role of epitaxial growth and HAZ grain size, Journal of Manufacturing Processes. 41 (2019) 242–251. https://doi.org/10.1016/j.jmapro.2019.03.032.
[74]	R. Singh, J. Hyzak, T. Howson, R. Biederman, Recrystallization behavior of cold rolled alloy 718, Superalloys. 718 (1991) 205–215.
[75]	W.M. Tucho, V. Hansen, Characterization of SLM-fabricated Inconel 718 after solid solution and precipitation hardening heat treatments, Journal of Materials Science. 54 (2019) 823–839.
[76]	R. Jiang, A. Mostafaei, J. Pauza, C. Kantzos, A.D. Rollett, Varied heat treatments and properties of laser powder bed printed Inconel 718, Materials Science and Engineering: A. 755 (2019) 170–180.
[77]	Atomic Radius for all the elements in the Periodic Table, WOLFRAM MATHEMATICA. (2014). https://periodictable.com/Properties/A/AtomicRadius.v.html.
[78]	Y. Cao, P. Bai, F. Liu, X. Hou, Y. Guo, Effect of the solution temperature on the precipitates and grain evolution of IN718 fabricated by laser additive manufacturing, Materials. 13 (2020) 340. https://doi.org/10.3390/ma13020340.
[79]	H. Qi, M. Azer, A. Ritter, Studies of standard heat treatment effects on microstructure and mechanical properties of laser net shape manufactured Inconel 718, Metallurgical and Materials Transactions A. 40 (2009) 2410–2422.
[80]	X. Zhao, J. Chen, X. Lin, W. Huang, Study on microstructure and mechanical properties of laser rapid forming Inconel 718, Materials Science and Engineering: A. 478 (2008) 119–124.
[81]	F. Liu, X. Lin, G. Yang, M. Song, J. Chen, W. Huang, Recrystallization and its influence on microstructures and mechanical properties of laser solid formed nickel base superalloy Inconel 718, Rare Metals. 30 (2011) 433–438.
[82]	P. Blackwell, The mechanical and microstructural characteristics of laser-deposited IN718, Journal of Materials Processing Technology. 170 (2005) 240–246.
[83]	S. Raghavan, B. Zhang, P. Wang, C.-N. Sun, M.L.S. Nai, T. Li, J. Wei, Effect of different heat treatments on the microstructure and mechanical properties in selective laser melted Inconel 718 alloy, Materials and Manufacturing Processes. 32 (2017) 1588–1595.
[84]	V. Popovich, E. Borisov, A. Popovich, V.S. Sufiiarov, D. Masaylo, L. Alzina, Functionally graded Inconel 718 processed by additive manufacturing: Crystallographic texture, anisotropy of microstructure and mechanical properties, Materials & Design. 114 (2017) 441–449.
[85]	Y.-L. Kuo, S. Horikawa, K. Kakehi, The effect of interdendritic δ phase on the mechanical properties of Alloy 718 built up by additive manufacturing, Materials & Design. 116 (2017) 411–418.
[86]	D. Ivanov, A. Travyanov, P. Petrovskiy, V. Cheverikin, Е. Alekseeva, A. Khvan, I. Logachev, Evolution of structure and properties of the nickel-based alloy EP718 after the SLM growth and after different types of heat and mechanical treatment, Additive Manufacturing. 18 (2017) 269–275.
[87]	V. Popovich, E. Borisov, A. Popovich, V.S. Sufiiarov, D. Masaylo, L. Alzina, Impact of heat treatment on mechanical behaviour of Inconel 718 processed with tailored microstructure by selective laser melting, Materials & Design. 131 (2017) 12–22.
[88]	A. Kreitcberg, V. Brailovski, S. Turenne, Elevated temperature mechanical behavior of IN625 alloy processed by laser powder-bed fusion, Materials Science and Engineering: A. 700 (2017) 540–553.
[89]	E. Fayed, D. Shahriari, M. Saadati, V. Brailovski, M. Jahazi, M. Medraj, Influence of homogenization and solution treatments time on the microstructure and hardness of Inconel 718 fabricated by laser powder bed fusion process, Materials. 13 (2020).
[90]	A. Hilaire, E. Andrieu, X. Wu, High-temperature mechanical properties of alloy 718 produced by laser powder bed fusion with different processing parameters, Additive Manufacturing. 26 (2019) 147–160.
[91]	G.E. Bean, T.D. McLouth, D.B. Witkin, S.D. Sitzman, P.M. Adams, R.J. Zaldivar, Build orientation effects on texture and mechanical properties of selective laser melting Inconel 718, Journal of Materials Engineering and Performance. 28 (2019) 1942–1949. https://doi.org/10.1007/s11665-019-03980-w.
[92]	X. Li, J.J. Shi, G.H. Cao, A.M. Russell, Z.J. Zhou, C.P. Li, G.F. Chen, Improved plasticity of Inconel 718 superalloy fabricated by selective laser melting through a novel heat treatment process, Materials & Design. 180 (2019) 107915. https://doi.org/10.1016/j.matdes.2019.107915.
[93]	H. Yuan, W.C. Liu, Effect of the δ phase on the hot deformation behavior of Inconel 718, Materials Science and Engineering: A. 408 (2005) 281–289. https://doi.org/10.1016/j.msea.2005.08.126.
[94]	Y.C. Lin, J. Deng, Y.-Q. Jiang, D.-X. Wen, G. Liu, Hot tensile deformation behaviors and fracture characteristics of a typical Ni-based superalloy, Materials & Design. 55 (2014) 949–957. https://doi.org/10.1016/j.matdes.2013.10.071.
[95]	A. Mostafa, D. Shahriari, I.P. Rubio, V. Brailovski, M. Jahazi, M. Medraj, Hot compression behavior and microstructure of selectively laser-melted IN718 alloy, The International Journal of Advanced Manufacturing Technology. 96 (2018) 371–385.
[96]	Y. Wang, L. Zhen, W.Z. Shao, L. Yang, X.M. Zhang, Hot working characteristics and dynamic recrystallization of delta-processed superalloy 718, Journal of Alloys and Compounds. 474 (2009) 341–346. https://doi.org/10.1016/j.jallcom.2008.06.079.
[97]	S.-H. Zhang, H.-Y. Zhang, M. Cheng, Tensile deformation and fracture characteristics of delta-processed Inconel 718 alloy at elevated temperature, Materials Science and Engineering: A. 528 (2011) 6253–6258.
[98]	G. Varela-Castro, J.-M. Cabrera, J.-M. Prado, Critical strain for dynamic recrystallisation. The particular case of steels, Metals. 10 (2020) 135. https://doi.org/10.3390/met10010135.
[99]	GE Reports Staff, 5 Ways GE is Changing the World with 3D Printing, (2017). https://www.ge.com/news/reports/5-ways-ge-changing-world-3d-printing.
[100]	D.A. Lesyk, S. Martinez, B.N. Mordyuk, V.V. Dzhemelinskyi, А. Lamikiz, G.I. Prokopenko, Post-processing of the Inconel 718 alloy parts fabricated by selective laser melting: Effects of mechanical surface treatments on surface topography, porosity, hardness and residual stress, Surface and Coatings Technology. 381 (2020) 125136. https://doi.org/10.1016/j.surfcoat.2019.125136.
[101]	D. Newell, Solution anneal heat treatments to enhance mechanical performance of additively manufactured Inconel 718, Thesis for Doctor of Philosophy Degree, Air Force Institute of Technology, 2020. https://scholar.afit.edu/etd/3210.
[102]	W. Huang, J. Yang, H. Yang, G. Jing, Z. Wang, X. Zeng, Heat treatment of Inconel 718 produced by selective laser melting: Microstructure and mechanical properties, Materials Science and Engineering: A. 750 (2019) 98–107.
[103]	R. Shi, S.A. Khairallah, T.T. Roehling, T.W. Heo, J.T. McKeown, M.J. Matthews, Microstructural control in metal laser powder bed fusion additive manufacturing using laser beam shaping strategy, Acta Materialia. 184 (2020) 284–305. https://doi.org/10.1016/j.actamat.2019.11.053.
[104]	N. Raghavan, S. Simunovic, R. Dehoff, A. Plotkowski, J. Turner, M. Kirka, S. Babu, Localized melt-scan strategy for site specific control of grain size and primary dendrite arm spacing in electron beam additive manufacturing, Acta Materialia. 140 (2017) 375–387. https://doi.org/10.1016/j.actamat.2017.08.038.
[105]	T.T. Roehling, S.S.Q. Wu, S.A. Khairallah, J.D. Roehling, S.S. Soezeri, M.F. Crumb, M.J. Matthews, Modulating laser intensity profile ellipticity for microstructural control during metal additive manufacturing, Acta Materialia. 128 (2017) 197–206. https://doi.org/10.1016/j.actamat.2017.02.025.
[106]	T. Vilaro, C. Colin, J.D. Bartout, L. Nazé, M. Sennour, Microstructural and mechanical approaches of the selective laser melting process applied to a nickel-base superalloy, Materials Science and Engineering: A. 534 (2012) 446–451. https://doi.org/10.1016/j.msea.2011.11.092.
[107]	Y.-L. Kuo, S. Horikawa, K. Kakehi, Effects of build direction and heat treatment on creep properties of Ni-base superalloy built up by additive manufacturing, Scripta Materialia. 129 (2017) 74–78. https://doi.org/10.1016/j.scriptamat.2016.10.035.
[108]	B. Diepold, N. Vorlaufer, S. Neumeier, T. Gartner, M. Göken, Optimization of the heat treatment of additively manufactured Ni-base superalloy IN718, International Journal of Minerals, Metallurgy and Materials. 27 (2020) 640–648. https://doi.org/10.1007/s12613-020-1991-6.
[109]	C.S. Pande, B.B. Rath, M.A. Imam, Effect of annealing twins on Hall–Petch relation in polycrystalline materials, Materials Science and Engineering: A. 367 (2004) 171–175. https://doi.org/10.1016/j.msea.2003.09.100.
[110]	Y. Yuan, Y. Gu, C. Cui, T. Osada, T. Yokokawa, H. Harada, A Novel Strategy for the Design of Advanced Engineering Alloys—Strengthening Turbine Disk Superalloys via Twinning Structures, Advanced Engineering Materials. 13 (2011) 296–300. https://doi.org/10.1002/adem.201000232.
[111]	E. Fayed, D. Shahriari, M. Saadati, V. Brailovski, M. Jahazi, M. Medraj, Effect of Homogenization and Solution Treatments Time on the Elevated-Temperature Mechanical Behavior of Inconel 718 Fabricated by Laser Powder Bed Fusion, Manuscript Submitted for Publication. (2020).
[112]	Design Expert software, Stat-Ease, Inc., Minneapolis, MN, 2019.
[113]	B. Beausir, J.-J. Fundenberger, Analysis tools for electron and X-ray diffraction, Université de Lorraine, Metz, 2017. www.atex-software.eu.
[114]	Quantax Esprit software, Bruker Nano GmbH, Berlin, Germany, 2015.
[115]	H. Zhang, D. Gu, C. Ma, M. Guo, J. Yang, R. Wang, Effect of post heat treatment on microstructure and mechanical properties of Ni-based composites by selective laser melting, Materials Science and Engineering: A. (2019) 138294.
[116]	D. Connétable, B. Ter-Ovanessian, É. Andrieu, Diffusion and segregation of niobium in fcc-nickel, Journal of Physics: Condensed Matter. 24 (2012) 095010. https://doi.org/10.1088/0953-8984/24/9/095010.
[117]	L. Johnson, M. Mahmoudi, B. Zhang, R. Seede, X. Huang, J.T. Maier, H.J. Maier, I. Karaman, A. Elwany, R. Arróyave, Assessing printability maps in additive manufacturing of metal alloys, Acta Materialia. 176 (2019) 199–210. https://doi.org/10.1016/j.actamat.2019.07.005.
[118]	Dave VanAken, Engineering concepts: formation of annealing twins, Industrial Heating. (2000). https://www.industrialheating.com/articles/86154-engineering-concepts-formation-of-annealing-twins.
[119]	T. Watanabe, An approach to grain boundary design for strong and ductile polycrystals, Res Mechanica. 11 (1984) 47–84.
[120]	M. Jouiad, E.Marin, R. Devarapali, J. Cormier, F. Ravaux, C. Gall, J.-M. Franchet, Microstructure andmechanical properties evolutions of alloy 718 during isothermal and thermal cycling over-aging, Materials and Design. 102 (2016) 284–296. https://doi.org/10.1016/j.matdes.2016.04.048.
[121]	S.J. Hong, W.P. CHEN,, T.W. WANG, A diffraction study of the γ″ phase in Inconel 718 superalloy, Metallurgical and Materials Transactions A. 32A (2001).
[122]	X.S. Xie, J.X. Dong, M.C. Zhang, Research and Development of Inconel 718 Type Superalloy, Materials Science Forum. 539–543 (2007) 262–269. https://doi.org/10.4028/www.scientific.net/MSF.539-543.262.
[123]	Y. Han, P. Deb, M.C. Chaturvedi, Coarsening behaviour of γ″- and γ′-particles in Inconel alloy 718, Metal Science. 16 (1982) 555–562. https://doi.org/10.1179/030634582790427118.
[124]	A. Agnoli, C. Le Gall, J. Thebault, E. Marin, J. Cormier, Mechanical properties evolution of γ′/γ″ nickel-base superalloys during long-term thermal over-aging, Metallurgical and Materials Transactions A. 49 (2018) 4290–4300. https://doi.org/10.1007/s11661-018-4778-x.
[125]	A. Volek, R.F. Singer, R. Buergel, J. Grossmann, Y. Wang, Influence of topologically closed packed phase formation on creep rupture life of directionally solidified nickel-base superalloys, Metallurgical and Materials Transactions A. 37 (2006) 405–410. https://doi.org/10.1007/s11661-006-0011-4.
[126]	H. Monajati, A.K. Taheri, M. Jahazi, S. Yue, Deformation characteristics of isothermally forged UDIMET 720 nickel-base superalloy, Metallurgical and Materials Transactions A. 36 (2005) 895–905. https://doi.org/10.1007/s11661-005-0284-z.
[127]	M. Dehmas, J. Lacaze, A. Niang, B. Viguier, TEM Study of High-Temperature Precipitation of Delta Phase in Inconel 718 Alloy, Advances in Materials Science and Engineering. 2011 (2011) e940634. https://doi.org/10.1155/2011/940634.
[128]	M. Balbaa, S. Mekhiel, M. Elbestawi, J. McIsaac, On selective laser melting of Inconel 718: Densification, surface roughness, and residual stresses, Materials & Design. 193 (2020) 108818. https://doi.org/10.1016/j.matdes.2020.108818.
[129]	X. Yu, X. Lin, F. Liu, L. Wang, Y. Tang, J. Li, S. Zhang, W. Huang, Influence of post-heat-treatment on the microstructure and fracture toughness properties of Inconel 718 fabricated with laser directed energy deposition additive manufacturing, Materials Science and Engineering: A. (2020) 140092. https://doi.org/10.1016/j.msea.2020.140092.
[130]	E. Fayed, M. Saadati, D. Shahriari, V. Brailovski, M. Jahazi, M. Medraj, Optimization of the post-process heat treatment of additively manufactured Inconel 718 superalloy using laser powder bed fusion process, Manuscript Submitted for Publication. (2020).
[131]	A.C. Karaoglanli, K. Ogawa, A. Türk, I. Ozdemir, Thermal shock and cycling behavior of thermal barrier coatings (TBCs) used in gas turbines, in: Progress in Gas Turbine Performance, IntechOpen, 2013.
[132]	D.-H. Jeong, M.-J. Choi, M. Goto, H.-C. Lee, S. Kim, Effect of service exposure on fatigue crack propagation of Inconel 718 turbine disc material at elevated temperatures, Materials Characterization. 95 (2014) 232–244.
[133]	Z. Wang, K. Guan, M. Gao, X. Li, X. Chen, X. Zeng, The microstructure and mechanical properties of deposited-IN718 by selective laser melting, Journal of Alloys and Compounds. 513 (2012) 518–523.
[134]	J.F. Radavich, The physical metallurgy of cast and wrought alloy 718, in: Superalloys 718 Metallurgy and Applications (1989), TMS, 2004: pp. 229–240. https://doi.org/10.7449/1989/Superalloys_1989_229_240.
[135]	Y. Idell, L.E. Levine, A.J. Allen, F. Zhang, C.E. Campbell, G.B. Olson, J. Gong, D.R. Snyder, H.Z. Deutchman, Unexpected δ-phase formation in additive-manufactured Ni-based superalloy, JOM. 68 (2016) 950–959. https://doi.org/10.1007/s11837-015-1772-2.
[136]	C. Slama, C. Servant, G. Cizeron, Aging of the Inconel 718 alloy between 500 and 750 °C, Journal of Materials Research. 12 (1997) 2298–2316. https://doi.org/10.1557/JMR.1997.0306.
[137]	L.M. Suave, J. Cormier, P. Villechaise, A. Soula, Z. Hervier, D. Bertheau, J. Laigo, Microstructural evolutions during thermal aging of alloy 625: Impact of temperature and forming process, Metallurgical and Materials Transactions A. 45 (2014) 2963–2982. https://doi.org/10.1007/s11661-014-2256-7.
[138]	Z.S. Yu, J.X. Zhang, Y. Yuan, R.C. Zhou, H.J. Zhang, H.Z. Wang, Microstructural evolution and mechanical properties of Inconel 718 after thermal exposure, Materials Science and Engineering: A. 634 (2015) 55–63. https://doi.org/10.1016/j.msea.2015.03.004.
[139]	R. Thompson, J. Dobbs, D. Mayo, The effect of heat treatment on microfissuring in alloy 718, Weld.J. 65 (1986) 299.
[140]	M. Sundararaman, P. Mukhopadhyay, S. Banerjee, Precipitation of the δ-Ni3Nb phase in two nickel base superalloys, Metallurgical Transactions A. 19 (1988) 453–465. https://doi.org/10.1007/BF02649259.
[141]	R. Cozar, A. Pineau, Morphology of γ’ and γ" precipitates and thermal stability of Inconel 718 type alloys, Metallurgical Transactions. 4 (1973) 47–59. https://doi.org/10.1007/BF02649604.
[142]	C. Slama, M. Abdellaoui, Structural characterization of the aged Inconel 718, Journal of Alloys and Compounds. 306 (2000) 277–284. https://doi.org/10.1016/S0925-8388(00)00789-1.
[143]	A. Chamanfar, L. Sarrat, M. Jahazi, M. Asadi, A. Weck, A.K. Koul, Microstructural characteristics of forged and heat treated Inconel-718 disks, Materials & Design (1980-2015). 52 (2013) 791–800. https://doi.org/10.1016/j.matdes.2013.06.004.
[144]	OriginPro, OriginLab Corporation, Northampton, MA, USA, 2019.