1. Jinoop AN, Paul CP, Bindra KS(2019) Laser-assisted directed energy deposition of nickel super alloys: A review. Proceedings of the IMechE 233: 2376–2400.
2. Fan W, Ji W, Wang L, et al(2020) A review on cutting tool technology in machining of Ni-based superalloys() Int J Adv Manuf Technol 110: 2863–2879.
3. Marchese G, Lorusso M, Parizia S, et al(2018) Influence of heat treatments on microstructure evolution and mechanical properties of Inconel 625 processed by laser powder bed fusion. Materials Science and Engineering: A 729: 64–75.
4. Pleass C, Jothi S(2018) Influence of powder characteristics and additive manufacturing process parameters on the microstructure and mechanical behaviour of Inconel 625 fabricated by Selective Laser Melting. Additive Manufacturing 24: 419–431.
5. Ramenatte N, Vernouillet A, Mathieu S, et al(2020) A comparison of the high-temperature oxidation behaviour of conventional wrought and laser beam melted Inconel 625. Corrosion Science 164: 108347.
6. Benoit MJ, Mazur M, Easton MA, et al(2021) Effect of alloy composition and laser powder bed fusion parameters on the defect formation and mechanical properties of Inconel 625. Int J Adv Manuf Technol 114: 915–927.
7. Gola K, Dubiel B, Kalemba-Rec I(2020) Microstructural Changes in Inconel 625 Alloy Fabricated by Laser-Based Powder Bed Fusion Process and Subjected to High-Temperature Annealing. J of Materi Eng and Perform 29: 1528–1534.
8. Marchese G, Parizia S, Rashidi M, et al(2020) The role of texturing and microstructure evolution on the tensile behavior of heat-treated Inconel 625 produced via laser powder bed fusion. Materials Science and Engineering: A 769: 138500.
9. Jinoop AN, Paul CP, Nayak SK, et al(2021) Effect of laser energy per unit powder feed on Hastelloy-X walls built by laser directed energy deposition based additive manufacturing. Optics & Laser Technology 138: 106845.
10. Yadav S, Paul CP, Jinoop AN, et al(2020) Laser Directed Energy Deposition based Additive Manufacturing of Copper: Process Development and Material Characterizations. Journal of Manufacturing Processes 58: 984–997.
11. Shrestha S, Chou K(2021) A study of transient and steady-state regions from single-track deposition in laser powder bed fusion. Journal of Manufacturing Processes 61: 226–235.
12. Cheng B, Chou K(2020) A numerical investigation of support structure designs for overhangs in powder bed electron beam additive manufacturing. Journal of Manufacturing Processes 49: 187–195.
13. Resnina N, Palani IA, Belyaev S, et al(2021) Structure, martensitic transformations and mechanical behaviour of NiTi shape memory alloy produced by wire arc additive manufacturing. Journal of Alloys and Compounds 851: 156851.
14. Nayak SK, Mishra SK, Paul CP, et al(2020) Effect of energy density on laser powder bed fusion built single tracks and thin wall structures with 100 µm preplaced powder layer thickness. Optics & Laser Technology 125: 106016.
15. Ye W, Bao J, Lei J, et al(2021) Multiphysics Modeling of Thermal Behavior of Commercial Pure Titanium Powder During Selective Laser Melting. Met Mater Int. Epub ahead of print. DOI: 10.1007/s12540-021-01019-1.
16. Gerstgrasser M, Cloots M, Stirnimann J, et al(2021) Residual stress reduction of LPBF-processed CM247LC samples via multi laser beam strategies. Int J Adv Manuf Technol. Epub ahead of print. DOI: 10.1007/s00170-021-07083-6.
17. Erturk AT, Bulduk ME, Tarakçi G, et al(2021) Investigation of the Microstructure and Mechanical Characteristics of Lattice Structures Produced by Laser Powder Bed Fusion Method. Met Mater Int. Epub ahead of print 10 September. DOI: 10.1007/s12540-021-01038-y.
18. Zhang Y, Yang S, Zhao YF(2020) Manufacturability analysis of metal laser-based powder bed fusion additive manufacturing—a survey. Int J Adv Manuf Technol 110: 57–78.
19. Salarian M, Asgari H, Vlasea M(2020) Pore space characteristics and corresponding effect on tensile properties of Inconel 625 fabricated via laser powder bed fusion. Materials Science and Engineering: A 769: 138525.
20. Olleak A, Xi Z(2021) A study of modeling assumptions and adaptive remeshing for thermomechanical finite element modeling of the LPBF process. Int J Adv Manuf Technol 115: 3599–3615.
21. Benarji K, Ravi Kumar Y, Jinoop AN, et al(2021) Effect of Heat-Treatment on the Microstructure, Mechanical Properties and Corrosion Behaviour of SS 316 Structures Built by Laser Directed Energy Deposition Based Additive Manufacturing. Met Mater 27: 488–499.
22. Jahns K, Bappert R, Böhlke P, et al(2020) Additive manufacturing of CuCr1Zr by development of a gas atomization and laser powder bed fusion routine. Int J Adv Manuf Technol 107: 2151–2161.
23. Chadha K, Tian Y, Spray J, et al(2021) Microtextural Characterization of Additively Manufactured SS316L After Hot Isostatic Pressing Heat Treatment. Met Mater Int. Epub ahead of print. DOI: 10.1007/s12540-021-01046-y.
24. Ganesh MRS, Reghunath N, J.Levin M, et al(2021) Strontium in Al–Si–Mg Alloy: A Review. Met Mater Int. Epub ahead of print 5 October. DOI: 10.1007/s12540-021-01054-y.
25. Aryanpour G, Mashl S, Warke V(2013) Elastoplastic–viscoplastic modelling of metal powder compaction: application to hot isostatic pressing. Powder Metallurgy 56: 14–23.
26. Liverani E, Lutey AHA, Ascari A, et al(2020) The effects of hot isostatic pressing (HIP) and solubilization heat treatment on the density, mechanical properties, and microstructure of austenitic stainless steel parts produced by selective laser melting (SLM). Int J Adv Manuf Technol 107: 109–122.
27. Liu H, Wang L, Jiang Y, et al(2018) Study on SiO2 thin film modified by post hot isostatic pressing. Vacuum 148: 258–264.
28. Paul CP, Jinoop AN, Nayak SK, et al(2020) Laser Additive Manufacturing in Industry 4.0: Overview, Applications, and Scenario in Developing Economies. In: Balasubramanian KR, Senthilkumar V (1st eds) Additive Manufacturing Applications for Metals and Composites: IGI Global, Trichy, pp. 271–295.
29. Hu X, Xue Z, Ren T, et al(2020) On the fatigue crack growth behaviour of selective laser melting fabricated Inconel 625: Effects of build orientation and stress ratio. Fatigue Fract Eng Mater Struct 43: 771–787.
30. Li S, Wei Q, Shi Y, et al() Microstructure Characteristics of Inconel 625 Superalloy Manufactured by Selective Laser Melting. Journal of Materials Science & Technology 31: 946–952.
31. Kreitcberg A, Brailovski V, Turenne S(2017) Elevated temperature mechanical behavior of IN625 alloy processed by laser powder-bed fusion. Materials Science and Engineering: A 700: 540–553.
32. Wang Y, Yang J, Huang J, et al(2018) Hot isostatic diffusion bonding tungsten alloy and high-strength steel Part I: Design and preparation of Ni-Si-B interlayer by magnetron sputtering. Journal of Manufacturing Processes 35: 360–367.
33. Kang N, Lu JL, Li QG, et al(2020) A new way to net-shaped synthesis tungsten steel by selective laser melting and hot isostatic pressing. Vacuum 179: 109557.
34. Sarkar S, Mukherjee S, Kumar CS, et al(2020) Effects of heat treatment on microstructure, mechanical and corrosion properties of 15-5 PH stainless steel parts built by selective laser melting process. Journal of Manufacturing Processes 50: 279–294.
35. Hyer H, Newell R, Matejczyk D, et al(2021) Microstructural Development in As Built and Heat Treated IN625 Component Additively Manufactured by Laser Powder Bed Fusion. J Phase Equilib Diffus 42: 14–27.
36. Guo X, Ling H, Huang X(2020) Effect of HIP treatment on the microstructure and mechanical properties of a Ni-based superalloy fabricated by selective laser melted method. J Phys: Conf Ser 1605: 012143.
37. Vernouillet A, Vande Put A, Pugliara A, et al(2020) Metal dusting of Inconel 625 obtained by laser beam melting: Effect of manufacturing process and hot isostatic pressure treatment. Corrosion Science 174: 108820.
38. Son K-T, Kassner ME, Lee KA(2020) The Creep Behavior of Additively Manufactured Inconel 625. Advanced Engineering Materials 22: 1900543.
39. Poulin J-R, Brailovski V, Terriault P(2018) Long fatigue crack propagation behavior of Inconel 625 processed by laser powder bed fusion: Influence of build orientation and post-processing conditions. International Journal of Fatigue 116: 634–647.
40. Nayak SK, Mishra SK, Jinoop AN, et al(2020) Experimental Studies on Laser Additive Manufacturing of Inconel-625 Structures Using Powder Bed Fusion at 100 µm Layer Thickness. J of Materi Eng and Perform. Epub ahead of print. DOI: 10.1007/s11665-020-05215-9.
41. Razavi M, Irankhah R, Rahimipour MR(2015) Effect of milling of C and Ti mixture as ceramic coating on the properties of 7Ch3 tool steel during plasma spray process. Proceedings of the Institution of Mechanical Engineers, Part L: Journal of Materials: Design and Applications 229: 137–145.
42. Gao Y, Zhou M(2018) Superior Mechanical Behavior and Fretting Wear Resistance of 3D-Printed Inconel 625 Superalloy. Applied Sciences 8: 2439.
43. Jinoop AN, Denny J, Paul CP, et al(2019) Effect of post heat-treatment on the microstructure and mechanical properties of Hastelloy-X structures manufactured by laser based Directed Energy Deposition. Journal of Alloys and Compounds 797: 399–412.
44. Qiu C, Panwisawas C, Ward M, et al(2015) On the role of melt flow into the surface structure and porosity development during selective laser melting. Acta Materialia 96: 72–79.
45. King WE, Anderson AT, Ferencz RM, et al(2015) Laser powder bed fusion additive manufacturing of metals; physics, computational, and materials challenges. Applied Physics Reviews 2: 041304.
46. Niu S, Yin K, You Q, et al(2019) The alloying elements dispersion and its mechanisms in a Ni-based superalloy during electron beam remelting. Vacuum 166: 107–113.
47. Yang Z, Fang Y, He J(2020) Numerical simulation of heat transfer and fluid flow during vacuum electron beam welding of 2219 aluminium girth joints. Vacuum 175: 109256.
48. Bidare P, Bitharas I, Ward RM, et al(2018) Fluid and particle dynamics in laser powder bed fusion. Acta Materialia 142: 107–120.
49. Atkinson HV, Davies S(2000) Fundamental aspects of hot isostatic pressing: An overview. Metall and Mat Trans A 31: 2981–3000.
50. Keller T, Lindwall G, Ghosh S, et al(2017) Application of finite element, phase-field, and CALPHAD-based methods to additive manufacturing of Ni-based superalloys. Acta Materialia 139: 244–253.
51. DuPont JN(1996) Solidification of an alloy 625 weld overlay. Metall Mater Trans A 27: 3612–3620.
52. Tong X, Zhang H, Li DY(2015) Effect of Annealing Treatment on Mechanical Properties of Nanocrystalline α-iron: an Atomistic Study. Sci Rep 5: 8459.
53. Nguejio J, Szmytka F, Hallais S, et al(2019) Comparison of microstructure features and mechanical properties for additive manufactured and wrought nickel alloys 625. Materials Science and Engineering: A 764: 138214.