[1] Tan C L, Zhou K S, Ma W Y et al. Research progress of laser additive manufacturing of maraging steels[J]. Acta Metallurgica Sinica, 56, 36-52(2020).

[2] Wen S F, Ji X T, Zhou Y et al. Development status and prospect of selective laser melting of mould steels[J]. Laser & Optoelectronics Progress, 55, 011404(2018).

[3] Armillotta A, Baraggi R, Fasoli S. SLM tooling for die casting with conformal cooling channels[J]. The International Journal of Advanced Manufacturing Technology, 71, 573-583(2014).

[4] Chen H Y, Gu D D, Dai D H et al. Microstructure and composition homogeneity, tensile property, and underlying thermal physical mechanism of selective laser melting tool steel parts[J]. Materials Science and Engineering: A, 682, 279-289(2017).

[5] Tan C L, Zhou K S, Ma W Y et al. Microstructural evolution, nanoprecipitation behavior and mechanical properties of selective laser melted high-performance grade 300 maraging steel[J]. Materials & Design, 134, 23-34(2017).

[6] Jägle E A, Choi P P, van Humbeeck J et al. Precipitation and austenite reversion behavior of a maraging steel produced by selective laser melting[J]. Journal of Materials Research, 29, 2072-2079(2014).

[7] DebRoy T, Wei H L, Zuback J S et al. Additive manufacturing of metallic components-Process, structure and properties[J]. Progress in Materials Science, 92, 112-224(2018).

[8] Fayazfar H, Salarian M, Rogalsky A et al. A critical review of powder-based additive manufacturing of ferrous alloys: process parameters, microstructure and mechanical properties[J]. Materials & Design, 144, 98-128(2018).

[9] Chen L, Zhou F, Zhang L et al. Performance optimization of maraging steel M300 formed by selective laser melting[J]. Heat Treatment of Metals, 44, 136-139(2019).

[10] Ying J L, Chao B X, Jiang K Q et al. Development and prospect of ultra high strength steel[J]. New Technology & New Process, 1-4(2018).

[11] Kürnsteiner P, Wilms M B, Weisheit A et al. High-strength Damascus steel by additive manufacturing[J]. Nature, 582, 515-519(2020).

[12] Kürnsteiner P, Wilms M B, Weisheit A et al. Massive nanoprecipitation in an Fe-19Ni-xAl maraging steel triggered by the intrinsic heat treatment during laser metal deposition[J]. Acta Materialia, 129, 52-60(2017).

[13] Cyr E, Lloyd A, Mohammadi M. Tension-compression asymmetry of additively manufactured Maraging steel[J]. Journal of Manufacturing Processes, 35, 289-294(2018).

[14] Bai Y C, Yang Y Q, Wang D et al. Influence mechanism of parameters process and mechanical properties evolution mechanism of maraging steel 300 by selective laser melting[J]. Materials Science and Engineering: A, 703, 116-123(2017).

[15] Mooney B, Kourousis K I, Raghavendra R. Plastic anisotropy of additively manufactured maraging steel: influence of the build orientation and heat treatments[J]. Additive Manufacturing, 25, 19-31(2019).

[16] He Y, Yang K, Sha W. Microstructure and mechanical properties of a 2000 MPa grade co-free maraging steel[J]. Metallurgical and Materials Transactions A, 36, 2273-2287(2005).

[17] Sha W, Malinov S[M]. Titanium alloys: modelling of microstructure, properties and applications(2009).

[18] Tang Y T, Panwisawas C, Ghoussoub J N et al. Alloys-by-design: application to new superalloys for additive manufacturing[J]. Acta Materialia, 202, 417-436(2021).

[19] Platl J, Leitner H, Turk C et al. Determination of martensite start temperature of high-speed steels based on thermodynamic calculations[J]. Steel Research International, 91, 2000063(2020).

[20] Ishida K. Calculation of the effect of alloying elements on the Ms temperature in steels[J]. Journal of Alloys and Compounds, 220, 126-131(1995).

[21] Zhang S G. Calculation of martensite start temperature Ms by Yu’s empirical electron theory of solid and molecule[J]. Transactions of Materials and Heat Treatment, 25(2004).

[22] Hou Z Z, Wu J J. Application of artificaial networks in the prediction of martensite start temperature[J]. Transactions of Materials and Heat Treatment, 25(2004).

[23] Sun Y P. Discussion on the characteristics of martensitic transformation[J]. Journal of Chengdu University(Natural Science Edition), 15, 18-22(1996).

[24] Nedjad S H, Garabagh M R M, Ahmadabadi M N et al. Effect of further alloying on the microstructure and mechanical properties of an Fe-10Ni-5Mn maraging steel[J]. Materials Science and Engineering: A, 473, 249-253(2008).

[25] Zhao X, Song B, Zhang Y J et al. Decarburization of stainless steel during selective laser melting and its influence on Young’s modulus, hardness and tensile strength[J]. Materials Science and Engineering: A, 647, 58-61(2015).

[26] DebRoy T, Wei H L, Zuback J S et al. Additive manufacturing of metallic components-process, structure and properties[J]. Progress in Materials Science, 92, 112-224(2018).

[27] Zhang Z Y, Chu B B, Wang L et al. Effects of process parameters on tensile property of 316L stainless steel parts by selective laser melting[J]. Journal of Hebei University of Technology, 48, 1-5(2019).

[28] Badrossamay M, Childs T H C. Further studies in selective laser melting of stainless and tool steel powders[J]. International Journal of Machine Tools and Manufacture, 47, 779-784(2007).

[29] Damiens A, Bonnefoy H, Titeux I. Influence of processing parameters on mechanical and fatigue properties of 316L steel manufactured by selective laser melting[J]. Welding in the World, 64, 1321-1328(2020).

[30] Yu C F, Zhao C C, Zhang Z F et al. Tensile properties of selective laser melted 316L stainless steel[J]. Acta Metallurgica Sinica, 56, 683-692(2020).

[31] Tan C L, Zhou K S, Kuang M et al. Microstructural characterization and properties of selective laser melted maraging steel with different build directions[J]. Science and Technology of Advanced Materials, 19, 746-758(2018).

[32] Tan C L[D]. Selective laser melting of maraging steel and its composite, gradient materials(2019).

[33] Bai Y C, Wang D, Yang Y Q et al. Effect of heat treatment on the microstructure and mechanical properties of maraging steel by selective laser melting[J]. Materials Science and Engineering: A, 760, 105-117(2019).

[34] Yin S, Chen C Y, Yan X C et al. The influence of aging temperature and aging time on the mechanical and tribological properties of selective laser melted maraging 18Ni-300 steel[J]. Additive Manufacturing, 22, 592-600(2018).

[35] Kempen K, Yasa E, Thijs L et al. Microstructure and mechanical properties of selective laser melted 18Ni-300 steel[J]. Physics Procedia, 12, 255-263(2011).

[36] Liu Y F, Tang M K, Hu Q et al. Densification behavior, microstructural evolution, and mechanical properties of TiC/AISI420 stainless steel composites fabricated by selective laser melting[J]. Materials & Design, 187, 108381(2020).

[37] Dehgahi S, Ghoncheh M H, Hadadzadeh A et al. The role of titanium on the microstructure and mechanical properties of additively manufactured C300 maraging steels[J]. Materials & Design, 194, 108965(2020).

[38] Li K, Wei L, An B et al. Aging phenomenon in low lattice-misfit cobalt-free maraging steel: Microstructural evolution and strengthening behavior[J]. Materials Science and Engineering: A, 739, 445-454(2019).

[39] Shamsdini S, Shakerin S, Hadadzadeh A et al. A trade-off between powder layer thickness and mechanical properties in additively manufactured maraging steels[J]. Materials Science and Engineering: A, 776, 139041(2020).

[40] Alam M K, Mehdi M, Urbanic R J et al. Mechanical behavior of additive manufactured AISI 420 martensitic stainless steel[J]. Materials Science and Engineering: A, 773, 138815(2020).

[41] Yao Y Z, Huang Y H, Chen B et al. Influence of processing parameters and heat treatment on the mechanical properties of 18Ni300 manufactured by laser based directed energy deposition[J]. Optics & Laser Technology, 105, 171-179(2018).

[42] Yang K, Qu W S, Kong F Y et al. Effects of solution treatment temperature on grain growth and mechanical properties of high strength 18%Ni cobalt free maraging steel[J]. Materials Science and Technology, 19, 117-124(2003).

[43] Campanelli S L, Contuzzi N, Ludovico A D. Manufacturing of 18 Ni marage 300 steel samples by selective laser melting[J]. Advanced Materials Research, 83/84/85/86, 850-857(2009).

[44] Casalino G, Campanelli S L, Contuzzi N et al. Experimental investigation and statistical optimisation of the selective laser melting process of a maraging steel[J]. Optics & Laser Technology, 65, 151-158(2015).

[45] Hermann Becker T, Dimitrov D. The achievable mechanical properties of SLM produced maraging steel 300 components[J]. Rapid Prototyping Journal, 22, 487-494(2016).

[46] Casati R, Lemke J, Tuissi A et al. Aging behaviour and mechanical performance of 18-Ni 300 steel processed by selective laser melting[J]. Metals, 6, 218(2016).

[47] Zhou Y Y, Wang F, Xue C. Microstructure and mechanical properties of 3D printing 18Ni300 die steel[J]. Physical Testing and Chemical Analysis (Part A: Physical Testing), 52, 243-246(2016).

[48] Tan C L, Zhou K S, Ma W Y et al. Interfacial characteristic and mechanical performance of maraging steel-copper functional bimetal produced by selective laser melting based hybrid manufacture[J]. Materials & Design, 155, 77-85(2018).

[49] Kučerová L, Zetková I, Jandová A et al. Microstructural characterisation and in situ straining of additive-manufactured X3NiCoMoTi 18-9-5 maraging steel[J]. Materials Science and Engineering: A, 750, 70-80(2019).

[50] Lee J, Choe J, Park J et al. Microstructural effects on the tensile and fracture behavior of selective laser melted H13 tool steel under varying conditions[J]. Materials Characterization, 155, 109817(2019).

[51] Damon J, Hanemann T, Dietrich S et al. Orientation dependent fatigue performance and mechanisms of selective laser melted maraging steel X3NiCoMoTi18-9-5[J]. International Journal of Fatigue, 127, 395-402(2019).

[52] Li J N, Wang X L, Qi W J et al. Laser nanocomposites-reinforcing/manufacturing of SLM 18Ni300 alloy under aging treatment[J]. Materials Characterization, 153, 69-78(2019).

[53] Li S L, Liu M M, Ren Y et al. Hydrogen embrittlement behaviors of additive manufactured maraging steel investigated by in situ high-energy X-ray diffraction[J]. Materials Science and Engineering: A, 766, 138341(2019).

[54] Mooney B, Kourousis K I, Raghavendra R et al. Process phenomena influencing the tensile and anisotropic characteristics of additively manufactured maraging steel[J]. Materials Science and Engineering: A, 745, 115-125(2019).

[55] Bai Y C, Zhao C L, Zhang Y et al. Microstructure and mechanical properties of additively manufactured multi-material component with maraging steel on CrMn steel[J]. Materials Science and Engineering: A, 802, 140630(2021).

[56] Zhao X, Dong S Y, Yan S X et al. The effect of different scanning strategies on microstructural evolution to 24CrNiMo alloy steel during direct laser deposition[J]. Materials Science and Engineering: A, 771, 138557(2020).

[57] Shamsdini S, Ghoncheh M H, Sanjari M et al. Plastic deformation throughout strain-induced phase transformation in additively manufactured maraging steels[J]. Materials & Design, 198, 109289(2021).

[58] Tan C L, Chew Y, Duan R X et al. Additive manufacturing of multi-scale heterostructured high-strength steels[J]. Materials Research Letters, 9, 291-299(2021).

[59] Tan C L, Chew Y, Weng F et al. Superior strength-ductility in laser aided additive manufactured high-strength steel by combination of intrinsic tempering and heat treatment[J]. Virtual and Physical Prototyping, 16, 460-480(2021).

[60] Shakerin S, Hadadzadeh A, Amirkhiz B S et al. Additive manufacturing of maraging steel-H13 bimetals using laser powder bed fusion technique[J]. Additive Manufacturing, 29, 100797(2019).

[61] Kučerová L, Zetková I, Jeníček Š et al. Hybrid parts produced by deposition of 18Ni300 maraging steel via selective laser melting on forged and heat treated advanced high strength steel[J]. Additive Manufacturing, 32, 101108(2020).

[62] Azizi H, Ghiaasiaan R, Prager R et al. Metallurgical and mechanical assessment of hybrid additively-manufactured maraging tool steels via selective laser melting[J]. Additive Manufacturing, 27, 389-397(2019).

[63] Kang N, Ma W Y, Heraud L et al. Selective laser melting of tungsten carbide reinforced maraging steel composite[J]. Additive Manufacturing, 22, 104-110(2018).

[64] Oter Z C, Coskun M, Akca Y et al. Benefits of laser beam based additive manufacturing in die production[J]. Optik, 176, 175-184(2019).

[65] Bai Y C, Yang Y Q, Xiao Z F et al. Selective laser melting of maraging steel: mechanical properties development and its application in mold[J]. Rapid Prototyping Journal, 24, 623-629(2018).

[66] Huang Y S[D]. The design and property of conformal cooling channels fabricated by selective laser melting(2018).

[67] Zhang W, Yao J H, Dong C H et al. Repairing and strengthening of eroded turbine blades by laser technology[J]. Journal of Power Engineering, 28, 967-971(2008).

[68] Shu Z F, Huang C P, Lin X et al. Research progress and prospect of laser additive manufacturing of steel[J]. Journal of Netshape Forming Engineering, 11, 81-88(2019).

[69] Huang Y L, Zhu P, Meng Q B. Research on repair technology of 2Cr13 blade by stellite alloy laser additive manufacturer[J]. Electric Welding Machine, 49, 84-87(2019).

[70] Gou W J, Hu W, Wang L H. Repairing welding technology of turbine blade of martensitic stainless steel[J]. Electric Welding Machine, 46, 79-82(2016).

[71] Wang H, Chai L J, Zhao K et al. Microstructure and property of Al2O3 and Al2O3/FeCrNi coating prepared on ferritic/martensitic steel by pulsed laser cladding[J]. Atomic Energy Science and Technology, 55, 249-255(2021).

[72] Zhu H M, Hu J P, Li B C et al. Research progress of laser cladding stainless steel coating on Fe-based substrate[J]. Surface Technology, 49, 74-84(2020).

[73] Alam M K, Edrisy A, Urbanic J et al. Microhardness and stress analysis of laser-cladded AISI 420 martensitic stainless steel[J]. Journal of Materials Engineering and Performance, 26, 1076-1084(2017).

[74] Huang Z L, Wang G, Wei S P et al. Process improvement in laser hot wire cladding for martensitic stainless steel based on the Taguchi method[J]. Frontiers of Mechanical Engineering, 11, 242-249(2016).

[75] Guo W M, Li X Q, Ding N et al. Microstructure characteristics and mechanical properties of a laser cladded Fe-based martensitic stainless steel coating[J]. Surface and Coatings Technology, 408, 126795(2021).

[76] Li B C, Zhu H M, Qiu C J et al. Development of high strength and ductile martensitic stainless steel coatings with Nb addition fabricated by laser cladding[J]. Journal of Alloys and Compounds, 832, 154985(2020).

[77] Wu B D, Liu X, Li J F et al. Tungsten-chromium coatings on reduced activation ferritic/martensitic steels prepared by laser melting deposition process[J]. Journal of Nuclear Materials, 543, 152573(2021).