[1] 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).

[2] Wei H L, Mukherjee T, Zhang W et al. Mechanistic models for additive manufacturing of metallic components[J]. Progress in Materials Science, 116, 100703(2021).

[3] Wei H L, Liu F Q, Wei L et al. Multiscale and multiphysics explorations of the transient deposition processes and additive characteristics during laser 3D printing[J]. Journal of Materials Science & Technology, 77, 196-208(2021).

[4] Wei H L, Cao Y, Liao W H et al. Mechanisms on inter-track void formation and phase transformation during laser powder bed fusion of Ti-6Al-4V[J]. Additive Manufacturing, 34, 101221(2020).

[5] DebRoy T, Mukherjee T, Wei H L et al. Metallurgy, mechanistic models and machine learning in metal printing[J]. Nature Reviews Materials, 6, 48-68(2021).

[6] Bartlett J L, Li X D. An overview of residual stresses in metal powder bed fusion[J]. Additive Manufacturing, 27, 131-149(2019).

[7] Cao Y, Wei H L, Yang T et al. Printability assessment with porosity and solidification cracking susceptibilities for a high strength aluminum alloy during laser powder bed fusion[J]. Additive Manufacturing, 46, 102103(2021).

[8] Strantza M, Ganeriwala R K, Clausen B et al. Coupled experimental and computational study of residual stresses in additively manufactured Ti-6Al-4V components[J]. Materials Letters, 231, 221-224(2018).

[9] Mukherjee T, Zhang W, DebRoy T. An improved prediction of residual stresses and distortion in additive manufacturing[J]. Computational Materials Science, 126, 360-372(2017).

[10] Zhang T H, Wang Y, Fang X F et al. Research status and development of residual stress detection and elimination methods[J]. Journal of Netshape Forming Engineering, 9, 122-127(2017).

[11] Xu X Y, Lü Y T, Zhang D et al. Measuring residual stress by neutron diffraction[J]. Materials Review, 29, 117-122(2015).

[12] Machirori T, Liu F Q, Yin Q Y et al. Spatiotemporal variations of residual stresses during multi-track and multi-layer deposition for laser powder bed fusion of Ti-6Al-4V[J]. Computational Materials Science, 195, 110462(2021).

[13] Cheng B, Shrestha S, Chou K. Stress and deformation evaluations of scanning strategy effect in selective laser melting[J]. Additive Manufacturing, 12, 240-251(2016).

[14] Wu Y, Ma P Z, Bai W Q et al. Numerical simulation of temperature field and stress field in 316L/AISI304 laser cladding with different scanning strategies[J]. Chinese Journal of Lasers, 48, 2202002(2021).

[15] Yang G, Li Y H, Zhou S Y et al. Thermal-mechanical coupling of regional scanning based on characteristic regions in laser additive manufacturing[J]. Chinese Journal of Lasers, 48, 1002115(2021).

[16] Chen D N, Liu T T, Liao W H et al. Temperature field during selective laser melting of metal powder under different scanning strategies[J]. Chinese Journal of Lasers, 43, 0403003(2016).

[17] Fan P, Pan J T, Ge Y M et al. Finite element analysis of residual stress in TC4/TC11 titanium alloy gradient material produced by laser additive manufacturing[J]. Chinese Journal of Lasers, 48, 1802012(2021).

[18] Ding J, Colegrove P, Mehnen J et al. Thermo-mechanical analysis of wire and arc additive layer manufacturing process on large multi-layer parts[J]. Computational Materials Science, 50, 3315-3322(2011).

[19] Tang Q, Chen P, Chen J Q et al. Numerical simulation of welding deformation in laser hybrid welding based on SYSWELD[J]. Transactions of the China Welding Institution, 40(2019).

[20] Ren S, Li C J, Li L et al. Study on deformation simulation of hull welding based on inherent strain method[J]. Ship Engineering, 37, 84-88(2015).

[21] Ni C Y, Zhang C D, Liu T T et al. Deformation prediction of metal selective laser melting based on inherent strain method[J]. Chinese Journal of Lasers, 45, 0702004(2018).

[22] Chen C P, Lei Y, Chen B Q et al. Numerical simulation of deformation of typical parts in selective laser melting additive manufacturing[J]. Applied Laser, 41, 814-821(2021).

[23] Liang X, Cheng L, Chen Q et al. A modified method for estimating inherent strains from detailed process simulation for fast residual distortion prediction of single-walled structures fabricated by directed energy deposition[J]. Additive Manufacturing, 23, 471-486(2018).

[24] Chen Q, Liang X, Hayduke D et al. An inherent strain based multiscale modeling framework for simulating part-scale residual deformation for direct metal laser sintering[J]. Additive Manufacturing, 28, 406-418(2019).

[25] Liang X, Dong W, Chen Q et al. On incorporating scanning strategy effects into the modified inherent strain modeling framework for laser powder bed fusion[J]. Additive Manufacturing, 37, 101648(2021).

[26] Tran H T, Liang X, To A C. Efficient prediction of cracking at solid-lattice support interface during laser powder bed fusion via global-local J-integral analysis based on modified inherent strain method and lattice support homogenization[J]. Additive Manufacturing, 36, 101590(2020).

[27] Liang X, Chen Q, Cheng L et al. Modified inherent strain method for efficient prediction of residual deformation in direct metal laser sintered components[J]. Computational Mechanics, 64, 1719-1733(2019).

[28] Foroozmehr A, Badrossamay M, Foroozmehr E et al. Finite element simulation of selective laser melting process considering optical penetration depth of laser in powder bed[J]. Materials & Design, 89, 255-263(2016).

[29] Gu D D, He B B. Finite element simulation and experimental investigation of residual stresses in selective laser melted Ti-Ni shape memory alloy[J]. Computational Materials Science, 117, 221-232(2016).

[30] Shan X Y, Tan M J, O’Dowd N P. Developing a realistic FE analysis method for the welding of a NET single-bead-on-plate test specimen[J]. Journal of Materials Processing Technology, 192/193, 497-503(2007).

[31] Hussein A, Hao L, Yan C Z et al. Finite element simulation of the temperature and stress fields in single layers built without-support in selective laser melting[J]. Materials & Design, 52, 638-647(2013).

[32] Wang J H, Lu H, Wei L W. Prediction of welding distortions based on theory of inherent strain by FEM and its application[J]. Transactions of the China Welding Institution, 23(2002).

[33] Deng D A, Murakawa H, Liang W. Numerical simulation of welding distortion in large structures[J]. Computer Methods in Applied Mechanics and Engineering, 196, 4613-4627(2007).

[34] Yuan M G, Ueda Y. Prediction of residual stresses in welded T- and I-joints using inherent strains[J]. Journal of Engineering Materials and Technology, 118, 229-234(1996).

[35] Liang X, Dong W, Hinnebusch S et al. Inherent strain homogenization for fast residual deformation simulation of thin-walled lattice support structures built by laser powder bed fusion additive manufacturing[J]. Additive Manufacturing, 32, 101091(2020).

[36] Siewert M, Neugebauer F, Epp J et al. Validation of Mechanical Layer Equivalent Method for simulation of residual stresses in additive manufactured components[J]. Computers & Mathematics With Applications, 78, 2407-2416(2019).

[37] Wang Y X, Zhang P, Hou Z G et al. Inherent strain method and thermal elastic-plastic analysis of welding deformation of a thin-wall beam[J]. Journal of Mechanics, 24, 301-309(2008).

[38] Dong W, Liang X, Chen Q et al. A new procedure for implementing the modified inherent strain method with improved accuracy in predicting both residual stress and deformation for laser powder bed fusion[J]. Additive Manufacturing, 47, 102345(2021).

[39] Setien I, Chiumenti M, van der Veen S et al. Empirical methodology to determine inherent strains in additive manufacturing[J]. Computers & Mathematics With Applications, 78, 2282-2295(2019).

[40] Strantza M, Ganeriwala R K, Clausen B et al. Effect of the scanning strategy on the formation of residual stresses in additively manufactured Ti-6Al-4V[J]. Additive Manufacturing, 45, 102003(2021).