(一) 金属增材制造
1) X.Z. Li, X.W. Fang, M.G. Zhang, H.K. Zhang,Y.S. Duan, K. Huang*. Gradient microstructure and prominent performance of wire-arc directed energy deposited magnesium alloy via laser shock peening. Int J Mach Tools Manuf, 188(2023) 104029
2) X.Z. Li, X.W. Fang, X. Jiang, Y.S. Duan, Y. Li, H.K. Zhang, X.P. Li, K. Huang*. Additively manufactured high-performance AZ91D magnesium alloys with excellent strength and ductility via nanoparticles reinforcement. Addit Manuf, 69(2023) 103550
3) X.Z. Li, M.G. Zhang, X.W. Fang, Z.X. Li, G.H. Jiao. K. Huang*. Improved strength-ductility synergy of directed energy deposited AZ31 magnesium alloy with cryogenic cooling mode. Virtual Phys Prototyp, 18(2023) e2170252
4) T. Chang, X. Fang, G. Liu, H. Zhang, K. Huang*, Wire and arc additive manufacturing of dissimilar 2319 and 5B06 aluminum. Journal of Materials Science & Technology 124(2022)65-75
5) N. Xi, K. Tang, X. Fang, Y. Li, Y. Duan, K. Huang*. Enhanced comprehensive properties of directed energy deposited Inconel 718 by a novel integrated deposition strategy. Journal of Materials Science & Technology, 141(2023)42-55 (ESI 高被引论文)
6) X. Fang, C. Ren, L. Zhang, C. Wang, K. Huang*, B. Lu*. A model of bead size based on the dynamic response of CMT-based wire and arc additive manufacturing process parameters. Rapid Prototyping Journal. 27(2021) 741-753
7) X.W. Fang, H. Li, X.G.Li, K. Huang*, L.J. Zhang*, B.H. Lu. Effect of post heat treatment on the microstructure and mechanical properties of wire-arc additively manufactured A357 alloy components. Mater Lett 269(2020)127674
8) X.W. Fang, L.J. Zhang, G.P. Chen, K. Huang*, F. Xue, L. Wang, J.Y. Zhao, B.H. Lu*. Microstructure evolution of wire-arc additively manufactured 2319 aluminum alloy with interlayer hammering. Mater Sci Eng A 800(2021)140168
9) Z. Chen, P. Wei, S.Z. Zhang, B.H. Lu*, L.J. Zhang*, X.G. Yang, K. Huang, Y. Z.Huang, X.P. Li, Q. L. Zhao. Graphene reinforced nickel-based superalloy composites fabricated by additive manufacturing. Mater Sci Eng A 769(2020)138484
10) X.W. Fang, L.J. Zhang, J.N. Yang, H. Bai, L. Zhao, K. Huang*, B.H. Lu*. Effect of characteristic substrate parameters on the deposition geometry of CMT additive manufactured Al-6.3%Cu alloy. Appl Therm Eng 162(2019) 114302
11) X. Fang, G. Chen, J. Yang, Y. Xie, K. Huang*, B. Lu. Wire and arc additive manufacturing of high strength Al-Zn-Mg aluminum alloy. Frontiers in Materials 8(2021) 656429
12) A. K. Sahu, S. Bag, Ke Huang. Mitigation of micro-cracks in dissimilar welding of Inconel 718 and austenitic stainless steel. Philo Mag Lett 100(2020)365-374
13) 黄科,方学伟,卢秉恒. 《锻压手册》第四版 第一卷 锻造,《增材制造》章节,2020年,机械工业出版社。
14) X. Fang, J. Yang, S.Wang, C. Wang, K. Huang*, H. Li, B. Lu. Additive manufacturing of high performance AZ31 magnesium alloy with full equiaxed grains: Microstructure, mechanical property, and electromechanical corrosion performance. J. Mater. Process. Technol 300(2022)117430
15) N. Xi, X. Fang, Y. Duan, Q. Zhang, K. Huang*, Wire arc additive manufacturing of Inconel 718: Constitutive modelling and its microstructure basis,Journal of Manufacturing Processes 75(2022)1134-1143
16) M. Zhang, X. Fang, Y. Wang, X. Jiang, T. Chang, N. Xi, K. Huang*, High superelasticity NiTi fabricated by cold metal transfer based wire arc additive manufacturing. Mater Sci Eng A 840 (2022) 143001
17)X.W. Fang, L.J. Zhang, G.P. Chen, X.F. Dang, K. Huang, L. Wang, B.H. Lu*. Correlations between microstructure characteristics and mechanicalproperties in 5183 aluminium alloy fabricated by wire-arc additivemanufacturing with different arc modes. Materials 11(2018) 207
18) 李新志,方学伟,常天行,冯成慧,黄科*. 选区激光熔化精密成形轻质镁合金的研究进展。精密成形工程.14(2022)78-93
19) X. Li, X. Fang, S. Wang, S. Wang, M. Zha, K. Huang*. Selective laser melted AZ91D magnesium alloy with superior balance of strength and ductility, Journal of Magnesium and Alloys, 2022 https://doi.org/10.1016/j.jma.2022.06.004
20) M. Zhang, Y. Duan, X. Fang*, H. Zhang, G. Jiao, Y. Li, K. Huang*, Tailoring the superelasticity of NiTi alloy fabricated by directed energy deposition through the variation of residual stress. Mater Des 224(2022)111311
21) Y.D. Jing, X.W. Fang, N.Y. Xi, X.L. Feng, K. Huang*. Investigation of microstructure and mechanical properties evolution in 7050 aluminum alloy and 316L stainless steel treated by laser shock peening. Mater Charact 182(2021)111571
22) Y.D. Jing, X.W. Fang, N.Y. Xi, T.X. Chang, Y.S. Duan, K. Huang*. Improved tensile strength and fatigue properties of wire-arc additively manufactured 2319 aluminum alloy by surface laser shock peening. Mater Sci Eng A 2023(864)144599
23) X.W. Fang, L.J. Zhang*, H. Li, C. Li, K. Huang, B.H. Lu. Microstructure evolution and mechanical behavior of 2219 aluminum alloys additively fabricated by cold metal transfer process. Materials 11(2018) 812
24) K. Huang*, T.X. Chang, Y.D. Jing, X.W. Fang, B.H. Lu. Additive Manufacturing of Magnesium Alloys. In "Additive and Subtractive Manufacturing", J. Paulo Davim (ed), De Gruyter, 2019. (Book Chapter)
25) G.H. Jiao, X.W. Fang, X.M. Chen*, N.Y. Xi, M. G. Zhang, Y. Liu, H.Y. Wu, K. Huang*. The origin of low thermal expansion coefficient and enhanced tensile properties of Invar alloy fabricated by Directed Energy Deposition. J Mater Process Technol, 317(2023) 117994
26) N. Kalentics*, K. Huang*, M. Ortega Varela de Seijas, A. Burn, V. Romano, R.E.Logé. Laser shock peening: a promising tool for tailoring metallic microstructures in selective laser melting. J. Mater. Process. Technol 266(2019)612-618
27) T.X. Chang, H.K. Zhang, X.W. Fang, Y.D. Jing, N.Y. Xi, K. Huang*. Tailoring precipitation of directed energy deposited Al-Cu alloy via laser shock peening. Addit Manuf, 73(2023) 103652
28)N. Xi, Z. Ni, X.W. Fang, Y. Zhou, K. Tang, H.K. Zhang, K. Huang*. Role of δ-phase on Mechanical Behaviors of Additive Manufactured Inconel 718: Detailed Microstructure Analysis and Crystal Plasticity Modelling. Int J Plasticity, 168(2023)103708
29) X.Z. Li, X.W. Fang, D.Q. Fang, W. Fu, X.R. Zhang, X.P. Li, K. Huang*. On the excellent strength-ductility synergy of wire-arc directed energy deposited Mg-Gd-Y-Zn-Zr alloy via manipulating precipitates. Addit Manuf, 69(2023) 103550 77(2023)103794
30) Y.D. Jing, X.W. Fang, Y.L. Geng, Y.S. Duan, K. Huang*. Simultaneous strength and ductility enhancement of wire-arc directed energy deposited Al–Cu alloy by interlayer laser shock peening. Mater Sci Eng A. 887(2023) 145699
31) Y. Zhou, T.X. Chang, X.W. Fang*, Y.K. Chen, Y.F. Li, K. Huang*. Tailoring the mechanical properties and thermal stability of additive manufactured micro-alloyed Al-Cu alloy via multi-stage heat treatment. Mater Des 233(2023)112287
32) X.W. Fang, J.N. Yang, X. Jiang, X.Z. Li, R.K. Chen, K. Huang*. Wire-arc directed energy deposited high-performance AZ31 magnesium alloy via a novel interlayer hammering treatment. Mater Sci Eng A. 889(2024) 145864
33) Y. Liu, X. Fang, X. Li, K. Huang*. The optimization of residual stress in arc bridge Hastelloy X components fabricated by Laser Powder Bed Fusion. Int J Adv Manuf Technol 129(2023) 4457–4471.
34) Z. Wu, S. Wu*, Y. Duan, K. Huang*, W. He, D. Du, A. Dong*. In situ X-ray tomography of fracture behaviour in low-porosity L-PBF AlSi10Mg alloy with laser shock peening. Virtual Phys Prototy. 18(2023)e2273955
35) X.Z. Li, X.W. Fang, M.G. Zhang, B.L. Wang, K. Huang*. Enhanced strength-ductility synergy of magnesium alloy fabricated by ultrasound assisted directed energy deposition. J Mater Sci & Technol 178C (2024) 247-261
36) M. Zhang, B.Wang, X. Li, G. Jiao, X. Fang, K. Huang*. Grain refinement of NiTi alloys during ultrasound-assisted wire-arc directed energy deposition. Virtual Phys Prototy. 19(2024)ee2289465
(二)金属热变形
1) K. Huang*, R.E. Logé. A review of different dynamic recrystallization phenomena in metallic materials. Mater & Design 111 (2016) 548-574 (ESI 高被引文章)
2) K. Huang*, R.E. Logé. Microstructure and flow stress evolution during hot deformation of 304L stainless steel in variable conditions. Mater Sci Eng A 711(2018) 600-610
3) H.K. Zhang, H. Xiao, X.W. Fang, Q. Zhang, R.E. Logé, K. Huang*. A critical assessment of experimental investigation of dynamic recrystallization of metallic materials Mater & Design 193 (2020) 108873
4) K. Huang*. Editor.《Recrystallization: Types, Techniques and Applications》. 2020, Nova Publisher (Book)
5) O. Beltran, K. Huang*, R.E. Logé. A mean field model of dynamic and post-dynamic recrystallization predicting kinetics, grain size and flow stress. Comp. Mater. Sci 102 (2015) 293-303
6) P. Bernard, S. Bag, K.Huang, R.E.Logé*.A two-site mean field model of discontinuous dynamic recrystallization. Mater Sci Eng A 528(2011) 7357-7367
7)K. H. Wang, G. Liu*, W. Tao, J. Zhao, K. Huang. Study on the mixed dynamic recrystallization mechanism during the globularization process of laser -welded TA15 Ti-alloy joint under hot tensile deformation. Mater Charact 126 (2017) 57-63
8)K. Wang, G. Liu*, K. Huang, D.J. Politis, L. Wang. Effect of recrystalllization on hot deformation mechanism of TA15 titanium alloy under uniaxial tension and biaxial gas bulging conditions. Mater Sci Eng A 708(2017)149-158
9) K. Wang, G. Liu*, J. Zhao, K. Huang, L. Wang. Experimental and modelling study of an approach to enhace gas bulging formability of TA15 titanium alloy tube based on dynamic recrystallization. J. Mater. Process. Technol 259(2018)387-396
10)J. Zhao, K. Wang, K. Huang, G. Liu*. Recrystallization behavior during hot tensile deformation of TA15 titanium alloy sheet with substantial prior deformed substructures. Mater Charact 151(2019)429-435
11) M. Cao*, Q. Zhang, K. Huang, X. Wang, B. Chang, L. Cai. Microstructural evolution and deformation behavior of copper alloy during rheoforging process. Journal of Materials Science & Technology 42(2020)17-27
12) H. Li, M. Cao, L.Q. Niu, K. Huang, Q. Zhang*. Establishment of macro-micro constitutive model and deformation mechanism of semi-solid Al6061. J. Alloy. Compd 854 (2020) 157124
13)张宏凯,李岩,肖豪,黄科*,金属热变形微观组织精密控制的研究进展。精密成形工程 12(2020)49-59
14) M. Cao*, Q. Zhang, K. Huang, X. Wang, B. Chang, L. Cai. Microstructural evolution and deformation behavior of copper alloy during rheoforging process. Journal of Materials Science & Technology 42(2020)17-27
15) L. Niu, Q. Zhang, Y. Ma,Y.Chen,B. Han, K.Huang. A ductile fracture criterion under warm-working conditions based on the multiscale model combining molecular dynamics with finite element methods. International Journalof Plasticity. 149(2022) 103185
16)H. Zhang, Y. Li, T. Ma, T. Chang, P. Zhang, X. Fang, K. Huang*. Tailoring of nanoscale γ′ precipitates and unveiling their strengthening mechanisms in multimodal nickel-based superalloy GH4720Li. Mater Charact 188(2022)111918
17) H. Zhang, Y. Li, H. Ma, P. Zhang, T. Ma, K. Huang*. A novel short-process manufacturing method of γ′-strengthened superalloy: Modulation of nano-scaled γ′ precipitates during hot deformation. Mater Sci Eng A 846(2022)143257
18) H. Zhang, H. Ma, T. Chang, Y. Zhang, R.E. Logé, Q. Zhang, X. Fang, K. Huang*. Deformation mechanisms of primary γ′ precipitates in nickel-based superalloy. Scr Mater 224(2023)115109
(三)金属组织性能调控
1) K. Huang*, K. Marthinsen, Q. Zhao, R.E. Logé. The double-edge effect of second-phase particles on the recrystallization behaviour and associated mechanical properties of metallic materials. Prog. Mater. Sci 92(2018) 284-359 (影响因子:23.7, ESI 高被引论文)
2) K. Huang*, K. Zhang , K. Marthinsen, R.E. Logé. Controlling grain structure and texture in Al-Mn alloy from the competition between precipitation and recrystallization. Acta Mater 141(2017) 360-373 (影响因子:7.3)
3) K. Huang*, R.E. Logé, K. Marthinsen. On the sluggish recrystallization of cold-rolled Al-Mn-Fe-Si alloy. J. Mater. Sci 51 (2016) 1632-1643
4) K. Huang*, O. Engler, Y.J. Li, K. Marthinsen. Evolution in microstructure and properties during non-isothermal of a cold-rolled Al-Mn-Fe-Si alloy with different microchemistries. Mater. Sci. Eng A 628(2015) 216-229
5) K. Huang*, Y.J. Li, K. Marthinsen. Factors affecting the strength of P texture during annealing of cold-rolled Al-Mn-Fe-Si alloy. J. Mater. Sci 50 (2015) 5091-5103
6) K. Huang*, Y.J. Li, K. Marthinsen. Two-stage annealing of a cold rolled Al-Mn-Fe-Si alloy with different microchemistry states. J. Mater. Process. Technol 221 (2015) 87-99
7) K. Huang*, K. Marthinsen. The effect of heating rate on the softening behaviour of a deformed Al-Mn alloy with strong and weak concurrent precipitation. Mater. Charact 110 (2015) 215-221
8) K. Huang*, Y.J. Li, K. Marthinsen. Effect of heterogeneously distributed pre-existing dispersoids on the recrystallization behavior of Al-Mn-Fe-Si alloy. Mater. Charact 102 (2015) 92-97
9) K. Huang*, N. Wang, Y.J. Li, K. Marthinsen. The influence of microchemistry on the softening behavior of two cold-rolled Al-Mn-Fe-Si alloys. Mater. Sci. Eng. A 601 (2014) 86-96
10) X.W. Fang, H. Xiao, K. Marthinsen, A. Belyakov, X.Y. Fang, K. Huang*, Tailoring microstructure and texture of annealed Al-Mn alloy through the variation of homogenization and prior cold deformation strain. Mater Charct 166(2020)110438
11) K. Huang*, Y.J. Li, K. Marthinsen. Isothermal annealing of a cold-rolled Al-Mn-Fe-Si alloy with different microchemistry states.Trans. Nonferous Met. Soc. China 24(2014) 3840-3847
12) Q.L. Zhao*, H.D. Zhang, K.Huang*, K. Marthinsen. Correlating orientated grain number density of recrystallization in particle-containing aluminium alloys. Trans. Nonferrous Met. Soc. China 28(2018)220-225
14) Q. L. Zhao*, K. Huang, Y.J. Li, K. Marthinsen. Orientation preference of recrystallization in supersaturated aluminum alloys influenced by concurrent precipitation. Metall. Mater. Trans. A 47A(2016) 1378-1388
15) K. Huang, R.E. Logé. Zener Pinning. In “Reference Module in Materials Science Engineering”, S. Hashmi (ed), Elsevier, 2016. (Book Chapter)
(创新港)
