论文著作情况：

   至今，发表SCI论文200余篇，其中以一作和通讯发表150余篇（Nat. Commun.、Corros. Sci.、J. Mater. Sci. Technol.、Int. J. Plast.、Int. J. Heat Mass Tran.、Metall. Mater. Trans. B、ISIJ Int.、Steel Res. Int.、Mater. Sci. Eng., A、Metall. Mater. Trans. A、J. Alloys Compd.、Mater. Charact.等期刊）；《高氮不锈钢》等著作5部；授权发明专利70余项（美国专利2项）。

代表性论著：

（1）S.C. Zhang, H. Feng, H.B. Li*,   et al. Design for improving corrosion resistance of duplex stainless steels   by wrapping inclusions with niobium armour, Nature Communications,   2023, 14: 7869.

（2）Z.W.   Ni, H.C. Zhu*, H.B. Li*,   et al. Elucidating the promoting mechanism of nitrogen in the   columnar-to-equiaxed transition of steel ingot, International Journal   of Heat and Mass Transfer, 2024, 220: 125014.

（3）J. Dai, H.   Feng,H.B. Li*, et al. Insights   into the mechanism of Mo protecting CoCrFeNi HEA from pitting corrosion—A   quantitative modelling study on passivation and repassivation processes, Journal   of Materials Science & Technology, 2024, 182: 152–164.

（4）Y.M. Zhang, Y.X.   Hu, H.B. Li*, et al. Martensitic transformation induced planar   deformation of AlN nanoprecipitates in high nitrogen stainless steels, International   Journal of Plasticity, 2023, 166: 103631.

（5）H. Feng, H.B.   Li*, J.D. Qu, et al. Unveiling the significant contribution of matrix   elements to passivation behaviour and corrosion resistance of alloys by   modelling approach, Corrosion Science, 2023, 214, 111014.

（6）L.F. Xia, H.B.   Li*, H. Feng, et al. Enhanced strength and toughness of high nitrogen   stainless bearing steel by controlling interstitial partitioning via   V-microalloying, Journal of Materials Science & Technology,   2023, 151: 204–218.

（7）H.B. Li*, Y. Han, H.   Feng, et al. Enhanced strength-ductility synergy via high dislocation   density-induced strain hardening in nitrogen interstitial CrMnFeCoNi   high-entropy alloy, Journal of Materials Science & Technology,   2023, 141: 184–192.

（8）C.T. Yang, H. Feng, X.B. Chen, Y.   Han, H.B. Li*, et al. Enhanced pitting corrosion resistance of   CoCrFeMnNi high entropy alloy in the presence of Desulfovibrio vulgaris via   nitrogen doping, Journal of Materials Science & Technology,   2023, 139: 92–102.

（9）H. Feng, Y. Han, H.B. Li*, et   al. Enhancement in impact toughness of CoCrFeMnNi high-entropy alloy via nitrogen   addition, Journal of Alloys and Compounds, 2023, 932:167615.

（10）Z.Y. He, H.B. Li*, H.C. Zhu,   et al. Investigation on Porosity Formation With Pressure Drop Between   Dendrite Tip and Root During Pressurized Solidification of 30Cr15Mo1N Ingot,Metallurgical and Materials   Transactions B, 2023, 54(6): 3155–3163.

（11）H.B. Li*, Z.W. Ni, H.C. Zhu, et al.   Elimination mechanism of shrinkage porosity during pressurized solidification   process of 19Cr14Mn4Mo1N high-nitrogen steel ingot, Metallurgical and   Materials Transactions B, 2023, 54(3): 1422–1433.

（12）X.Z. Li, H.B. Li*, H. Feng,   et al. Nitrogen Solubility in Molten Ni, Ni-Cr, Ni-Mo and Ni-Cr-Mo Alloys   under Pressurized Atmosphere, Metallurgical and Materials Transactions   B, 2023, 54(1): 203–212.

（13）Z.Y. He, H.B. Li*, H.C. Zhu,   et al. Evolution of Precipitated Phase and Dendritic Structure Around   Nitrogen Pore in 30Cr15Mo1N Ingot, Metallurgical and Materials   Transactions B, 2023, 54(1): 213–220.

（14）H.B. Li*, P.C. Lu,   H. Feng, et al. Influence Mechanism of Crucible Materials on Cleanliness and   Inclusion Characteristics of High-Nitrogen Stainless Bearing Steel During   Vacuum Carbon Deoxidation, Metallurgical and Materials Transactions B,   2023, 54(3): 1099–1112.

（15）S.X. Yang, H.B.   Li*, H. Feng, et al. Effects of Atmosphere and Na2O in Slag on   Inclusion Characteristics of Al-Killed Fe–18Cr–18Mn Remelted by (P)ESR   Process,Metallurgical   and Materials Transactions B, 2023, 54(4): 2229–2243.

（16）H.B. Li*, W.C. Jiao,   H. Feng, et al. Roles of N-Alloying and austenitizing temperature in tuning   the hardness and strengthening–toughening behavior of M42 high-speed steel, Metallurgical   and Materials Transactions A, 2023, 54(6): 2451–2469.

（17）H. Feng, H.B. Li*, J. Dai, et   al. Why CoCrFeMnNi HEA could not passivate in chloride solution? – A novel strategy   to significantly improve corrosion resistance of CoCrFeMnNi HEA by   N-alloying, Corrosion Science, 2022, 204: 110396.

（18）J. Dai, H.B. Li*, H. Feng, et   al. Revealing significant effect of nitrogen on prolonging pitting corrosion lifetime   of martensitic stainless steel by modelling approach, Corrosion Science,   2022, 203: 110369.

（19）H. Feng, J. Dai, H.B. Li*, et   al. Sn microalloying enhances corrosion resistance of stainless steel by accelerating   heterogeneous nucleation of passive film, Corrosion Science,   2022, 201: 110279.

（20）X.J. Li, P. Zhou, H. Feng, Z.H.   Jiang, H.B. Li*, et al. Spontaneous passivation of the CoCrFeMnNi high   entropy alloy in sulfuric acid solution: The effects of alloyed nitrogen and   dissolved oxygen, Corrosion Science, 2022, 196: 110016.

（21）S.C. Zhang, H.B. Li*, Z.H.   Jiang, et al. Unveiling the mechanism of yttrium significantly improving high-temperature   oxidation resistance of super-austenitic stainless steel S32654,   Journal of Materials Science & Technology, 2022, 115:103-114.

（22）J.T. Yu, S.C. Zhang, H.B. Li*,   et al. Influence mechanism of boron segregation on the microstructure evolution   and hot ductility of super austenitic stainless steel S32654, Journal   of Materials Science & Technology, 2022, 112:184–194.

（23）S.C. Zhang, J.T. Yu, H.B. Li*,   et al. Refinement mechanism of cerium addition on solidification structure   and sigma phase of super austenitic stainless steel S32654, Journal of   Materials Science & Technology, 2022, 102: 105–114.

（24）X.L. Liu, H. Feng, J. Wang, X.F.   Chen, P. Jiang, F.P. Yuan, H.B. Li*, et al. Mechanism of dislocation   evolution during plastic deformation of nitrogen-doped CoCrFeMnNi   high-entropy alloy, Journal of Materials Science & Technology,   2022, 108: 256–269.

（25）J.L. Tian, K. Chen, H.B. Li*,   et al. Suppressing grain boundary embrittlement via Mo-driven interphase   precipitation mechanism in martensitic stainless steel, Materials   Science & Engineering A, 2022, 833: 142529.

（26）S.C. Zhang, Y.F. Geng, H.B. Li*,   et al. Design of a Novel Physical Simulator for Simulating Solidification   Process of Continuous Casting Steel Slab, Metallurgical and Materials   Transactions B, 2022, 53(6): 4006-4018.

（27）H.B. Li*, Z.Y. He, H.C Zhu, et al.   Influence Mechanism of Pressure on Nitrogen Bubble Formation During   Solidification Process in 30Cr15Mo1N Ingot, Metallurgical and Materials   Transactions B, 2022, 53(3): 1721-1732.

（28）P.C. Lu, H.B. Li*, H. Feng et   al. Improving Cleanliness and Controlling Inclusion Characteristics in   High-Nitrogen Stainless Bearing Steels by Optimizing Addition Order and   Contents of Mg and Ce, Metallurgical and Materials Transactions B,   2022, 53(3), 1920-1935.

（29）H.C. Zhu, H.B. Li*, Z.W. Ni,   et al. Effect of Solidification Pressure on Phase Transformation and   Precipitated Phases of 30Cr15Mo1N Ingot, Metallurgical and Materials   Transactions B, 2022, 53(1), 50-59.

（30）H. Feng, P.C. Lu, H.B. Li*,   et al. Effect of Mg Pretreatment and Ce Addition on Cleanliness and Inclusion   Evolution in High-Nitrogen Stainless Bearing Steels, Metallurgical and   Materials Transactions B, 2022, 53(2): 864-876.

（31）W.C. Jiao, H.B. Li*, H. Feng,   et al. Significant Improvement of Cleanliness and Macro micro-structure of   As-cast AISI M42 High Speed Steel by Mg Treatment, Metallurgical and   Materials Transactions B, 2022, 53(2): 1196-1211.

（32）S.X. Yang, H.B. Li*, H. Feng,   et al. Reaction Mechanism and Control Strategy of Aluminum Increase in High   Nitrogen Stainless Bearing Steel during Pressurized Electroslag Remelting, Metallurgical   and Materials Transactions B, 2022, 53(2): 1148-1161.

（33）H. Feng, H.B. Li*, X.Z. Li,   et al. Nitrogen Solubility and Gas Nitriding Kinetics in Fe–Cr–Mo–C Alloy   Melts under Pressurized Atmosphere, ISIJ International, 2022,   62 (6): 1049–1060.

（34）Y. Li, H. Yang, Z.H. Jiang, H.B.   Li*, et al. Change of Spinel in High Ca Treament at 38CrMoAl Steel, ISIJ   International, 2022, 62(11), 2276–2285.

（35）S.C. Zhang, H.B. Li*, M.Z. Ran,   et al. Effect of Al2O3 on Viscosity and Refining   Ability of High Basicity Slag for Heat-resistant Austenitic Stainless Steel, ISIJ   International, 2022, 62(11): 2207–2216.

（36）P.C. Lu, H.B. Li*, H. Feng,   et al. Formation Mechanism of AlN Inclusion in High-Nitrogen Stainless   Bearing Steels, Metallurgical and Materials Transactions B, 52,   2210-2223 (2021).

（37）H.C. Zhu, H.B. Li*, Z.Y. He,   et al. Effect of Solidification Pressure on Gap Width between H13 Ingot and   Mold, Metallurgical and Materials Transactions B, 52,   2210-2223(2021).

（38）H. Feng, H.B. Li*, Z.Z. Liu,   et al. Cleanliness Control of High Nitrogen Stainless Bearing Steel by Vacuum   Carbon Deoxidation in a PVIM Furnace, Metallurgical and Materials   Transactions B, 52, 3777-3787 (2021).

（39）S.X. Yang, H.B. Li*, H. Feng,   et al. Desulfurization Behavior 1 of Fe−18Cr−18Mn Alloy during the Pressurized Electroslag Remelting with   Different Atmospheres and Na2O-containing Slags, Metallurgical   and Materials Transactions B., 52, 1294-1308(2021).

（40）S.X. Yang, H. Feng, H.B. Li*,   et al. Nitrogen Solubility in Liquid Fe–Nb, Fe–Cr–Nb, Fe–Ni–Nb and   Fe–Cr–Ni–Nb Alloys, ISIJ International, 61(2021): 5, 1498-1505.

（41）H.C. Zhu, H.B. Li*, et al. Effect   of Pressure on Dendrite Structure and Characteristics of Carbides during   Solidification Process of H13 Die Steel Ingot, ISIJ International,   61(2021): 6, 1889-1898.

（42）L.C. Zheng, H.B. Li*, et al.   Effect of CaF2 on Viscosity and Refining Ability of Highly Basic   Slags for Duplex Stainless Steel, ISIJ International, 61(2021):   6, 1784-1793.

（43）K. Chen, H.B. Li*, Z.H. Jiang∗, et al. Multiphase   microstructure formation and its effect on fracture behavior of medium carbon   high silicon high strength steel, Journal of Materials Science &   Technology, 72 (2021) 81–92.

（44）Y. Han, H.B. Li*, H. Feng, et   al. Simultaneous enhancement in strength and ductility of Fe50Mn30Co10Cr10   high-entropy alloy via nitrogen alloying, Journal of Materials Science   & Technology, 65 (2021) 210–215.

（45）J.L. Tian, W. Wang, H.B. Li*,   et al. Understanding main factors controlling high cycle fatigue crack   initiation and propagation of high strength maraging stainless steels with Ti   addition, Materials Science & Engineering A, 805 (2021)   140589.

（46）S.C. Zhang, H.B. Li*, Z.H.   Jiang, et al. Influence of N on precipitation behavior, associated corrosion   and mechanical properties of super austenitic stainless steel S32654, Journal   of Materials Science & Technology, 2020,42, 143-155.

（47）S.C. Zhang, H.B. Li*, Z.H.   Jiang, et al. Chloride- and sulphate-induced hot corrosion mechanism of super   austenitic stainless steel S31254 under dry gas environment, Corrosion   Science, 2020,163, 108295.

（48）J. Dai, H. Feng, H.B. Li*, et   al. Nitrogen significantly enhances corrosion resistance of 316L stainless   steel in thiosulfate-chloride solution, Corrosion Science, 2020, 174,   108792.

（49）W.C. Jiao, H.B. Li*, H. Feng,   et al. Evolutions of Micro- and Macrostructure by Cerium Treatment in As-Cast   AISI M42 High-Speed Steel, Metallurgical and Materials Transactions B,   51, 2240–2251(2020).

（50）H.C. Zhu, H.B. Li*, Z.Y. He, et al. Effect of Pressure on Inclusion Number   Distribution During the Solidification Process of H13 Die Steel, Metallurgical   and Materials Transactions B, 51, 2976–2992(2020).

（51）W.C. Jiao, H.B. Li*,H.   Feng, et al. Effect of High Nitrogen Addition on Microstructure and   Mechanical Properties of As-cast M42 High Speed Steel, ISIJ   International, 60 (2020), 564–572.

（52）C.Y. Chen, Z.H. Jiang, Y. Li, M. Sun,   Q. Wang, K. Chen and H.B. Li*. State of the Art in the   Control of Inclusions in Spring Steel for Automobile - a Review, ISIJ   International, 60 (2020), 617–627.

（53）J. Yu, F.B. Liu, Z.H. Jiang, H.B. Li*, et al. Effects of Nitrogen Gas Pressure on the   Solidification Parameters and As-cast Microstructure Revolution during   Pressurized Electroslag Remelting AISI 304 Stainless Steel, ISIJ   International, 60 (2020),1684–1692.

（54）H.C. Zhu, H.B. Li*, Z.H. Jiang,   et al. Quantitative Correlation between Interfacial Heat Transfer Coefficient   and Pressure for 19Cr-14Mn-0.9N High Nitrogen Steel Cylindrical Ingot, ISIJ   International, 60 (2020), 1978–1984.

（55）Y. Han, H.B. Li*, H. Feng,   et al. Enhancing the strength and ductility of CoCrFeMnNi high-entropy alloy   by nitrogen addition, Materials Science & Engineering A,   789 (2020) 139587.

（56）K. Chen, Z.H. Jiang*, F.B. Liu, H.B. Li*, et al. Enhanced mechanical properties by retained   austenite in medium–carbon Si-rich microalloyed steel treated by   quenching–tempering, austempering and austempering–tempering processes, Materials   Science & Engineering A, 790 (2020) 139742.

（57）K. Chen, Z.H. Jiang, F.B. Liu, H.B. Li*, et al. Achievement of High Ductility and Ultra-high Strength   of V-Nb Microalloyed Spring Steel by Austempered Multiphase Microstructure, Metallurgical   and Materials Transactions A, 51, 3565–3575(2020).

（58）H. Feng, H.B. Li*, Z.H.   Jiang, et al. Designing for high corrosion-resistant high nitrogen   martensitic stainless steel based on DFT calculation and pressurized   metallurgy method. Corrosion Science, 2019, 158   (2019) 108081.

（59）H. Feng, H.B. Li*, W.C.   Jiao, et al. Significance of Partial Substitution of C by N on Strengthening   and Toughening Mechanisms of High Nitrogen Fe-15Cr-1Mo-C-N Martensitic   Stainless Steels. Metallurgical and Materials Transactions A, 2019, 50(11):   4987–4999.

（60）W.C. Jiao, H.B. Li*, J. Dai,   et al. Effect of partial replacement of carbon by nitrogen on intergranular   corrosion behavior of high nitrogen martensitic stainless steels. Journal   of Materials Science & Technology,2019, 35 (2019) 2357–2364.

（61）J. Yu, F.B. Liu, H.B. Li*, et al. Numerical Simulation and Experimental   Investigation of Nitrogen Transfer Mechanism from Gas to Liquid Steel During   Pressurized Electroslag Remelting Process. Metallurgical and Materials   Transactions B, 2019, 50, 3112~3124.

（62）J. Yu, F.B. Liu, H.B. Li*, et al. Effects of mold current on slag skin and heat flow   distribution during electroslag remelting at given power input. JOM,   71 (2019)744-753.

（63）Z.H. Jiang, G. Xu, Yang Li, H.B. Li*, et al. Effect of Ultra-high Magnesium on SKS51 Liquid   Steel Cleanliness and Microstructure. ISIJ International, 59 (2019)   1234-1241.

（64）H. Feng, Z.H. Jiang, H.B. Li*, et al. Influence of nitrogen on corrosion behaviour of   high nitrogen martensitic stainless steels manufactured by pressurized   metallurgy. Corrosion Science, 144 (2018) 288-300.

（65）H. Feng, H.B. Li*, X.L. Wu, et al.Effect of nitrogen on corrosion behaviour of a novel high nitrogen   medium-entropy alloy CrCoNiN manufactured by pressurized metallurgy. Journal   of Materials Science & Technology, 2018, 34: 1781–1790.

（66）Z.H. Jiang, H.C. Zhu, H.B. Li*, et al. A Novel Method for   Improving Cast Structure of M42 High Speed Steel by Pressurized Metallurgy   Technology, ISIJ International, 2018, 58 (7): 1267–1274.

（67）Z.H. Jiang, H.C. Zhu, H.B. Li*, et al. Effect of   solidification pressure on interfacial heat transfer and solidification   structure of 19Cr14Mn0.9N high nitrogen steel, ISIJ International,   2018, 58 (1): 107–113.

（68）Y. Li, C.Y. Chen, Z.H. Jiang, M. Sun,   H. Hu and H.B. Li*. Application of Alkali Oxides   in LF Refining Slag for Enhancing Inclusion Removal in C96V Saw Wire Steel, ISIJ   International, 2018, 58 (7): 1232–1241.

（69）C.Y. Chen, Z.H. Jiang, Y. Li, M. Sun,   G.Q. Qin, C.L. Yao, Q. Wang and H.B.   Li*. Effect of Rb2O on   Inclusion Removal in C96V Saw Wire Steels Using Low-Basicity LF Refining   Slag, ISIJ International, 2018, 58 (2018) 2032-2041.

（70）H.C. Zhu, Z.H. Jiang, H.B. Li*. Effect of Solidification   Pressure on Thermodynamic and Kinetic Parameters of 19Cr14Mn4Mo0.9N High   Nitrogen Steel. Steel Research International, 2018, 89(5): 1700475.

（71）H.C. Zhu, Z.H. Jiang*, H. B. Li*, et al. Effects of nitrogen   segregation and solubility on the formation of nitrogen gas pores in   21.5Cr-1.5Ni duplex stainless steel, Metallurgical and Materials Transactions B,   2017, 48, 2493-2503.

（72）H.B. Li*, S.X.   Yang, S.C. Zhang*, et al. Microstructure evolution and mechanical properties   of friction stir welding super-austenitic stainless steel S32654, Materials and Design,   2017, 118:207-217.

（73）H.B. Li, C.T. Yang,   E.Z. Zhou, C.G. Yang*, et al. Microbiologically influenced corrosion behavior   of S32654 super austenitic stainless steel in the presence of marine   pseudomonas aeruginosa biofilm, Journal of Materials Science &   Technology, 2017, 1-8.

（74）S.C. Zhang, Z.H. Jiang, H.B. Li*, et al. Detection of   susceptibility to intergranular corrosion of aged super austenitic stainless   steel S32654 by a modified electrochemical potentiokinetic reactivation   method, Journal of Alloys and Compounds, 2017, 695: 3083~3093.

（75）H.C. Zhu, Z.H. Jiang, H.B. Li*, J.H. Zhu, H. Feng, S.C.   Zhang, B.B. Zhang, P.B. Wang, and G.H. Liu. Effect of solidification pressure   on compactness degree of 19Cr14Mn0.9N high nitrogen steel using CAFE method, Steel   Research International, 2017, 88(7):1~12.

（76）H.B. Li, E.Z. Zhou,   Y.B. Ren et al. Investigation of microbiologically influenced corrosion of   highnitrogen nickel-free stainless steel by Pseudomonas aeruginosa, Corrosion   Science, 2016, 111: 811–821.

（77）H.B. Li*, B.B. Zhang, Z.H. Jiang, et al. A   new insight into high-temperature oxidation mechanism of super-austenitic   stainless steel S32654 in air, Journal of Alloys and Compounds,   2016, 86: 326-338.