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一、项目名称:新型钢铁材料的设计、制备和性能研究
二、推荐单位:中国科学院沈阳分院
三、项目简介:
本项目以发展新型钢铁材料为目标,近10年来在多项国家及辽宁省科研项目的支持下,以合金化和结构/功能一体化设计、显微组织控制等为主要学术思想,通过成分优化、纯净化冶炼、组织细化、相变控制、强韧化匹配、生物医学功能化等途径,在新型钢铁材料的设计、制备及性能研究方面开展了系统而深入的研究工作,取得了众多高水平研究成果,发展了一批具有自主知识产权和市场应用前景的新型钢铁材料,在国内外相关领域形成了很高的影响力。项目研究成果对于推动我国钢铁材料的发展与应用,提升钢铁材料的品质具有重要指导意义。项目取得的主要创新性研究成果包括:(1)高强高韧钢铁材料的设计理论,以解决钢铁结构材料强度与塑(韧)性之间的矛盾为切入点,形成了通过成分优化、纯净化、细晶化和复相组织控制等手段获得高强高韧钢铁材料的设计理论与制备技术。(2)结构/功能一体化钢铁新材料的设计理论,以环境保护和生物医用为主要方向,提出了具有抗菌抑菌、生物医学等功能特性的结构/功能一体化钢铁新材料设计思想,通过添加铜元素、以氮代镍等方式,使不锈钢具备了强烈和广谱杀菌特性、在人体中无有害镍离子溶出、抗凝血、抗感染、降低支架内再狭窄等特殊功能。相关研究成果具有独创性。(3)研究开发出一批具有自主知识产权和应用价值的高性能钢铁新材料,包括X80级高强度管线钢、X120级超高强度管线钢、X65级抗大变形管线钢、2800MPa级超高强度马氏体时效钢、2400MPa级无钴超高强度马氏体时效钢、应变诱发相变型高强韧马氏体时效不锈钢、氮化物强化型高铬耐热钢、高速列车转向架用特种弹簧钢、系列抗菌不锈钢、医用高氮无镍奥氏体不锈钢、抗感染医用不锈钢、抗支架内再狭窄不锈钢等钢铁新材料,性能均达到国际先进水平。在国内外相关学术期刊上总计发表文章140篇(其中SCI收录76篇,EI收录125篇),他引次数超过400次,授权23项国家发明专利。
四、完成人: 第1完成人:杨柯
学术贡献:全面负责项目的总体设计和实施,课题申请,国际合作项目的申请和执行,提出一系列创新学术思想。通过纯净化、细晶化、均质化来显著提高高性能结构钢铁材料的强度以及改善其强韧性配合。创造性地提出了钢铁材料的结构/生物医学功能一体化的创新思想,在国际上首次设计并开发出具有抗细菌感染、抑制支架内再狭窄等先进生物医学功能的医用不锈钢新材料。
第2完成人:单以银
学术贡献:超高强度管线钢等新型微合金化钢的成分设计、纯净化制备、控制轧制、相变特性、性能优化等方面研究,发展出X80、X100、X120等高强度级别的新型高性能管线钢原型材料。对管线钢的组织构成及其特征鉴别进行了创造性研究,在此基础上,进一步研究了管线钢的大变形特性。同时,还深入研究了管线钢的抗H2S腐蚀机理和疲劳裂纹扩展性能,为管线钢的工程应用提供了可靠的理论支持。
第3完成人:严伟
学术贡献:参与管线钢、高铬耐热钢、低活化马氏体钢等材料研究工作,在耐热钢的组织演变和稳定化方面进行了深入的研究,在此基础上创新地设计和制备出具有高组织稳定性的氮化物强化耐热钢新材料。对微合金钢中内生氮化钛夹杂物的形成微观机制及其对材料力学性能的影响进行了系统的研究,该创新研究工作对工业生产有重要指导意义。
第4完成人:任伊宾
学术贡献:在“以氮代镍”的创新设计思想指导下,设计和制备出中国首个高氮无镍医用奥氏体不锈钢新材料,并研究了高氮不锈钢的结构稳定性、高氮不锈钢的抗凝血行为及相关机制、氮对高氮不锈钢中的力学行为等。该创新性研究工作极大地推进了高氮无镍不锈钢的临床应用进程。
第5完成人:王威
学术贡献:通过纯净化手段制备出多种强度级别的马氏体时效钢,发展出目前国内强度级别最高的2800MPa级马氏体时效钢。在形变诱发马氏体时效钢的研究基础上,提出了马氏体时效钢梯度组织强化的创新性强韧化机制。另外,还提出了控制马氏体时效钢中析出相尺寸等级来提高马氏体时效钢的疲劳强度的创新性思想。
五、论文论著目录
1、高性能管线钢方面
(1)“微型拉伸试样的设计及其在高性能管线钢研究中的应用”,初蕴清, 段赞强, 董翰, 杨柯, 李守新, 王中光,金属学报,Vol.36(2000),p625。(SCI)
(2)“TMCP工艺对X60管线钢组织和性能的影响”,赵明纯,单以银,曲锦波,杨柯,郑磊,高珊,金属学报,Vol.37(2001),No.2,179。(SCI)
(3)“电磁搅拌对管线钢埋弧焊缝金属低温韧性的影响”,国旭明, 钱百年, 薜小怀, 李晶丽, 张艳,杨柯,金属学报, Vol.36(2000),177。(SCI)
(4)“加速冷却对控轧管线钢组织和性能的影响”,曲锦波,单以银,赵明纯,杨振国,杨柯,高珊,郑磊,钢铁,36(2001),No.9,46-49。
(5)“热变性和加速冷却对低碳微合金钢组织的影响”,曲锦波,单以银,赵明纯,杨柯,高珊,郑磊,钢铁研究学报,13(2001),No.5,43-47。
(6)“Influence of hot deformation and cooling conditions on the microstructures of low carbon microalloyed steels”, Jinbo QU, Yiyin SHAN, Mingchun ZHAO, Ke YANG, Journal of Materials Science & Technology, 17(2001), S1, S135-S138.(SCI)
(7)“控制热加工下管线钢中针状铁素体的形成”,赵明纯,单以银,曲锦波,肖福仁,钟勇,杨柯,金属学报,37(2001),No.8,820。(SCI)
(8)“热变形工艺对超纯净管线钢组织的影响”,钟勇,肖福仁,王忠军,单以银,杨柯,材料研究学报,17(2003),No.3,302。
(9)“Investigation on the H2S-resistant behaviors of acicular ferrite and ultrafine ferrite”, Ming-Chun Zhao, Yi-Ying Shan, Fu-Ren Xiao, Ke Yang and Yu-Hai Li, Materials Letters, 57(2002), p141-145.(SCI)
(10)“The effects of thermo-mechanical control proce on microstructures and mechanical properties of a commercial pipeline steel”, Ming-Chun Zhao, Ke Yang and Yiying Shan, Materials Science and Engineering A, Vol.335(2002), 14-20.(SCI)
(11)“Comparison on strength and toughne behaviors of microalloyed pipeline steels with acicular ferrite and ultrafine ferrite”, Ming-Chun Zhao, Ke Yang and Yi-Yin Shan, Materials Letters, Vol.57(2003), 1496-1500.(SCI)
(12)“Role of microstructure on sulfide stre cracking of oil and gas pipeline steels”, Ming-Chun Zhao, Bei Tang, Yi-Yin Shan and Ke Yang, Metall.Mater.Trans.A, 34(2003), May, 1089-1096.(SCI)
(13)“Acicular ferrite formation during hot plate rolling for pipeline steels”, Ming-Chun Zhao, Yi-Yin Shan, Fu-Ren Xiao and Ke Yang, Journal of Materials Science and Technology, 19(2003), No.3, 355-359.(SCI)
(14)“Continuous cooling transformation of undeformed and deformed low carbon pipeline steels”, Ming-Chun Zhao, Ke Yang, Fu-Ren Xiao, Yi-Yin Shan, Materials Science and Engineering A, 355(2003), 126-136.(SCI)
(15)“管线用超低碳钢中针状铁素体的形成及强韧化行为”,赵明纯,单以银,杨柯,李玉海,蒋星华,材料研究学报,Vol.16(2002),No.6,619。
(16)“Proceing of Ultralow Carbon Pipeline Steels with Acicular Ferrite”, Furen XIAO, Mingchun ZHAO, Yiyin SHAN, Bo LIAO, Ke YANG, Journal of Materials Science & Technology, 20(2004), No.6, 779-781.(SCI)(17)“管线钢疲劳特性研究进展”,钟勇,单以银,霍春勇,杨柯,材料导报,17(2003),No.8,11。
(18)“管线钢的疲劳裂纹扩展速率与疲劳寿命的关系研究”,钟勇,肖福仁,单以银,杨柯,金属学报,41(2005),No.5,523-528。(SCI)
(19)“Strengthening and improvement of sulfide stre cracking resistance in acicular ferrite pipeline steels by nano-sized carbonitrides”, Ming-Chun Zhao, Ke Yang, Scripta Materialia, 52(2005), 881-886.(SCI)
(20)“Difference in the role of non-quench aging on mechanical properties between acicular ferrite and ferrite-pearlite pipeline steels”, Ming-Chun ZHAO, Toshihiro HANAMURA, Hai QIU, Kotobu NAGAI, Yi-Yin SHAN and Ke YANG, ISIJ International, 45(2005), 116-120.(SCI)
(21)“Lath boundary thin-film martensite in acicular ferrite ultralow carbon pipeline steels”, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu, Ke Yang, Materials Science and Engineering A, 395(2005), 327-332.(SCI)
(22)Precipitation of Carbonitrides and Their Strengthening upon Non-quench Aging for Micro-alloyed Acicular Ferrite Pipeline Steels“, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu and Ke Yang, Mater.Trans., 46(2005), No.4, 784-789.(SCI)(23)”Effects of Nano-sized Microalloyed Carbonitrides and(23)High-density Pinned Dislocations on Sulfide Stre Cracking Resistance of Pipeline Steels“, Ming-Chun Zhao, Ke Yang, Journal of Materials Research, 20(2005), No.9, 2248.(SCI)
(24)”Effect of toughne on low cycle fatigue behavior of pipeline steels“, Yong Zhong, Yiyin Shan, Furen Xiao, Ke Yang, Materials Letters, 59(2005), 1780-1784.(SCI)
(25)”Grain growth and Hall-Petch relation in submicron-grained ferrite/cementite steel with nano-sized cementite particles in a heterogeneous and dense distribution“, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu, Kotobu Nagai and Ke Yang, Scripta Materialia, vol.54(6), 2006, 1193-1197.(SCI)
(26)”Dependence of strength and strength-elongation balance on the volume fraction of cementite particles in ultrafine grained ferrite/cementite steels“, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu, Kotobu Nagai, Ke Yang, Scripta Materialia, vol.54(7), 2006, 1385-1389.(SCI)(27)”In situ TEM study of the effect of M/A films at grain boundaries on crack propagation in an ultra-fine acicular ferrite pipeline steel“, Yong Zhong, Furen Xiao, Jingwu Zhang, Yiyin Shan, Wei Wang, Ke Yang, Acta Materialia, Volume 54(2006), Pages 435-443.(SCI)(Top 50 Highly Cited Articles by Chinese Mainland Authors, 2006-2010)(28)”Acicular ferritic microstructure of a low-carbon Mn-Mo-Nb microalloyed pipeline steel“, Furen Xiao, Bo Liao, Deliang Ren, Yiyin Shan, Ke Yang, Materials Characterization, 54(2005), 305-314.(SCI)
(29)”Isothermal transformation of low-carbon microalloyed steels“, Furen Xiao, Bo Liao, Yiyin Shan, Ke Yang, Materials Characterization, 54(2005), 417-423.(SCI)
(30)”Effect of Sulfur Content on Hydrogen Induced Cracking in Pipeline Steels“, Kai Liu, Yiyin Shan, Jiayan Xu, Ke Yang, Iron & Steel, Suppl.40(2005), 189.(31)”Challenge of mechanical properties of an acicular ferrite pipeline steel“, Furen Xiao, Bo Liao, Yiyin Shan, Guiying Qiao, Yong Zhong, Chunling Zhang and Ke Yang, Materials Science and Engineering: A, Vol.431(2006), Iues 1-2, 15 September, 41-52.(SCI)(32)“超低碳微合金管线钢中针状铁素体的组成对强度的影响”,王伟,单以银,杨柯,金属学报,43(2007),No.6,578-582。(SCI)
(33)“添加Mo-B对超高强度管线钢相变组织的影响”,魏伟,单以银,杨柯,王永权,金属学报,43(2007),No.9,943-948。(SCI)
(34)”Effect of applied stre and microstructure on sulfide stre cracking resistance of pipeline steels subjected to hydrogen sulfide “, Ming-Chun Zhao, Ming Liu, Andrej Antrens, Yi-Yin Shan and K.Yang, Materials Science and Engineering A,(2007),(SCI)
(35)”Study of High Strength Pipeline Steels with Different Microstructures“, Wei Wang, Yiyin Shan, Ke Yang, Materials Science and Engineering A, Volume 502(2009), Iues 1-2, 38-44.(36)”Relation among rolling parameters, microstructures and mechanical properties in an acicular ferrite pipeline steel“, Wei Wang, Wei Yan, Lin Zhu, Ping Hu, Yiyin Shan, Ke Yang, Materials and Design, Volume 30(2009), Iue 9 3436-3443.(SCI)
(37)”Proceing of ultralow carbon pipeline steels with acicular ferrite“, Xiao Furen, Liao Bo, Shan Yiyin, Yang Ke, Journal of Materials Science and Technology, 20(2004), p779.(SCI)(38)”Acicular ferritic microstructure of a low-carbon Mn–Mo–Nb microalloyed pipeline steel“, Furen Xiao, Bo Liao, Deliang Ren, Yiyin Shan, Ke Yang, Materials Characterization, 54(2005), p305-314,2005.(SCI)
(39)”Challenge of mechanical properties of an acicular ferrite pipeline steel“, Fu-Ren Xiao, Bo Liao∗, Yi-Yin Shan, Gui-Ying Qiao, Yong Zhong, Chunling Zhang, Ke Yang, Materials Science and Engineering A, 431(2006), p41–52.(SCI)
(40).”Isothermal transformation of low-carbon microalloyed steels“, Furen Xiao, Bo Liao, Yiyin Shan, Ke Yang, Materials Characterization, 54(2005), p417-422.(SCI)
(41)“冷却速度对低碳微合金钢组织的影响”,肖福仁,廖波,单以银,赵明纯,杨柯,NG STEEL’2001, Beijing, Nov.13-26, 2001: 357-361。(42)“热变形对低碳微合金钢连续冷却转变的影响”,单以银,肖福仁,赵明纯,杨柯,廖波,NG STEEL’2001, Beijing, Nov.13-26, 2001: 349-356。
2、高强韧马氏体时效钢方面
(1)“超纯净18Ni马氏体时效钢的晶粒尺寸及其对拉伸性能的影响”,何毅,杨柯,曲文生,孔凡亚,苏国越,金属学报,Vol.38(2002),No.1,53-57。(SCI)
(2)“固溶温度对超纯净18Ni(350)马氏体时效钢断裂韧性及微观组织的影响”,何毅,刘凯,杨柯, 金属学报, Vol.39(2003), No.1,381-386(3)“超纯净化18Ni(350)马氏体时效钢的研究”,何毅,杨柯,曲文生,孔凡亚,苏国越,金属学报,Vol.37(2001),No.8,852-856。(SCI)
(4)“2400MPa级无钴马氏体时效钢的力学性能初探”,何毅,杨柯,材料工程,2002年增刊,325。
(5)“超高强度18Ni无钴马氏体时效钢的力学性能”,何毅,杨柯,孔凡亚,曲文生,苏国越,金属学报,38(2002),第3期,278-282。(SCI)
(6)”Effect of Solution Temperature on Grain Growth and Mechanical Properties of A High Strength 18Ni Co-free Maraging Steel“, He Yi, Yang Ke, Qu Wensheng, Kong Fanya and Su Guoyue, J.Materials Science and Technology, 19(2003), 117-124.(SCI)
(7)”Strengthening and Toughening of A 2800 MPa Grade Maraging Steel“, Yi He, Ke Yang, Wensheng Qu, Fanya Kong and Guoyue Su, Materials Letter, 56(2002), p763-769.(SCI)(8)“2400MPa级无钴马氏体时效钢的力学性能初探”,何毅,杨柯,材料工程,2002年增刊,325。
(9)”Effects of solution treatment temperature on grain growth and mechanical properties of high strength 18% Ni cobalt free maraging steel“, Y.He, K.Yang, W.-S Qu, F.Y.Kong and G.Y.Su, J.Mater.Sci.Technol., Vol.19(2003), 117.(SCI)
(10)”Effect of Solution Temperature on Fracture Toughne and Microstructure of 18(350)Maraging Steel“, Yi HE, Kai Liu, Ke YANG, Acta Metallurgical Sinica, 2003, 4, 65.(11)”Microstructure and Mechanical Properties of a 2000 MPa Co-Free Maraging Steel after Aging at 753 K“, Y.He, K.YANG, W.SHA and D.J.CLELAND, Metall.Mater.Trans., Vol.35A(2004), 2747.(SCI)
(12)”Microstructure and Mechanical Properties of a 2000 MPa Grade Co-Free Maraging Steel“, YI He, KE YANG and WEI SHA, Metall.Mater.Trans., Vol.36A(2005), 2273.(SCI)(13)”Age Hardening and Mechanical Properties of a 2400 MPa Grade Cobalt-Free Maraging Steel“, YI HE, KE YANG, WEI SHA, ZHANGLI GUO and KAI LIU, Metall.Mater.Trans.A, vol.37(2006), 1107.(SCI)
(14)”Effect of Heat Treatment on Prior Grain Size and Mechanical Property of a Maraging Stainle Steel“, Kai Liu, Yiyin Shan, Zhiyong Yang, Jianxiong Liang, Lun Lu and Ke Yang, Journal of Materials Science and Technology, 22(2006), No.6, 769.(SCI)
(15)“未再结晶固溶处理对无钴马氏体时效钢组织和拉伸性能的影响”,季长恩,王威,单以银,杨柯,钢铁,43(2008),第9期,75-78。
(16)”Genetic Design and Characterization of Novel Ultra High Strength Stainle Steels Strengthened by Ni3Ti Intermetallic Nanoprecipitates“, W.Xu, P.E.J.Rivera-Diaz-del-Castillo, W.Wang, K.Yang, V.Blinznuk, L.A.I.Kestens, Z.van der Zwaag, Acta Materialia, Vol.58(2010), No.10, 3582-3593.(SCI)
(17)”Study on fatigue property of a new 2.8 GPa grade maraging steel“, Wei Wang, Wei Yan, Qiqiang Duan, Yiyin Shan, Zhefeng Zhang, Ke Yang, Materials Science and Engineering A, 527(2010), 3057-3063.(SCI)
(18)“新型形变诱发马氏体时效不锈钢的组织与性能”,邓利芬,严伟,王威,单以银,杨柯,材料热处理学报,32(2011),pp.92-96。
(19)”A new ultrahigh-strength stainle steel strengthened by various coexisting nanoprecipitates“, W.Xu, P.E.J.Rivera-Díaz-del-Castillo, W.Yan, K.Yang, D.San Martín, L.A.I.Kestens, S.van der Zwaag, Acta Materialia, 58(2010), pp.4067-4075.3、高氮不锈钢方面
(1)“真空感应炉冶炼高氮钢的影响因素研究”,任伊宾,杨柯,张炳春,肖克沈,梁勇,材料与冶金学报,3(2004),No.1,8-12。
(2)“用真空感应炉冶炼高氮不锈钢的工艺研究”,任伊宾,杨柯,张炳春,杨慧宾,梁勇,特殊钢,(2004),No.4,13。
(3)“高氮奥氏体不锈钢与316L不锈钢的冷变形行为研究”,王松涛,杨柯,单以银,李来风,金属学报,43(2007),No.2,171-176。(SCI)
(4)“冷变形对高氮奥氏体不锈钢组织与力学行为的影响”,王松涛,杨柯,单以银,李来风,金属学报,43(2007),No.7,713-718。(SCI)
(5)”Cavitation erosion resistance of high nitrogen stainle steel in comparison with low N content CrMnN stainle steel“, Y.X.Qiao, Y.G.Zheng, X.Q.Wu, W.Ke, K.Yang and Z.H.Jiang, Tribology, Vol.1(2007), No.3, 165.(SCI)
(6)”Plastic Deformation and Fracture Behaviors of Nitrogen Alloyed Austenitic Stainle Steels“, Songtao Wang, Ke Yang, Yiyin Shan and Laifeng Li, Materials Science and Engineering A, 490(2008), 95-104.(SCI)
(7)”Influence of Cold Work on Pitting Corrosion Behavior of a High Nitrogen Stainle Steel“, Yao Fu, Xingqiang Wu, Enhou Han, Wei Ke, Ke Yang, and Zhouhua Jiang, Journal of The Electrochemical Society, 155(2008), No.8, 455-463.(SCI)
(8)”Temperature dependence of tensile behavior of a high nitrogen Fe-Cr-Mn-Mo stainle steel“, Wei Wang, Songtao Wang, Ke Yang, Yiyin Shan, Materials and Design, Volume 30(2009), Iue 5, 1822-1824.(SCI)
(9)“Effects of Nitrogen on the Paivation of Nickel-Free High Nitrogen Stainle Steels in Acidic Chloride Solutions”, Y Fu, XQ Wu, EH Han, W Ke, K Yang, Z H Jiang, Electrochimica Acta, 2009, 54(16): 4005-4014.(SCI)
(10)“Effects of Cold Work and Sensitization Treatment on the Corrosion Resistance of High Nitrogen Stainle Steel in Chloride Solutions” ,Y Fu, XQ Wu, EH Han, W Ke, K Yang, ZH Jiang, Electrochimica Acta, 2009, 54(5): 1618-1629.(SCI)
(11)“Investigation on Pitting Corrosion of Nickel Free and Manganese Alloyed High Nitrogen Stainle Steels”, XQ Wu, Y Fu, JB Huang, EH Han, W Ke, K Yang, ZH Jiang, Journal of Materials Engineering and Performance, 2009,18(3): 287-298.(SCI)
(12)“Temperature dependence of tensile behaviors of nitrogen alloyed austenitic stainle steels” Wei Wang, Wei Yan, Ke Yang, and Yiyin Shan, Journal of materials engineering performance,2010,(19):1214-1219(SCI)
(13)“Uniform Corrosion and Intergranular Corrosion Behavior of Nickel Free and Manganese Alloyed High Nitrogen Stainle Steels”, XQ Wu, S Xu, JB Huang, EH Han, W Ke, K Yang, ZH Jiang,Materials and Corrosion, 2008, 59(8): 676-684.(SCI)
(14)“In Vitro Biocompatibility of a New High Nitrogen Nickel Free Austenitic Stainle Steel ”,YB Ren, HJ Yang, K Yang, BC Zhang,Key Engineering Materials, 2007, 342-343:605-608.(15)“镍对医用金属材料血小板粘附的影响”,马丹,任伊宾,李英民,黄晶晶,张炳春,杨柯,沈阳工业大学学报,30(2008)55-59。
(16)“双相不锈钢表面奥氏体高氮层的制备技术”,王耘涛,毛萍莉,陈立佳,任伊宾,张炳春,杨柯,沈阳工业大学学报,29(2007)285-288。
(17)“氮对冷变形高氮奥氏体不锈钢的微观结构的作用机理”,王威,陈淑梅,严伟,赵立君,单以银,杨柯,材料热处理学报,31(2010),59-65。
4、新型耐热钢方面
(1)”Study on Laves phase in an advanced heat-resistant steel“, P.HU, W.YAN, W.SHA, W.WANG, Z.l.GUO, Y.Y.SHAN, K.YANG., Front.Mater.Sci.China, 30(2009), pp.434-441.(2)”Nitride-strengthened reduced activation ferritic/martensitic steels“, Ping Hu, Wei Yan, Li-fen Deng, Wei Sha, Yi-yin Shan, Ke Yang, Fusion Engineering and Design, 85(2010), 1632-1637.(SCI)
(3)”Microstructure Evolution of a 10Cr Heat-resistant Steel during High Temperature Creep“, Ping Hu, Wei Yan, Wei Sha, Wei Wang, Yiyin Shan, Ke Yang, Journal of Materials Science & Technology, 27(2011), pp.344-351.(SCI)(4)”Constitutive equations of the minimum creep rate for 9%Cr heat resistant steels“, Yun Xiang Chen, Wei Yan, Wei Wang, YiYin Shan, Ke Yang, Material Science Engineer A, 534(2012), 649-653.(SCI)
(5)“Effect of heat treatment on microstructure and hardne of Eurofer 97, Eurofer ODS and T92 steels”, Lu, Z., Faulkner, R.G., Riddle, N., Martino, F.D., Yang, K., Journal of Nuclear Materials, 386-388(2009), p 445-448.(SCI)
(6)”Effect of Carbon Reduction on the Toughne of 9CrWVTaN Steels“, Wei Yan, Ping Hu, Lifen Deng, Wei Wang,Wei Sha, Yiyin Shan, Ke Yang, Metallurgical Materials Transaction A, on line.(SCI)
(7)“CLAM钢在600℃长期时效过程中的组织与性能变化,杨春光,严伟,王威,单以银,杨柯,吴宜灿.,金属学报,47(2011)pp.917-920。(SCI)
(8)“T/P91钢在高应力条件下蠕变行为的CDM模型模拟”,陈云翔,严伟,胡平,单以银,杨柯,金属学报,47(2011),pp.1372-1377。(SCI)
(9)“钇对9Cr-2WVTa低活化马氏体钢理学性能的影响”,严伟,胡平,王伟,赵立君,单以银,杨柯,核科学与工程,29(2009),No.1,50。
(10)“9Cr马氏体耐热钢膨胀-温度曲线上的斜率变化研究”,胡平,严伟,单以银,杨柯,金属热处理,34(2009),52-55。
(11)“新型耐热钢NF12的热处理工艺”,严伟,胡平,赵立君,单以银,杨柯,金属热处理,34(2009),59-61。
5、新型医用不锈钢方面
(1)“新型医用不锈钢性能研究”,任伊宾,杨柯,张炳春,梁勇,功能材料,Suppl.,35(2004),2351-2354。
(2)”Nickel-free stainle steel for medical applications“, Ren Yibin.Yang Ke.Zhang Bingchun, Wang Yaqing and Liang Yong, Journal of Materials Science and Technology, 20(2004), 571.(SCI)
(3)“含Cu抗菌不锈钢的微观组织及其抗菌性能”,陈四红,吕曼祺,张敬党,董加胜,杨柯,金属学报,40(2004),314。(SCI)
(4)“抗菌不锈钢及其在医疗卫生领域中的应用”,杨柯,陈四红,董加胜,宋莉,吕曼祺,中国公共关系,21(增刊),2005,97-100。
(5)“含Cu铁素体抗菌不锈钢的抗菌特性”,吕曼祺,陈四红,董加胜,杨柯,材料研究学报,19(2005年),6期,581-588。
(6)“铁素体抗菌不锈钢的抗菌特性研究”,杨柯,陈四红,董加胜,吕曼祺,金属功能材料,12(2005年),6期,6-9。
(7)“铁素体抗菌不锈钢抗菌过程与机理初探”,吕曼祺,陈四红,董加胜,杨柯,金属功能材料,12(2005年),6期,10-13。(8)“含Cu抗菌不锈钢的工艺与耐蚀性能”,杨柯,董加胜,陈四红,吕曼祺,材料研究学报,20(2006年),5期,524。
(9)“含La医用316L不锈钢的体外抗凝血性能研究”,杨化娟,杨柯,张炳春,金属学报,42(2006),No.9,959-964。(10)”Pitting Corrosion Resistance of La Added 316L Stainle Steel in Simulated Body Fluids“, Huajuan Yang, Ke Yang, Bingchun Zhang, Materials Letters, 61(2007), Iues 4-5, 1154-1157.(SCI)
(11)“含铜抗菌不锈钢的抗菌特性研究”,南黎,刘永前,杨伟超,徐慧,李瑛,吕曼祺,杨柯,金属学报,43(2007),No.10,1065-1070。(SCI)
(12)”In vitro studies of platelet adhesion on medical nickel-free stainle steel surface“, Yibin Ren, Ke Yang, Bingchun Zhang, Material Letters, 59(2005), 1785-1789.(SCI)
(13)”In Vitro Biocompatibility of A New High Nitrogen Nickel Free Austenitic Stainle Steel“, Yibin Ren, Huajuan Yang, Ke Yang, Bingchun Zhang, Key Engineering Materials, 342-343(2007), 605-608.(SCI)
(14)”Antibacterial Mechanism of Copper-bearing Antibacterial Stainle Steel against E.Coli“, Li NAN, Weichao YANG, Yongqian LIU, Hui XU, Ying LI, Manqi LU and Ke YANG, Journal of Materials Science and Technology, Vol.24(2008), No.2, 197-201.(SCI)
(15)”Study on Antibacterial Mechanism of Copper-bearing Austenitic Stainle Steel by Atomic Force Microscopy“, Li NAN, Yongqian LIU, Manqi LU, Ke YANG, Journal of Materials Science: Materials in Medicine, 19(2008), No.9, 3057-3062.(SCI)
(16)“含铜马氏体抗菌不锈钢的研究”,刘永前,南黎,陈德敏,杨柯,稀有金属材料与工程,37(2008),No.8,1380-1383。(SCI)
(17)”Study of Cu Ions Diolution from Cu-bearing Antibacterial Stainle Steel“, Nan Li, Yang Ke, Journal of Materials Science and Technology, 26(2010), No.10, 941-944.(SCI)(18)”Study of Nickel-free Austenitic Stainle Steels for Medical Application Science and Technology of Advanced Materials“, Ke Yang and Yibin Ren, Science and Technology of Advanced Materials, 11(2010),(13pp).(19)”Effect of nitrogen on blood compatibility of nickel-free high nitrogen stainle steel for biomaterial“, P.Wan, Y.Ren, B.Zhang, K.Yang, Materials Science and Engineering: C, 30(2010), 8, 1183-1189.(SCI)
(20)“新型抗菌不锈钢微螺钉种植体的细胞毒性分析”,张丹,张扬,卢利,杨柯,薛楠,中国组织工程与临床康复,2010(4),14(16):2916-2920。
(21)“抗菌不锈钢材料的细胞毒性评价研究”,薛楠,张丹,张扬,杨柯,南黎,郭艳,口腔医学,30(2010),No.12,712-715。
(22)“医用不锈钢的研究与发展”,杨柯,任伊宾,中国材料进展,2010,12期:1-10.(23)”In vitro Study on a New High Nitrogen Nickel-free Austenitic Stainle Steel for Coronary Stents“, Yibin Ren, Peng Wan, Feng Liu, Bingchun Zhang and Ke Yang, Journal of Materials Science and Technology, 27(2011), 4, 325-331.(SCI)
(24)”Study of copper precipitation behavior in a Cu-bearing austenitic antibacterial stainle steel“, Ling Ren, Li Nan, Ke Yang, Materials & Design, 32(2011), Iue 4, 2374-2379.(SCI)(25)”Antibacterial effect of 317L stainle steel contained copper in prevention of implant-related infection in vitro and in vivo“, Hongwei Chai, Lei Guo, Xiantao Wang, Yuping Fu, Junlin Guan, Lili Tan, Ling Ren, Ke Yang, Journal of Materials Science: Materials in Medicine, 22(2011), 2525-2535.(SCI)
6、钢的显微组织与强韧化机制方面
(1)”Effect of TiN Inclusions on the Impact Toughne of Low Carbon Microalloyed Steels“, W.YAN, Y.Y.SHAN and K.YANG, Metall.and Mater.Trans.A, 37(2006), pp.2147-58.(SCI)(2)”Microstructural Evolution of Submicron Sized Ferrite in Bimodal Structural Ultrafine Grained Ferrite/Cementite Steels by Annealing below Austenized Temperature“, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu, Ke Yang., Metall.Mater.Trans.A, vol.37, 2006.(SCI)(3)”Low absorbed energy ductile dimple fracture in lower shelf region in an ultrafine grained ferrite/cementite steel“, Ming-Chun Zhao, Toshihiro Hanamura, Hai Qiu, Ke Yang., Metall.Mater.Trans.A, vol.37, 2006.(SCI)
(4)”Influence of TiN Inclusions on Cleavage Fracture Behavior of Low Carbon Microalloyed Steels“, W.YAN, Y.Y.SHAN and K.YANG, Metall.and Mater.Trans.A, 38(2007), pp.1211-1222.(SCI)
(5)”Change of tensile behavior of a high-strength low-alloy steel with tempering temperature“, Wei Yan, Lin Zhu, Wei Sha, Yi-yin Shan, Ke Yang, Materials Science and Engineering: A, Volume 517(2009), Iues 1-2, 369-374.(SCI)
(6)”Delamination Fracture Related to Tempering in a High-Strength Low-Alloy Steel“, W.YAN, W.SHA, L.ZHU, Y.Y.SHAN, K.YANG, Metall.and Mater.Trans.A, Vol.41(2010), 159-171.(SCI)
(7)”Effect of the Small Reaustenized Grains on the Mechanical Properties of a HSLA Steel“, Zhao Lian-yu, Yan Wei, Shan Yi-yin, Yang Ke, Journal of Iron and Steel Research International, 18(2011), pp.312-315.(SCI)
(8)”Effect of Heat Treatment on the Mechanical Properties and the Carbide Characteristics of a High Strength Low Alloy Steel", Zhang Wen-feng, Hu Ping, Zhou Qiang-guo, Yan Wei, Shan Yi-yin, Yang Ke, Journal of Iron and Steel Research International, 18(2011), pp.143-147.(SCI)
