付立铭 - 上海交通大学材料科学与工程学院

付立铭
副研究员

所属二级机构：高性能金属材料研究所

通讯地址：上海交通大学材料学院A楼407

电子邮箱：lmfu@sjtu.edu.cn

从事先进高性能金属结构材料的设计开发、强韧化机理、强韧化技术及应用技术研究。主要面向超强高硬金属材料、超强耐磨材料、金属材料的结构及功能一体化和表面改性等研究，挖掘金属结构材料性能潜力，开发研制面向未来的新型高强韧、高性能金属及合金材料。研制的材料成功应用在海洋船舶、航天军工和重型机械等领域。主持及参加多项国家及企业的重大项目与重大课题的立项、评审等工作，主持及参加国家自然科学基金面上、国防军工、国家重大专项、省部级重点及面上等纵向科研自主项目共6项，千万级校地/企合作项目3项，以及宝武钢铁、鞍钢集团、日照钢铁、国家核电、上海电气、中国一汽、上海环科院、西安热工院、徐工集团等大型企业横向合作科研资助项目80余项。相关研究成果发表国内外论文110余篇，SCI收录60余篇，申请及授权国家发明专利30余项，合著书籍1部，参加撰写并出版美国金属学会主办的ASM Handbook钢铁标准热处理标准（2014，,4D卷）。获得第十届“创业江苏”科技创业大赛、第十一届中国创新创业大赛江苏赛区优秀团队奖，第九届中国国际“互联网 +”大学生创新创业大赛上优秀指导教师奖。获2024年江苏台州市凤城英才双创人才计划、2022年度江苏省科学技术一等奖。

教育经历

2009年-2014年，上海交通大学材料学博士

工作经历

2022年-1970年，上海交通大学，副研究员
2017年-2022年，上海交通大学，专职科研系列：助理研究员
2014年-2019年，上海交通大学，专职科研队伍：博士后
2004年-2009年，宝钢中央研究院，科研助理、科研主管、副主任研究员

研究方向

超高强金属组织与性能调控及强韧化机理
超级高强特种合金钢的制备技术开发

科研项目

基于亚稳奥氏体温变形和相变调控的3.0GPa超级高强高韧钢的制备及其强韧化机理研究
难降解高浓度有机废水深度氧化设备大型化关键技术研究（上海市配套）
超大型盾构机用超强高韧耐磨刀盘制造
高精度高闭合度疲劳裂纹能力验证嵌块制造开发
超大口径PHP大型发射装置制造工艺研发及组织与性能评定
金属管道性能验证试块裂纹嵌块制作（第二批）采购合同
履带板组织与性能、铸造工艺及耐久性寿命评估研究
机械疲劳裂纹缺陷开制采购合同
超超临界火电机组关键材料焊接及力学性能评估研究
镍基合金超薄板材制备工艺开发
3.5~4.0%Si高硅钢塑性改善机理及可制造性技术研究
微纳结构先进高强钢的制备及其强韧化机理研究
孪晶诱发塑性（TWIP）钢的组织纳米化及其变形机制
超大挖铲斗关键制造技术研究及产业化（300吨矿挖铲斗关键部件材料分析及关键部件试制）
超大口径平衡炮大型发射装置用特种合金材料研发
400吨超大挖机高耐磨斗齿及锁定机构技术开发及国产化制造
航天军工用先进超高强特种合金钢棒材制造技术研究
超大挖铲斗关键制造技术研究及产业化（阶段一：400吨矿挖正铲铲斗耐磨件材料分析与齿尖试制）
高端装备紧固件用先进高强钢的强韧化机理研究
先进超高强度铜合金的开发及组织与性能调控工艺和强韧化机理研究
原奥组织超细化及成分梯度化的快速加热工艺研究
2.5GPa超级高强钢板的开发及其强韧化机理研究

研究情况

论文信息

[1] Jiantao Fan, Shuo Ma, Liming Fu*, Pengfei Yu, Gong Li*, Mao Wen, Aidang Shan*, Partial recrystallization of Ni42Fe30Cr12Mn8Al5Ti3 complex-concentrated alloy to achieve enhanced strength-ductility combination, Journal of Alloys and Compounds 1020 (2025) 179412.
[2] Tao Fu, Liming Fu*, Dongyang Qin, Cong Ye, Shuo Ma, Mao Wen, Aidang Shan*, Effect of annealing temperature on microstructure and mechanical properties of a heavy cold-rolled Custom 465 maraging stainless steel, Materials Science and Engineering: A 936 (2025) 148443.
[3] Tianchi Ma, Bin Fu*, Wei Guan, Yanhui Guo, Liming Fu*, Aidang Shan, Dissolution Behavior of Carbide in 4Cr13 Martensitic Stainless Steel during Austenitizing, Journal of Materials Engineering and Performance 34(6) (2025) 5394-5401.
[4] Dongyang Qin, Tao Fu, Liming Fu*, Cong Ye, Shuo Ma*, Aidang Shan*, Enhancement of strength–ductility in a martensitic stainless steel via heavy warm–rolling and tempering–partitioning treatment, Journal of Materials Science 60(32) (2025) 14102-14123.
[5] Tian Genqi, C. U. I. Zhengqiang, S. H. I. Chenyi, M. A. O. Bo, Zhao Shuangqun, F. U. Liming, Wang Yanfeng, Shan Aidang, Research and Application Progress of Ferritic Heat-resistant Steels for Boilers, Journal of Chinese Society of Power Engineering 45(3) (2025) 334-346.
[6] Kesen Wang, Fangzhou Qi, Deyun Liu, Shuo Ma*, Liming Fu*, Aidang Shan*, Achieving excellent mechanical and electrical properties in Al-Si alloy via heterogeneous lamella structure with high-density nanoprecipitates, Materials Science and Engineering: A 924 (2025) 147778.
[7] Yutao Wang, Liming Fu*, Shuo Ma*, Wei Wang, Aidang Shan*, A 2.6 GPa Ultra-Strong Steel with Ultrafine Lamellar Structure Produced by Heavy Warm Rolling, Acta Metallurgica Sinica (English Letters) 38(9) (2025) 1613-1627.
[8] Xiaofeng Wu, Yao Lu, Mingjian Wang, Mao Wen, Liming Fu*, Shuo Ma, Aidang Shan*, Comparative study the effect of β-phase ratio on mechanical properties of Ti-4Al-2.5V-1.5Fe and Ti-6Al-4V alloys by heavy warm rolling followed by annealing, Journal of Alloys and Compounds 1033 (2025) 181274.
[9] Xiaobin Yang, Deyun Liu, Siyu Kuang, Kai Yin, Cong Ye, Yiheng Dong, Jiang Ju, Zhao Shen, Shuo Ma*, Liming Fu*, Aidang Shan*, Outstanding strength-ductility combination in NAB alloy via coarse Widmanstätten α phases and ultrafine (α+κ) lamella structure, Materials Science and Engineering: A 920 (2025) 147565.
[10] Yang Du, Yiheng Dong, Shuo Ma*, Xiaobin Yang, Jiang Ju, Zhao Shen, Zhongyuan Suo, Liming Fu*, Aidang Shan, Insight into the tribological behavior of the dual-phase nickel aluminum bronze alloy by multiscale characterization, Wear 556-557 (2024) 205530.
[11] Jiantao Fan, Tao Fu, Shuo Ma, Liming Fu*, Mao Wen, Aidang Shan*, Study on the strain partitioning behavior in heterostructured complex-concentrated alloy via high-resolution digital image correlation, Materials Science and Engineering: A 908 (2024) 146809.
[12] Xinbo Ji, Mingjian Jian, Huakai Zhang, Liming Fu*, Liangliang Jian, Yang Chen, Guangcheng Zhang, Aidang Shan*, Effects of prior austenite refinement on microstructure and property of ultra-fine lath martensitic steel, Materials Letters 358 (2024) 135816.
[13] Shuo Ma, Zhao Shen*, Xiaobin Yang, Jiang Ju, Xiaoqin Zeng, Liming Fu*, Aidang Shan*, Observation of the formation of CuAl2O4 by the direct consumption of Al2O3 in an NAB alloy at elevated temperature, Corrosion Science 232 (2024) 112026.
[14] Genqi Tian, Yuantao Xu, Liming Fu*, Bo Mao, Shuangqun Zhao, Yanfeng Wang, Aidang Shan*, Effect of long-term aging on the microstructure evolution and fracture mechanism of 9% Cr steels, Materials Science and Engineering: A 893 (2024) 146133.
[15] Yuxuan Liu, Shichang Liu, Liming Fu*, Huanrong Wang, Wei Wang, Mao Wen, Aidang Shan*, Achieving Fine-Grained Microstructure and Superior Mechanical Property in a Plain Low-Carbon Steel Using Heavy Cold Rolling Combined with Short-Time Heat Treatment, Acta Metallurgica Sinica (English Letters) 36(10) (2023) 1719-1734.
[16] Shuo Ma, Xuan Li, Xiaobin Yang, Liming Fu*, Lei Liu, Mingxu Xia, Aidang Shan*, Effect of Annealing Temperature on Microstructure and Properties of a Heavy Warm Rolled Nickel Aluminum Bronze Alloy, Metallurgical and Materials Transactions A 54(1) (2023) 293-311.
[17] Shuo Ma, Xiaobin Yang, Liming Fu*, Aidang Shan*, Achieving high strength-ductility synergy in nickel aluminum bronze alloy via a quenching-aging-tempering heat treatment, Materials Letters 333 (2023) 133661.
[18] Shuo Ma, Cong Ye, Xiaobin Yang, Liming Fu*, Jiantao Fan, Jian Wang, Aidang Shan*, Microstructure evolution during the heavy warm rolling of a nickel aluminum bronze, Materials Science and Engineering: A 883 (2023) 145458.
[19] Shuo Ma, Qing Zhang, Jiantao Fan, Liming Fu*, Mao Wen, Manping Liu, Aidang Shan*, Excellent combination of strength, conductivity and ductility realized in a dilute Cu-Cr-Zr alloy by coherent nanoprecipitates, Materials Science and Engineering: A 885 (2023) 145614.
[20] Genqi Tian, Bo Mao, Yuantao Xu, Liming Fu*, Zuogui Zhang, Yanfeng Wang, Aidang Shan*, Investigation on gradual degradation of mechanical property and microstructure in 9% Cr heat-resistant steels via interrupted creep test, Journal of Materials Science 58(10) (2023) 4637-4656.
[21] Jian Wang, Jiantao Fan, Liming Fu*, Aidang Shan*, Improved Mechanical Properties in Carbon Martensitic Steel Achieved by Continuous Carbon Gradient and Multilayered Structure, Acta Metallurgica Sinica (English Letters) 36(12) (2023) 2069-2078.
[22] Jian Wang, Qing Tao, Jiantao Fan, Liming Fu*, Aidang Shan*, Enhanced mechanical properties of a high-carbon martensite steel processed by heavy warm rolling and tempering, Materials Science and Engineering: A 872 (2023) 144958.
[23] Jiantao Fan, Liming Fu*, Yanle Sun, Feng Xu, Yi Ding, Mao Wen, Aidang Shan*, Unveiling the precipitation behavior and mechanical properties of Co-free Ni47-xFe30Cr12Mn8AlxTi3 high-entropy alloys, Journal of Materials Science & Technology 118 (2022) 25-34.
[24] Jiantao Fan, Xinbo Ji, Liming Fu*, Jian Wang, Shuo Ma, Yanle Sun, Mao Wen, Aidang Shan*, Achieving exceptional strength-ductility synergy in a complex-concentrated alloy via architected heterogeneous grains and nano-sized precipitates, International Journal of Plasticity 157 (2022) 103398.
[25] Xinbo Ji, Liming Fu*, Han Zheng, Jian Wang, Hengchang Lu, Wei Wang, Mao Wen, Han Dong, Aidang Shan*, Strengthening of Ultrafine Lamellar-Structured Martensite Steel via Tempering-Induced Nanoprecipitation, Acta Metallurgica Sinica (English Letters) 35(11) (2022) 1812-1824.
[26] Xin-bo Ji, Si-xin Zhao, Li-ming Fu*, Jian Peng, Jia-qiang Gao, Da-jiang Yu, Zong-ze Huang, Ai-dang Shan*, High cycle rotating bending fatigue performance and fracture behavior in a pearlite–ferrite dual-phase steel, Journal of Iron and Steel Research International 29(3) (2022) 519-528.
[27] Jian Wang, Qing Tao, Han Zheng, Liming Fu*, Aidang Shan*, Microstructure and mechanical properties of a continuous carbon-gradient sheet steel, Materials Letters 308 (2022) 131059.
[28] Xinbo Ji, Liming Fu*, Han Zheng, Jian Peng, Wei Wang, Aidang Shan*, Ultrafine lamellar microstructure with greatly enhanced strength and ductility of martensite steel via heavily warm rolling of metastable austenite, Materials Science and Engineering: A 826 (2021) 141977.
[29] Han Zheng, Liming Fu*, Xinbo Ji, Yi Ding, Wei Wang, Mao Wen, Aidang Shan*, Microstructural evolution and mechanical property of ultrafine-grained pearlitic steel by cold rolling: The influence of cementite morphology, Materials Science and Engineering: A 824 (2021) 141860.
[30] Shuo Ma, Liming Fu*, Aidang Shan*, Enhancing strength-ductility of the aluminum bronze alloy by generating high-density ultrafine annealing twins, Materials Characterization 177 (2021) 111057.
[31] Han Zheng, Liming Fu*, Xinbo Ji, Ziyong Li, Yanle Sun, Sixin Zhao, Wei Wang, Aidang Shan*, Granular Carbides-Assisted Ultrafine-Ferrite Fabrication in the Pearlitic Steel Without Severe Plastic Deformation and Annealing, Acta Metallurgica Sinica (English Letters) 33(12) (2020) 1645-1656.
[32] Ziyong Li, Liming Fu, Jian Peng, Han Zheng, Aidang Shan, Effect of annealing on microstructure and mechanical properties of an ultrafine-structured Al-containing FeCoCrNiMn high-entropy alloy produced by severe cold rolling, Materials Science and Engineering: A 786 (2020) 139446.
[33] 马硕, 龚安华, 付立铭, 单爱党, 温轧高强韧镍铝青铜合金的组织与力学性能, 中国有色金属学报 (2020).
[34] Ziyong Li, Liming Fu*, Jian Peng, Han Zheng, Xinbo Ji, Yanle Sun, Shuo Ma, Aidang Shan*, Improving mechanical properties of an FCC high-entropy alloy by γ′ and B2 precipitates strengthening, Materials Characterization 159 (2020) 109989.
[35] Shuo Ma, Liming Fu*, Xuedong Ma, Aidang Shan*, Ultra-strong nickel aluminum bronze alloys with ultrafine microstructures by continuous heavy hot rolling, Materials Characterization 158 (2019) 109986.
[36] Han Zheng, Liming Fu*, Ziyong Li, Xinbo Ji, Qijiang Wang, Wei Wang, Aidang Shan*, An ultrahigh-strength steel produced by heavy warm rolling of the metastable austenite, Materials Today Communications 21 (2019) 100646.
[37] Jian Peng, Ziyong Li, Liming Fu*, Xinbo Ji, Zhuorui Pang, Aidang Shan*, Carbide precipitation strengthening in fine-grained carbon-doped FeCoCrNiMn high entropy alloy, Journal of Alloys and Compounds 803 (2019) 491-498.
[38] Ziyong Li, Liming Fu*, Han Zheng, Rui Yu, Lifeng Lv, Yanle Sun, Xianping Dong, Aidang Shan*, Effect of Annealing Temperature on Microstructure and Mechanical Properties of a Severe Cold-Rolled FeCoCrNiMn High-Entropy Alloy, Metallurgical and Materials Transactions A 50(7) (2019) 3223-3237.
[39] Lifeng Lv, Liming Fu*, Yanle Sun, Aidang Shan*, An investigation on the microstructure and mechanical properties in an ultrafine lamellar martensitic steel processed by heavy warm rolling and tempering, Materials Science and Engineering: A 731 (2018) 369-376.
[40] Liming Fu*, Mokun Shan, Daoda Zhang, Huanrong Wang, Wei Wang, Aidang Shan, Microstructure Evolution and Mechanical Behavior of a Hot-Rolled High-Manganese Dual-Phase Transformation-Induced Plasticity/Twinning-Induced Plasticity Steel, Metallurgical and Materials Transactions A 48(5) (2017) 2179-2192.
[41] Liming Fu, Likun Fan, Zhigang Li, Nairong Sun, Huanrong Wang, Wei Wang, Aidang Shan*, Yield behaviour associated with stacking faults in a high-temperature annealed ultra-low carbon high manganese steel, Materials Science and Engineering: A 582 (2013) 126-133.
[42] Liming Fu, Zhiming Li, Huanrong Wang, Wei Wang, Aidang Shan*, Lüders-like deformation induced by delta-ferrite-assisted martensitic transformation in a dual-phase high-manganese steel, Scripta Materialia 67(3) (2012) 297-300.
[43] Liming Fu, Huanrong Wang, Wei Wang, Aidang Shan*, Austenite grain growth prediction coupling with drag and pinning effects in low carbon Nb microalloyed steels, Materials Science and Technology 27(6) (2011) 996-1001.
[44] Liming Fu, Aidang Shan, Wei Wang, Effect of Nb solute drag and NbC precipitate pinning on the recrystallization grain growth in low carbon Nb-microalloyed steel, Acta Metallurgica Sinica 46(7) (2010) 832-837.

专利著作

超高强度高塑性低碳相变与孪晶诱发塑性热轧钢板及制法 CN102296232B 付立铭, 单爱党
一种Nb、Ti合金化低碳高强度高塑性TWIP钢及制备方法 CN102312158B 付立铭, 单爱党
一种超细结构高强度Ti 6Al 4V合金板材的制备方法 CN105112832B 李志明, 孙衍乐, 付立铭, 单爱党, 查民中, 周友方
一种超细晶高熵合金的制备方法 CN108179343B 李紫勇*, 付立铭, 单爱党
超高强度高韧性耐蚀耐氧化超细晶合金钢及其制备方法 CN107779746B 郑晗*, 付立铭, 单爱党
高强韧超细双相片层结构QAl10-4-4铝青铜合金的板材的制备方法 CN109136804B 马硕*, 付立铭, 单爱党
一种超细结构高强韧薄带铝的制备方法 CN110983213B 付立铭, 单爱党
一种循环轧制高强高韧双相钢制备方法 CN111041178B 庞卓锐*, 付立铭, 单爱党
一种超高强度高韧性合金钢及其制备方法 CN110306127B 庞卓锐*, 付立铭, 单爱党
超高强度高韧性超细组织结构空冷硬化钢板材及其制备工艺 CN112063921B 冀新波*, 付立铭, 单爱党
一种提升镍铝青铜合金强度和韧性的热处理工艺方法 CN 115044747 B 马硕*, 杨晓斌*, 付立铭, 单爱党
一种新型1500MPa无铍超级高强高韧铜合金及其制备方法 CN 114990380 B 马硕*, 付立铭, 单爱党
一种超高强高韧超细组织低碳低合金钢及其制备方法 CN 115074637 B 刘宇轩*, 付立铭, 单爱党
一种超大挖掘机用耐磨斗齿的热处理方法 CN116377189B 王勇, 付立铭, 张志洋, 徐筱慧, 单爱党
一种获取焊接材料非线性混合硬化模型的方法 CN 114121189 B 徐济进, 付立铭, 袁勇, 尹宏飞, 单爱党, 谷月峰
一种抗菌高强韧铜改性建水紫陶及其制备方法 CN 116179920 B 马硕, 付立铭, 单爱党
一种易于铆接的新能源汽车用再生铝压铸件及其制备方法 CN 117363906 B 付立铭, 沈耀, 单爱党

付立铭 副研究员

付立铭
副研究员