潘宇
副研究员、硕士生导师
电子邮件: panyu@ustb.edu.cn
科研方向
航空航天用钛合金材料制造
注射成形、增材制造等近净成形技术
轻质耐热钛基复合材料及钛铝合金
粉末冶金钛材料塑性加工理论及应用
基于数据驱动的钛基新材料开发
注射成形、增材制造等近净成形技术
轻质耐热钛基复合材料及钛铝合金
粉末冶金钛材料塑性加工理论及应用
基于数据驱动的钛基新材料开发
简历
工学博士,副研究员,入选国家博新计划、北京市科协青年托举人才,获北京市优秀博士学位论文,现任先进粉末冶金钛材料研究所副所长。香港城市大学访问学者,博士毕业于北京科技大学,长期从事粉末冶金钛材料制造技术研究。近年来主持国家自然科学基金面上项目和青年项目、国防KGJ稳定支持项目、山东省重点研发计划课题、北京市科技计划项目、中国博士后科学基金等项目20余项;以一作/通讯于Acta Mater., Corros. Sci., J. Mater. Sci. Technol.等期刊发表SCI论文60余篇;申获国家发明专利50余项;出版专著2部,制订国家/行业标准3项;担任中国有色金属学会轻合金材料专业委员会委员、北京粉末冶金研究会理事、《Progress in Natural Science: Materials International》、《Additive Manufacturing Froniters》和《工程科学学报》等期刊青年编委。学科竞赛优秀指导教师,指导研究生获得“挑战杯”北京市一等奖。
代表性著作
[1]Yu Pan, Yucheng Yang, Qingjun Zhou, Xuanhui Qu, Peng Cao, Xin Lu*, Achieving synergy of strength and ductility in powder metallurgy commercially pure titanium by a unique oxygen scavenger, Acta Materialia, 2024, 263: 119485.
[2]Yanjun Liu, Yu Pan*, Ranpeng Lu, Aihua Yu, Shuya Zhao, Jianzhuo Sun, Xin Lu*, Oxygen scavenging-driven plastic response of α2-Ti3Al in dual-phase TiAl alloy, Acta Materialia, 2026, 305: 121853.
[3]Yu Pan, Xin Lu*, Muhammad D. Hayat, Chengcheng Liu, Yang Li, Xingyu Li, Xuanhui Qu, Peng Cao, Effect of Sn addition on the high-temperature oxidation behaviour of high Nb-containing TiAl alloys, Corrosion Science, 2020, 166: 108449.
[4]Yu Pan, Jinshan Zhang, Jianzhuo Sun, Yanjun Liu, Ce Zhang, Rui Li, Fan Kuang, Xinxin Wu, Xin Lu*, Enhanced strength and ductility in a powder metallurgy Ti material by the oxygen scavenger of CaB6, Journal of Materials Science and Technology, 2023, 137: 132-142.
[5]Aihua Yu, Yu Pan*, Yanjun Liu, Tengfei Zheng, Yi Wen, Yuan Wu, Xin Lu*, Harnessing oxygen-driven phase engineering for a strong and ductile duplex titanium alloy, Advanced Composites and Hybrid Materials, 2025, 8: 425.
[6]Ranpeng Lu, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Xinxin Wu, Aihua Yu, Fan Kuang, Jiayu Li, Xin Lu*, A novel high-performance Ti6Al4V alloy scheme: achieving synergy of near-full density and fine equiaxed-grain via uncovered sintering window by pressureless sintering, Journal of Materials Science and Technology, 2026, 263: 286-298.
[7]Aihua Yu, Yu Pan*, Fucheng Wan, Fan Kang, Xin Lu*, Multi-objective optimization of laser powder bed fused titanium considering strength and ductility: A new framework based on explainable stacking ensemble learning and NSGA-II, Journal of Materials Science and Technology, 2025, 228: 241-255.
[8]Yu Pan*, Xin Lu*, Peng Cao, Microstructure evolution and mechanical properties of a novel ultrastrong and ductile PM Ti6Al4V composite, Materials Science and Engineering A, 2023, 886: 145683.
[9]Yu Pan, Ziqiang Pi, Bowen Liu, Wei Xu, Ce Zhang, Xuanhui Qu, Xin Lu*, Influence of heat treatment on the microstructural evolution and mechanical properties of W6Mo5Cr4V2Co5Nb (825 K) high speed steel, Materials Science and Engineering A, 2020, 787: 139480.
[10]Fan Kuang, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Chenxin Lei, Xin Lu*, Crafting high-strength and ductile powder metallurgy Ti6Al4V alloy with a multi-scale microstructure, Materials Science and Engineering: A, 2024, 892: 146054.
[11]Chengxin Lei, Yu Pan*, Fan Kuang, Wangtu Huo, Ming Zhu, Xin Lu*, A novel configuration design of strong and ductile (TiC + Ti5Si3) / Ti laminated composites, Materials Science and Engineering: A, 2024, 892: 145961.
[12]Peng Huang, Fan Kuang, Aihua Yu, Qingjun Zhou, Jilai Wang, Ning Guo, Yu Pan*, Xin Lu, Gradient microstructure evolution and strengthening mechanism of Ti6Al4V joint by laser additive connection, Materials Science and Engineering: A, 2025, 948: 149386.
[13]Liansheng Yue, Qingjun Zhou, Yu Pan*, Fan Kuang, Aihua Yu, Xin Lu*, Fatigue deformation behavior and fracture mechanism of high fatigue-resistant laser directed energy deposition fabricated titanium alloy: Effect of multi-scale microstructure, International Journal of Fatigue, 2024, 188: 108518.
[14]Aihua Yu, Qingjun Zhou, Yu Pan*, Fucheng Wan, Fan Kuang, Xin Lu*, Hybrid clustering-enhanced interpretable machine learning for fatigue life prediction across various cyclic stages in laser powder bed fused Ti-6Al-4V alloy, International Journal of Fatigue, 2025, 198: 108995.
[15]Fan Kuang, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Chengxin Lei, Xin Lu*, Investigating phase transformation, densification and diffusion mechanism of TiH2 powder to achieve a high ductile Ti6Al4V alloy, Journal of Materials Processing Technology, 2024, 329: 118459.
[16]Fan Kuang, Qingjun Zhou, Yu Pan*, Aihua Yu, Peng Huang, Ning Guo, Xin Lu*, A novel approach to achieving hybrid-manufactured Ti6Al4V under ultra-high power additive manufacturing, Materials and Design, 2025, 253: 114011.
[17]Yu Pan*, Yanjun Liu, Fan Kuang, Chengxin Lei, Xin Lu*, In-situ formed TiCx reinforced Ti composites derived from polyzirconocarbosilane precursor: Synthesis, characterization and mechanical properties, Materials Characterization, 2024, 217: 114365.
[18]Yu Pan, Weibin Li, Xin Lu*, Muhammad D. Hayat, Wenwen Song, Xuanhui Qu, Peng Cao, Microstructure and tribological properties of titanium matrix composites reinforced with in situ synthesized TiC particles, Materials Characterization, 2020, 170, 110633.
[19]Yu Pan, Jinshan Zhang, Fan Kuang, Ce Zhang, Yucheng Yang, Xin Lu*, Grain growth kinetics and densification mechanism of Ti/CaB6 composites by powder metallurgy pressureless sintering, Journal of Alloys and Compounds, 2023, 939: 168686.
[20]Yanjun Liu, Yu Pan*, Jianzhuo Sun, Jinshan Zhang, Fan Kuang, Xin Lu*, Metal injection molding of high-performance Ti composite using hydride-dehydride (HDH) powder, Journal of Manufacturing Processes, 2023, 89: 328-337.[21]《钛粉末近净成形技术》,副主编,冶金工业出版社,2022.
[2]Yanjun Liu, Yu Pan*, Ranpeng Lu, Aihua Yu, Shuya Zhao, Jianzhuo Sun, Xin Lu*, Oxygen scavenging-driven plastic response of α2-Ti3Al in dual-phase TiAl alloy, Acta Materialia, 2026, 305: 121853.
[3]Yu Pan, Xin Lu*, Muhammad D. Hayat, Chengcheng Liu, Yang Li, Xingyu Li, Xuanhui Qu, Peng Cao, Effect of Sn addition on the high-temperature oxidation behaviour of high Nb-containing TiAl alloys, Corrosion Science, 2020, 166: 108449.
[4]Yu Pan, Jinshan Zhang, Jianzhuo Sun, Yanjun Liu, Ce Zhang, Rui Li, Fan Kuang, Xinxin Wu, Xin Lu*, Enhanced strength and ductility in a powder metallurgy Ti material by the oxygen scavenger of CaB6, Journal of Materials Science and Technology, 2023, 137: 132-142.
[5]Aihua Yu, Yu Pan*, Yanjun Liu, Tengfei Zheng, Yi Wen, Yuan Wu, Xin Lu*, Harnessing oxygen-driven phase engineering for a strong and ductile duplex titanium alloy, Advanced Composites and Hybrid Materials, 2025, 8: 425.
[6]Ranpeng Lu, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Xinxin Wu, Aihua Yu, Fan Kuang, Jiayu Li, Xin Lu*, A novel high-performance Ti6Al4V alloy scheme: achieving synergy of near-full density and fine equiaxed-grain via uncovered sintering window by pressureless sintering, Journal of Materials Science and Technology, 2026, 263: 286-298.
[7]Aihua Yu, Yu Pan*, Fucheng Wan, Fan Kang, Xin Lu*, Multi-objective optimization of laser powder bed fused titanium considering strength and ductility: A new framework based on explainable stacking ensemble learning and NSGA-II, Journal of Materials Science and Technology, 2025, 228: 241-255.
[8]Yu Pan*, Xin Lu*, Peng Cao, Microstructure evolution and mechanical properties of a novel ultrastrong and ductile PM Ti6Al4V composite, Materials Science and Engineering A, 2023, 886: 145683.
[9]Yu Pan, Ziqiang Pi, Bowen Liu, Wei Xu, Ce Zhang, Xuanhui Qu, Xin Lu*, Influence of heat treatment on the microstructural evolution and mechanical properties of W6Mo5Cr4V2Co5Nb (825 K) high speed steel, Materials Science and Engineering A, 2020, 787: 139480.
[10]Fan Kuang, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Chenxin Lei, Xin Lu*, Crafting high-strength and ductile powder metallurgy Ti6Al4V alloy with a multi-scale microstructure, Materials Science and Engineering: A, 2024, 892: 146054.
[11]Chengxin Lei, Yu Pan*, Fan Kuang, Wangtu Huo, Ming Zhu, Xin Lu*, A novel configuration design of strong and ductile (TiC + Ti5Si3) / Ti laminated composites, Materials Science and Engineering: A, 2024, 892: 145961.
[12]Peng Huang, Fan Kuang, Aihua Yu, Qingjun Zhou, Jilai Wang, Ning Guo, Yu Pan*, Xin Lu, Gradient microstructure evolution and strengthening mechanism of Ti6Al4V joint by laser additive connection, Materials Science and Engineering: A, 2025, 948: 149386.
[13]Liansheng Yue, Qingjun Zhou, Yu Pan*, Fan Kuang, Aihua Yu, Xin Lu*, Fatigue deformation behavior and fracture mechanism of high fatigue-resistant laser directed energy deposition fabricated titanium alloy: Effect of multi-scale microstructure, International Journal of Fatigue, 2024, 188: 108518.
[14]Aihua Yu, Qingjun Zhou, Yu Pan*, Fucheng Wan, Fan Kuang, Xin Lu*, Hybrid clustering-enhanced interpretable machine learning for fatigue life prediction across various cyclic stages in laser powder bed fused Ti-6Al-4V alloy, International Journal of Fatigue, 2025, 198: 108995.
[15]Fan Kuang, Yu Pan*, Jianzhuo Sun, Yanjun Liu, Chengxin Lei, Xin Lu*, Investigating phase transformation, densification and diffusion mechanism of TiH2 powder to achieve a high ductile Ti6Al4V alloy, Journal of Materials Processing Technology, 2024, 329: 118459.
[16]Fan Kuang, Qingjun Zhou, Yu Pan*, Aihua Yu, Peng Huang, Ning Guo, Xin Lu*, A novel approach to achieving hybrid-manufactured Ti6Al4V under ultra-high power additive manufacturing, Materials and Design, 2025, 253: 114011.
[17]Yu Pan*, Yanjun Liu, Fan Kuang, Chengxin Lei, Xin Lu*, In-situ formed TiCx reinforced Ti composites derived from polyzirconocarbosilane precursor: Synthesis, characterization and mechanical properties, Materials Characterization, 2024, 217: 114365.
[18]Yu Pan, Weibin Li, Xin Lu*, Muhammad D. Hayat, Wenwen Song, Xuanhui Qu, Peng Cao, Microstructure and tribological properties of titanium matrix composites reinforced with in situ synthesized TiC particles, Materials Characterization, 2020, 170, 110633.
[19]Yu Pan, Jinshan Zhang, Fan Kuang, Ce Zhang, Yucheng Yang, Xin Lu*, Grain growth kinetics and densification mechanism of Ti/CaB6 composites by powder metallurgy pressureless sintering, Journal of Alloys and Compounds, 2023, 939: 168686.
[20]Yanjun Liu, Yu Pan*, Jianzhuo Sun, Jinshan Zhang, Fan Kuang, Xin Lu*, Metal injection molding of high-performance Ti composite using hydride-dehydride (HDH) powder, Journal of Manufacturing Processes, 2023, 89: 328-337.[21]《钛粉末近净成形技术》,副主编,冶金工业出版社,2022.
获奖
[1]2022年06月 中国博士后创新人才支持计划
[2]2024年02月 北京市科协青年托举人才
[3]2024年12月 北京市优秀博士学位论文
[4]2025年11月 中国有色金属工业科学技术一等奖
[5]2023年06月 教育部技术发明二等奖
[6]2020年10月 中国发明协会发明创新一等奖(金奖)
[7]2021年06月 北京科技大学“校长奖章”
[8]2021年11月 中国国际“互联网+”创新创业大赛国赛银奖
[2]2024年02月 北京市科协青年托举人才
[3]2024年12月 北京市优秀博士学位论文
[4]2025年11月 中国有色金属工业科学技术一等奖
[5]2023年06月 教育部技术发明二等奖
[6]2020年10月 中国发明协会发明创新一等奖(金奖)
[7]2021年06月 北京科技大学“校长奖章”
[8]2021年11月 中国国际“互联网+”创新创业大赛国赛银奖
专利
[1]潘宇,吴鑫鑫,路新,刘艳军,况帆,粉末粒度极配方法和钛及钛合金复杂薄壁件及其制备方法,中国发明专利,ZL 202211373878.9.
[2]潘宇,刘艳军,路新,朱郎平,细晶高致密TiAl合金制件及其制备方法,中国发明专利,ZL 202310376256.1.
[3]潘宇,刘艳军,路新,基于机器学习的高性能多元TiAl基合金成分设计方法,中国发明专利,ZL 202311041945.3.
[4]潘宇,李家瑜,况帆,路新,高疲劳寿命钛合金制件及其制备方法,中国发明专利,CN 202510501555.2.
[5]潘宇,黄鹏,路新,于爱华,增材制造用钛基粉末、高疲劳寿命钛基制件及其制备方法,中国发明专利,CN 202511322960.4.
[6]潘宇,于爱华,况帆,路新,基于小样本机器学习的增材制造制件疲劳性能预测方法,中国发明专利,CN 202511474718.9.
[7]潘宇,陆冉鹏,路新,注射成形用钛合金粉末、注射成形钛合金制件及其制备方法,中国发明专利,CN 202511322963.8.
[8]潘宇,况帆,路新,间隙氮原子强化的超高强双相钛合金制件及其制备方法,中国发明专利,CN 202510585518.4.
[9]潘宇,岳连生,况帆,路新,周庆军,低氧微球形钛粉和钛制件的增等复合制造及热处理方法,中国发明专利,CN 202311743875.6.
[10]潘宇,路新,许国庆,钛基复合材料的分析方法、存储介质和钛制件及制备方法,中国发明专利,CN 202211578083.3.
[2]潘宇,刘艳军,路新,朱郎平,细晶高致密TiAl合金制件及其制备方法,中国发明专利,ZL 202310376256.1.
[3]潘宇,刘艳军,路新,基于机器学习的高性能多元TiAl基合金成分设计方法,中国发明专利,ZL 202311041945.3.
[4]潘宇,李家瑜,况帆,路新,高疲劳寿命钛合金制件及其制备方法,中国发明专利,CN 202510501555.2.
[5]潘宇,黄鹏,路新,于爱华,增材制造用钛基粉末、高疲劳寿命钛基制件及其制备方法,中国发明专利,CN 202511322960.4.
[6]潘宇,于爱华,况帆,路新,基于小样本机器学习的增材制造制件疲劳性能预测方法,中国发明专利,CN 202511474718.9.
[7]潘宇,陆冉鹏,路新,注射成形用钛合金粉末、注射成形钛合金制件及其制备方法,中国发明专利,CN 202511322963.8.
[8]潘宇,况帆,路新,间隙氮原子强化的超高强双相钛合金制件及其制备方法,中国发明专利,CN 202510585518.4.
[9]潘宇,岳连生,况帆,路新,周庆军,低氧微球形钛粉和钛制件的增等复合制造及热处理方法,中国发明专利,CN 202311743875.6.
[10]潘宇,路新,许国庆,钛基复合材料的分析方法、存储介质和钛制件及制备方法,中国发明专利,CN 202211578083.3.
科研项目
[1]国家自然科学基金面上项目,基于间隙氮原子强化的1500MPa级超高强Ti6Al4V合金制备及其强韧化机理研究,2026.01至2029.12,主持
[2]国家自然科学基金青年项目,新型近球形钛粉整形改性及其约束钝化机制研究,2024.01至2026.12,主持;
[3]山东省重点研发计划课题,新一代航天飞行器关键结构件高效低成本增材制造及产业化应用,2025.07至2028.06,主持;
[4]国防KGJ稳定支持课题,钛合金粉末烧结坯高温塑性变形行为及热处理强韧化机理研究,2024.01至2026.12,主持;
[5]北京市科技计划项目课题,航天用半固态球化钛合金及制件关键技术开发,2024.10至2026.09,主持;
[6]中国博士后创新人才支持计划项目,粉末冶金钛合金烧结控氧机理及其近终形制造应用基础研究,2022.07至2024.12,主持;
[7]中国博士后科学基金面上项目,氢致钛粉末坯烧结组织优化及其粉末锻造成形基础研究,2022.12至2024.12,主持;
[8]中央高校基本科研业务经费人才引进项目,粉末钛合金注射成形技术及应用研究,主持;
[9]新金属材料国家重点实验室开放基金,TiAl合金粉末强化烧结致密化机理及其注射成形技术研究,主持;
[10]校企合作项目,激光选区熔化成形钛合金断裂韧性、疲劳性能研究,主持;
[11]校企合作项目,激光熔化沉积增材制造钛合金低周疲劳性能研究,主持;
[12]校企合作项目,Ti2AlNb复合粉体包套热等静压技术研究,主持。
[2]国家自然科学基金青年项目,新型近球形钛粉整形改性及其约束钝化机制研究,2024.01至2026.12,主持;
[3]山东省重点研发计划课题,新一代航天飞行器关键结构件高效低成本增材制造及产业化应用,2025.07至2028.06,主持;
[4]国防KGJ稳定支持课题,钛合金粉末烧结坯高温塑性变形行为及热处理强韧化机理研究,2024.01至2026.12,主持;
[5]北京市科技计划项目课题,航天用半固态球化钛合金及制件关键技术开发,2024.10至2026.09,主持;
[6]中国博士后创新人才支持计划项目,粉末冶金钛合金烧结控氧机理及其近终形制造应用基础研究,2022.07至2024.12,主持;
[7]中国博士后科学基金面上项目,氢致钛粉末坯烧结组织优化及其粉末锻造成形基础研究,2022.12至2024.12,主持;
[8]中央高校基本科研业务经费人才引进项目,粉末钛合金注射成形技术及应用研究,主持;
[9]新金属材料国家重点实验室开放基金,TiAl合金粉末强化烧结致密化机理及其注射成形技术研究,主持;
[10]校企合作项目,激光选区熔化成形钛合金断裂韧性、疲劳性能研究,主持;
[11]校企合作项目,激光熔化沉积增材制造钛合金低周疲劳性能研究,主持;
[12]校企合作项目,Ti2AlNb复合粉体包套热等静压技术研究,主持。