孙彬涵
E-mail: binhan.sun@ecust.edu.cn
职称: 教授、博士生导师
地址: 上海市梅陇路130号 实验17楼425室
网站:https://www.researchgate.net/profile/Binhan-Sun
https://www.mpie.de/4604692/hydrogen_embrittlement
欢迎机械与材料领域优秀学子报考硕士/博士研究生
个人简介:
教育经历:
2013.09-2018.05:加拿大麦吉尔大学,博士(导师:Stephen Yue教授)
2011.09-2013.07:东北大学,硕士(导师:姜周华教授)
2007.09-2011.06:东北大学,学士
工作经历:
2023.01 至今:教授,3354cc金沙集团
2021.09 至今(兼职):客座教授,高性能合金氢致断裂研究组组长 (External Group Leader),德国马克斯普朗克钢铁研究所
2021.12-2023.01:特聘研究员,3354cc金沙集团
2020.07-2021.09:合金原理与设计课题组副组长 (Deputy Group Leader),德国马克斯普朗克钢铁研究所
2018.03-2020.03:洪堡学者、博士后 (Host:Dierk Raabe教授),德国马克斯普朗克钢铁研究所
致力于研究高性能金属损伤失效行为和抗损伤强韧性设计,研究服务于航空航天、新能源、汽车等重大领域。德国洪堡学者、国家高层次青年人才、上海海外高层次人才。先后主持/承担了国家自然科学基金委、科技部、工信部、德国洪堡基金会、加拿大工务及政府服务部等多项国家级研究项目。担任5个SCI期刊的编委/青年编委/客座编辑,波兰和加拿大科学基金的评审人,以及 Acta Mater. 等超过30个材料和机械领域权威期刊的独立审稿人。在Nature、Science、Nature Materials、PNAS、Nature Communications、Science Advances、Acta Mater.(金属材料领域顶刊)等领域内顶级期刊发表文章70余篇,入选2023年度全球前2%高被引科学家,多次担任国际/国内学术会议分会主席并做特邀报告。
课题组长期与德国、加拿大、挪威、英国、美国、澳大利亚等国际著名高校与研究院所保持科研合作与学术交流。
研究方向
研究服务于航空航天、新能源、汽车等重大领域,具体方向如下:
1. 氢能装备与材料
2. 金属氢致损伤断裂
3. 金属抗损伤强韧性设计
4. 特种材料先进制造
5. 材料基因工程
6. 先进高强度汽车钢等
研究方法包括宏微观尺度表征与测试、机器学习、数值模拟等
荣誉奖励
1. 金属材料顶刊Acta Mater/Scripta Mater 杰出审稿人(2022)
2. 德国马普协会奖金 (2020)
3. 德国洪堡学者(2018)
3. 加拿大自然科学与工程研究委员会奖金(2016)
4. Graduate Excellence Awards, 麦吉尔大学(2016)
5. Metall. Mater. Trans. A 编辑推荐文章(2016)
6. 中国国家奖学金(2012)
7. 挑战杯辽宁省特等奖(2012)
代表性著作
*通讯作者
1. W. Peng, X. Li, J. Gao, C. He, Y. Zhang, T. Lu, X-C. Zhang*, L. Zhang*, B. Sun*, S-T. Tu, Abnormal grain growth behavior in gradient nanostructured titanium investigated by coupled quasi-in-situ EBSD experiments and phase-field simulations, Acta Materialia, 276 (2024), 120141.
2. Y. Zhang, C. He, Q. Yu, X. Li, X. Wang, Y. Zhang, J. Wang, C. Jiang, Y. Jia, X-C. Zhang*, B. Sun*, R. O. Ritchie, S-T. Tu, Nacre-like surface nanolaminates enhance fatigue resistance of pure titanium, Nature Communications, 15 (2024), 6917.
3. F. Wang, M. Song, M. N. Elkot, N. Yao, B. Sun, M. Song*, Z. Wang*, D. Raabe*, Shearing brittle intermetallics enhances cryogenic strength and ductility of steels, Science, 284 (2024), 1017-1022.
4. B. Sun*, H. Zhao, X. Dong, C. Teng, A. Zhang, S. Kong, J. Zhou, X-C. Zhang, S-T. Tu*, Current challenges in the utilization of hydrogen energy-a focused review on the issue of hydrogen-induced damage and embrittlement, Advances in Applied Energy, 14 (2024), 100168
5. H. Shi*, S. Nandy, H. Cheng, B. Sun*, D. Ponge, In-situ investigation of the interaction between hydrogen and stacking faults in a bulk austenitic steel, Acta Materialia, 262 (2024), 119441.
6. H. Cheng, X. Lu, J. Zhou, T. Lu, B. Sun*, X-C. Zhang*, S-T. Tu, The influence of L12 ordered precipitates on hydrogen embrittlement behavior in a CoCrNi-based medium entropy alloys, Acta Materialia, 260 (2023), 119328.
7. B. Sun*, A. K. da Silva, Y. Wu, Y. Ma, H. Chen, C. Soctt, D. Ponge, D. Raabe, Physical metallurgy of medium-Mn advanced high strength steels, International Materials Reviews, 68 (2023), 786-824.
8. N. Yao, T. Lu*, K. Feng, B. Sun*, R. Wang, J. Wang, Y. Xie, P. Zhao, B. Han, X. Zhang*, S-T. Tu, Ultrastrong and ductile additively manufactured precipitation-hardening medium-entropy alloy at ambient and cryogenic temperatures, Acta Materialia, 236 (2022), 118142.
9. M. N. Elkot*, B. Sun*, X. Zhou, D. Ponge, D. Raabe, Hydrogen-assisted decohesion associated with nanosized grain boundary κ-carbides in a high-Mn lightweight steel , Acta Materialia, 241 (2022), 118392.
10. X. Dong, D. Wang, P. Sukumar, A. Tehranchi, D. Ponge, B. Sun*, D. Raabe, Hydrogen-associated decohesion and localized plasticity in a high-Mn and high-Al two-phase lightweight steel, Acta Materialia, 239 (2022), 118296.
11. X. Wang , C. Liu , B. Sun*, D. Ponge, C. Jiang*, D. Raabe, The dual role of martensitic transformation in fatigue crack growth, Proceedings of the National Academy of Sciences of the United States of America (PNAS), 119 (2022), No. 9 e2110139119.
12. H. Zhao*, P. Chakraborty, D. Ponge, T. Hickel, B. Sun, B. Gault*, D. Raabe*, Hydrogen trapping and embrittlement in high-strength Al-alloys: an atomic-scale perspective, Nature, (602) 2022, 437-441.
13. B. Sun*, W. Lu, B. Gault, R. Ding, S.K. Makineni, D. Wan, C-H. Wu, H. Chen, D. Ponge, D. Raabe*, Chemical heterogeneity enhances hydrogen resistance in high-strength steels, Nature Materials, 20 (2021), 1629-1634.
14. B. Sun*,W. Krieger, M. Rohwerder, D. Ponge**, D. Raabe, Dependence of hydrogen embrittlement mechanisms on microstructure-driven hydrogen distribution in medium Mn steels, Acta Materialia, 183 (2020), 313-328.
15. Y. Ma*, B. Sun*, A. Schokel, W. Song, D. Ponge, D. Raabe, W. Bleck, Phase boundary segregation-induced strengthening and discontinuous yielding in ultrafine-grained duplex medium-Mn steels, Acta Materialia, 200 (2020), 389–403.
16. R. Ding, Y. Yao, B. Sun, G. Liu, J. He, T. Li, X. Wan, Z. Dai, D. Ponge, D. Raabe, C. Zhang, A.Godfrey, G. Miyamoto, T. Furuhara, Z. Yang, S. van der Zwaag, H. Chen*, Chemical boundary engineering: a new route towards lean, ultrastrong yet ductile steels, Science Advances, (6) 2020, eaay1430.
17. B. Sun*,Y. Ma, N. Vanderesse, R.S. Varanasi, W. Song, P. Bocher, D. Ponge**, D. Raabe, Macroscopic to nanoscopic in situ investigation on yielding mechanisms in ultrafine grained medium Mn steels: Role of the austenite-ferrite interface, Acta Materialia, 178 (2019), 10-25.
18. B. Sun*, D. Palanisamy, D. Ponge**, B. Gault, F. Fazeli, C. Scott, S. Yue, D. Raabe, Revealing fracture mechanisms of medium manganese steels with and without delta-ferrite, Acta Materialia, 164 (2019), 683-696.
19. B. Sun*, F. Fazeli, C. Scott, N. Brodusch, R. Gauvin, S. Yue, The influence of silicon additions on the deformation behavior of austenite-ferrite duplex medium manganese steels, Acta Materialia,148 (2018), 249-262.
全部文章列表见:https://scholar.google.com/citations?user=t2eE248AAAAJ&hl=en