孙聪，长聘副教授，博导，沈阳市高层次人才“拔尖人才”，中国机械工程学会生产工程分会（光整加工领域）委员，辽宁省机械工程学会表面工程分会秘书长，国家自然基金同行评议专家，EI《表面技术》青年编委,EI《Surface Science and Technology》青年编委，《Intelligent and Sustainable Manufacturing》编委，《金刚石与磨料磨具工程》编委，教育部学位论文评审专家

邮箱：suncong1@mail.neu.edu.cn; a20082051@163.com

电话：024-83689002，13022406322

教育背景：

2008.9-2012.7，东北大学，机械工程及自动化，学士

2012.9-2014.7，东北大学，机械设计及理论，硕士

2014.9-2015.7，中国航发黎明，机械工程师

2015.9-2019.10，东北大学，机械设计及理论，博士

工作经历：

2020-2021，东北大学，现代传动与数字化技术研究所，讲师.

2022，东北大学，现代传动与数字化技术研究所，副研究员.

2023至今，东北大学，现代传动与数字化技术研究所，副教授.

研究方向：

航空材料表面抗疲劳智能制造技术；半导体材料多能场辅助制造；涂层表面改性；增材制造；磨削与磁流变抛光技术

主讲课程：机械设计基础；机械设计基础课程设计

项目情况：

主持国家自然基金两项（青年、面上）

主持中国博士后基金面上项目

主持辽宁省自然基金面上项目一项

主持基本科研业务费三项

主持东北大学博士后基金一项

主持国家重点实验室项目一项

主持省重点实验室项目两项

主持企业横向二项

参与国家自然基金三项，参与辽宁省教改项目一项

获奖情况：苏州市东吴科技领军人才；博士研究生国家奖学金；2021年度东北大学优秀博士后；2021年度东北大学优秀博士论文；2021年度机械学院个人贡献奖；2022年获得沈阳市自然学术成果二等奖。2021年，2022年度国内EI杂志《表面技术》优秀作者；2022年度辽宁省第五届研究生材料先进连接技术论坛一等奖

课题组硕士就业去向：一汽大众，华晨宝马，606所，沈飞，中国电子集团研究所，中车常州戚墅堰研究所等。

设备情况：配套多种加工及检测设备，如：高温炉、混粉机、干燥机、疲劳试验机、拉伸试验机、切割机、球磨机、电化学抛光机、伺服磨床、线锯床、激光器、铺粉3D打印设备、磨抛机、磁流变抛光机、显微硬度仪、电化学工作站、残余应力仪、粗糙度仪、测力仪、高温红外热像仪、金相显微镜、超景深显微镜、共聚焦显微镜以及计算机工作站等，且与自动化所保持深度合作。

论文情况：以第一作者/通讯作者在IJMS、JMP、JAC、JMRT、ACME、IJMMD、JMPT、Cirp Procedia、IJAMT、东北大学学报及表面技术等国内外高水平SCI/EI期刊发表论文50余篇，其中SCI论文40余篇，同时担任IJMTM、IJMS、JMP、Measurement、Engineering Computations、IJAMT等国际SCI期刊审稿人。部分论文：

1. Sun C, Xiu S, Hong Y, et al. Prediction on residual stress with mechanical-thermal and transformation coupled in DGH [J]. International Journal of Mechanical Sciences. 2020, 179, 105629. (1区)

2. Sun C, Duan J, Lan D, et al. Prediction about ground hardening layers distribution on grinding chatter by contact stiffness [J]. Archives of Civil and Mechanical Engineering. 2018, 18(4), 1626-1642. (1区)

3. Sun C, Xiu S, Li Q, et al. Research on the embossment phenomenon of disc grinding by workpiece's removal rate [J]. Archives of Civil and Mechanical Engineering. 2019, 19(3), 739-755. (1区)

4. Sun C, Hong Y, Xiu, S, et al. Grain refinement mechanism of metamorphic layers by abrasive grinding hardening [J]. Journal of Manufacturing Processes. 2021, 69, 125-141. (1区)

5. Sun C, Lu Y, Xiu S, et al. Analysis on the removal mechanism of disc grinding based on dynamic thermal–mechanical coupling [J]. International Journal of Mechanics and Materials in Design. 2021. (1区)

6. Sun C, Hong Y, Xiu S, et al. Complicated microstructure transformation mechanism of the greenly grinding coating layer [J]. Journal of Materials Research and Technology. 2022. (1区)

7. Sun C, Xiu S, Zhang P, et al. Influence of the dynamic disc grinding wheel displacement on surface generation [J]. Journal of Manufacturing Processes. 2022. (1区)

8. Sun C, Hong Y, Xiu S, et al. Surface strengthening mechanism of the active grinding carburization [J]. Tribology International. 2023. (1区)

9. Hong Y, Xiu S, Sun C*, et al. Metallographic method for temperature measurement: Reconstruction of grinding temperature field based on critical austenitizing depth and cyclic feedback algorithm [J]. Journal of Materials Processing Technology. 2022. (1区)

10. Yao Y, Xiu S, Sun C*, et al. Investigation on grinding-induced dynamic recrystallization behavior of 40Cr alloy steel [J]. Journal of Alloys and Compounds. 2021, 867, 158773. (1区)

11. Hong Y,Sun C*, Xiu S, et al. Strengthening surface generation mechanism of carburizing-assisted grinding. Tribology International. 2023, 180, 108300. (1区)

12. Hong Y, Sun C*, Xiu S,et al. Grinding residual stress optimization under the micro-carburizing effect. Tribology International. 2023,188,108807.(1区)

13. Hong Y, Liang C, Sun C*, et al. 20CrMnTi surface strengthening based on laser-assisted carburizing grinding. Materials Characterization. 2024,208,113631. (1区)

14. Hong Y, Sun C*, Ma L, et al. Properties-accuracy Synergistic Manufacturing of Ti6Al4V Surface based on Laser Carburizing Grinding. Tribology International. 2024,109329.(1区) 

15. Zhang H, Sun C*, Hong Y, et al. Aluminum Nitride Surface Modification Mechanism by Laser Ultrasonic-assisted Grinding. Tribology International. 2024,109718.(1区)

16. Hong Y, Sun C*, Guo Q, et al. High-performance Ti6Al4V surface manufacture by laser carburising-assisted grinding. Tribology International. 2024,109912.(1区)

17. Zou X, Sun C*, Zhang J, et al. A simulation method for surface height distribution of end-face grinding workpieces. Journal of Manufacturing Processes. 2024,131.(1区)

18. Hong Y, Sun C*,Wang D, et al. Integrated laser alloying-grinding for additive-subtractive manufacturing of Ti6Al4V surface with B4C coating. Tribology International. 2025,110537.(1区)

19. Sun C, Lu Y, Feng W, et al. The grinding carburization surface removal mechanism considering mechanical-thermal effect and carbon diffusion hardening. Frontiers of Mechanical Engineering. 2025.(1区)

20. Hong Y, Sun C*, Zhang H, et al. Ti6Al4V laser carburizing grinding surface generation considering carbide distribution. Journal of Manufacturing Processes. 2025,145,454-466.(1区)

21. Hong Y, Sun C*, Feng J, et al. Additive-subtractive hybrid manufacturing of Ti6Al4V surfaces with graphite-B4C composite coatings. Tribology International. 2025, 110795.(1区)

22. Cheng Z, Sun C*, Duan M, et al. Research on surface magnetorheological polishing technology for optical grade components. Precision Engineering. 2026, 97.(1区)

23. Yang Z,Sun C*,Wang,D,et al.Ti6Al4V surface evolution mechanism by laser-induced multi-element infiltration grinding.Surface and Coatings Technology.2026,521,133110.(1区)