叶畅

师资队伍

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叶畅教授

电　　话

邮　　箱cye@hust.edu.cn

办公地点先进制造大楼东楼C514

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个人简介

       叶畅（Ye Chang，Professor），教授，博士生导师，ASME Fellow。武汉科技大学本科，华中科技大学硕士，美国普渡大学博士。2013年8月起任职于美国阿克伦大学机械工程系，2018年荣获美国国家科学基金委CAREER Award，2019年1月经阿克伦大学工学院学术委员会评选为tenured Associate Professor。2020年1月开始在华中科技大学工作。近年来在Acta Materialia, International Journal of Machine Tool and Manufacture, International Journal of Fatigue等国际权威期刊发表论文100余篇。在激光冲击强化、超声冲击强化、难加工金属电致塑性等领域开展了较为系统的研究，在多能量场加工过程中材料的残余应力和微观结构的演化等方向取得了一定成果。
       招收2026年秋季入学的硕士生、博士生。

研究方向

激光冲击强化、激光辅助先进制造、残余应力工程、失效分析

开设课程

本科生课程：《机械原理》

科研项目

[1] 基于电磁塑性的钛合金超声冲击强化机理研究（国家自然科学基金面上项目）
[2] 钛合金叶片脉冲电流辅助激光冲击强化（国家自然科学基金面上项目）
[3] 航发叶片和轴承制造过程电磁复合场辅助形性调控技术（国家重点研发计划子课题）

论文专著与专利

[1] Y. Yang, Y. Zhang, C. Ding, G. Liu, H Ma, L Jin, H. Ding, C. Ye*, J. Wang*, 2025, Enhancing the activity of <c+a> dislocations in Mg alloys via high-energy pulsed current Acta Materialia, 296: 121268. 

[2] W. Zhao*, Y. Dong, C. Ye, J. Zhao*, 2025, Simultaneously improving corrosion and fatigue resistance of A100 steel by laser assisted ultrasonic nanocrystal surface modification, International Journal of Fatigue, 199: 109056. 

[3] Z. Xu, L. Xu, W. Liu, J. Li, J. Wu, W. Zhou, X. Zhang, D. Zhang*, C. Ye*, Han Ding, 2025, Improving surface integrity of aero-engine blades using ultrasonic surface rolling processing, Journal of Materials Engineering & Performance, 34: 9198–9211. 

[4] Y. Zhang, L. Peng, Y. Ye, Y. Chi, L. Gao, X. Zha, T. Huang*, Y.K. Zhang, H. Ding, C. Ye*, 2025, Exploring the strengthening mechanisms of additive manufactured metals treated by ultrasonic nanocrystal surface modification, International Journal of Fatigue, 190: 108609.

[5] B. Huang, L. Xu, C. Tang, Y. Yang, J. Wu, Y. Zhang, Y. Ye, T. Huang, C. Ye*, H. Ding, 2025, Magnetic-assisted laser shock peening of 7075-T6 aluminum alloy, Optics and Laser Technology, 181:111923.

[6] K. Wang, B. Huang, Y. Ye, L. Gao, E Zhou, S. Zou*, C. Ye*, 2025, Effect of laser shock peening on the microstructure and fatigue properties of 2060 Al–Li alloy with hole structures, Optics and Laser Technology, 181:111832. 

[7] Y. Yang, T. Huang, C. Ye*, H. Ding, 2025, Recent Progress in Ultrasonic Surface Rolling: A Comprehensive Overview, Advanced Engineering Materials, Volume26, Issue22: 2401100.

[8] C. Tang, D. Zhang, F. Wang, F. Yin, D. Qian, K. Li, Z. Cai, T. Huang*, X. Zhang, J. Wang, C. Ye*, H. Ding, Effects of Magnetic Intensity on the Machining Quality and Tool Damage in Nickel-based Superalloys subjected to Magnetic-assisted Cutting, 2024, Journal of Materials Processing Technology, 331:118494.

[9] Y. Yang, R. Qin, Y. Dong, J. Wang*, C. Ye*, 2023, Crystal plasticity modeling of electropulsing induced plasticity in metals, International Journal of Plasticity, 171:103828. 

[10] Y. Ye, Y. Zhang, T. Huang, S. Zou, Y. Dong, H. Ding, V.K. Vasudevan, C. Ye*, 2023, A Critical Review of Laser Shock Peening of Aircraft Engine Components, Advanced Engineering Materials, 2023:2201451. 

[11] X. Li, J. Zhao, Y. Ye, Z. Xu, G. Liu, X. Luo, X. Wang, Y. Dong, T. Huang*, C. Ye*, H. Ding, 2023, Multi-objective optimization of laser shock peening based on an analytical model, International Journal of Fatigue, 172: 107640. 

[12] J. Yang, D. Liu*, K. Fan, Y. Liu, Z. Ren, D. Liu, X. Xu, T. Jia, H. Zhang, C. Ye, 2022, Designing a gradient structure in a Ni-based superalloy to improve fretting fatigue resistance at elevated temperatures through an ultrasonic surface rolling process, International Journal of Fatigue, 168:107397. 

[13] W. Zhao, D. Liu*, H. Zhang, J. Liu, C. Ma, R. Zhang, T. Huang, Y. Dong, C. Ye*, H. Ding, 2022, Improving peening efficacy through high-amplitude short duration pulsed current, Journal of Alloys and Compounds, 926:166987. 

[14] R. Zhang, W. Zhao, H. Zhang, W. Yang, G.X. Wang, Y. Dong*, C. Ye*, 2021, Fatigue Performance Rejuvenation of Corroded 7075-T651 Aluminum Alloy Through Ultrasonic Nanocrystal Surface Modification, International Journal of Fatigue, 153:106463.

[15] W. Zhao, D. Liu*, J. Yang, H. Zhang, C. Ma, X.H. Zhang, Z. Ren, R. Zhang, Y. Dong, C. Ye*, 2021, Improving Plain and Fretting Fatigue Resistance of A100 Steel Using Ultrasonic Nanocrystal Surface Modification, International Journal of Fatigue, 148: 106204. 

[16] Z. Ren, R. Chiang, H. Qin, V.K. Vasudevan, G.L. Doll*, Y. Dong, C. Ye*, 2020, Tribological performance of 52100 steel subjected to Boron-doped DLC coating and ultrasonic nanocrystal surface modification, Wear, 458–459: 203398. 

[17] Z. Ren, H. Qin, Y. Dong, G.L. Doll*, C. Ye*, 2019, A boron-doped diamond like carbon coating with high hardness and low friction coefficient, Wear, 436–437: 203031. 

[18] H. Zhang, Z. Ren, J. Liu, J. Zhao, Z. Liu, D. Lin, R. Zhang, M.J. Graber, N.K. Thomas, Z.D. Kerek, G.-X. Wang, Y. Dong*, C. Ye*, 2019, Microstructure evolution and electroplasticity in Ti64 subjected to electropulsing-assisted laser shock peening, Journal of Alloys and Compounds, 802:573-582.  

[19] W. Zhao, D. Liu*, X. Zhang, Y. Zhou, R. Zhang, H. Zhang, C. Ye*, 2019, Improving the fretting and corrosion fatigue performance of 300M ultra-high strength steel using the ultrasonic surface rolling process, International Journal of Fatigue, 121:30-38. 

[20] J. Liu, S. Suslov, Z. Ren, Y. Dong*, C. Ye*, 2019, Microstructure Evolution in Ti64 Subjected to Laser-assisted Ultrasonic Nanocrystal Surface Modification, International Journal of Machine Tool and Manufacture, 136:19-33.

[21] H. Zhang, J. Zhao, J. Liu, H. Qin, Z. Ren, G.L. Doll, Y. Dong*, C. Ye*, 2018, The Effects of Electrically-assisted Ultrasonic Nanocrystal Surface Modification on 3D-printed Ti-6Al-4V Alloy, Additive Manufacturing, 22:60-68. 

[22] H. Qin, Z. Ren, J. Zhao, C. Ye, G.L. Doll*, Y. Dong*, 2017, Effects of ultrasonic nanocrystal surface modification on the wear and micropitting behavior of bearing steel in boundary lubricated steel-steel contacts, Wear, 392-393: 29-38.

[23] C. Ma, M. T. Andani, H. Qin, N. S. Moghaddam, H. Ibrahim, A. Jahadakbar, A. Amerinatanzi, Z. Ren, H. Zhang, G. L. Doll, Y. Dong, M. Elahinia, C. Ye*, 2017, Improving surface finish and wear resistance of additive manufactured nickel-titanium by ultrasonic nano-crystal surface modification, Journal of Materials Processing Technology, 249: 433-440.

[24] H. Zhang, R. Chiang, H. Qin, Z. Ren, X. Hou, D. Lin, G. L. Doll, V. K. Vasudevan, Y. Dong, C. Ye*, 2017, The Effects of Ultrasonic Nanocrystal Surface Modification on the Fatigue Performance of 3D-Printed Ti64, International Journal of Fatigue, 103:136–146.

[25] C. Ye*, A. Telang, A. Gill, S. Suslov, Y. Idell, K. Zweiacker, J. Weizorek, Z. Zhou, D. Qian, S.R. Mannava, V.K. Vasudevan, 2014, Gradient Nanostructure and Residual Stresses Induced by Ultrasonic Nano-crystal Surface Modification in 304 Austenitic Stainless Steel for High Strength and High Ductility, Materials Science & Engineering A, 613: 274-288.

[26] C. Ye, S. Suslov, X. Fei, G.J. Cheng*, 2011, Bimodal Nanocrystallization of NiTi Shape Memory Alloy by Laser Shock Peening and Post Deformation Annealing, Acta Materialia, v 59, n 19, 7219-7227.

[27] C. Ye, S. Suslov, B.J. Kim, E.A. Stach, G.J. Cheng*, 2011, Fatigue Performance Improvement by Dynamic Strain Aging and Dynamic Precipitation in Warm Laser Shock Peening of AISI 4140 steel, Acta Materialia. v 59, n 3, p 1014-1025.

荣誉获奖

[1] NSF CAREER Award
[2] ASME Fellow

师资队伍

叶畅教授

个人简介

研究方向

开设课程

科研项目

论文专著与专利

荣誉获奖

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师资队伍

叶畅 教授

个人简介

研究方向

开设课程

科研项目

论文专著与专利

荣誉获奖

友情链接

关注我们

叶畅教授