黄成鹏，深圳大学材料学院助理教授。主要从事高性能金属结构材料及极端环境服役安全等方面的研究工作。研究兴趣主要集中在“材料学+力学”交叉领域，涵盖多尺度实验与数值模拟，包括先进合金设计、微结构调控与强韧化、冲击动态力学行为、变形与断裂机理、晶体塑性有限元模拟等。相关研究成果在Acta Materialia, Materials Science and Engineering A, Metallurgical and Materials Transactions A, Materials Futures, Computational Materials Science等国际期刊发表。已申请/授权中国和美国发明专利多项，并获瑞士日内瓦国际发明展金奖。

课程教学：

材料力学性能

联系方式：

地址：深圳市南山区学苑大道1066号深圳大学丽湖校区文韬楼B3-128

邮箱：cphuang@szu.edu.cn

课题组长期招收博士后、博士、硕士，欢迎具有材料、力学、机械、冶金等相关研究背景或兴趣的人员申请，有意者请邮件联系。

欢迎优秀本科生加入课题组学习。

(1) 先进高强韧合金设计与开发

(2) 金属材料的塑性变形与断裂机理

(3) 极端服役条件下（高温、高压、高应变速率）材料的力学行为

(4) 多尺度力学模拟（分子动力学、晶体塑性有限元等）

(1) C.P. Huang, M. Wang, K.Y. Zhu, A. Perlade, M.X. Huang*, Carbon induced negative strain-rate sensitivity of a quenching and partitioning steel, Acta Materialia, 2023, 255: 119099.

(2) C.P. Huang, S. Pan, C. Hu, Y.X. Liu, B.B. He*, M.X. Huang*, Dual role of dislocations in enhancing strength-ductility synergy in a TRIP-assisted steel, Materials Science and Engineering: A, 2025, 927: 148003.

(3) C.P. Huang, M. Wang, K.Y. Zhu, A. Perlade, M.X. Huang*, Intrinsic high-strain-rate softening in a high-strength quenching and partitioning steel, Metallurgical and Materials Transactions A, 2025, 56: 793-800.

(4) C.P. Huang, C. Hu, Y.X. Liu, Z.Y. Liang, M.X. Huang*, Recent developments and perspectives of advanced high-strength medium Mn steel: From material design to failure mechanisms, Materials Futures, 2022, 1(3): 032001.

(5) C.P. Huang, M.X. Huang*, Effect of processing parameters on mechanical properties of deformed and partitioned (D&P) medium Mn steels, Metals, 2021, 11(2): 356.

(6) C.P. Huang, F. Xu*, Y. Sun, Effects of morphology, tension and vibration on wettability of graphene: A molecular dynamics study, Computational Materials Science, 2017, 139: 216-224.

(7) C. Hu, C.P. Huang, Y.X. Liu, A. Perlade, K.Y. Zhu, M.X. Huang*, The dual role of TRIP effect on ductility and toughness of a medium Mn steel, Acta Materialia, 2023, 245: 118629.

(8) X.Y. Xu, C.P. Huang, H.Y. Wang, Y.Z. Li, M.X. Huang*, Rate-dependent transition of dislocation mechanisms in a magnesium alloy, Acta Materialia, 2024, 263: 119474.

(9) Y.X. Liu, C. Hu, C.P. Huang, S. Pan, B.B. He, M.X. Huang*, Rate-dependent brittle-ductile transition in a medium Mn steel, Acta Materialia, 2025, 290: 120996

(10) J.Q. Shi, C.P. Huang, H.Y. Wang, S.H. Deng, Z.J. Tan, H.L. Lu, J.Z. Hao, F.R. Shen, Y.F. Jia, J. Chen, Q. Wang, L.H. He, G. Wang*, In-situ neutron diffraction study of the strengthening mechanism and deformation behavior of cellular structure in high-entropy alloys by additive manufacturing,International Journal of Plasticity, 2024, 181: 104081.