高重阳
博士
个人简介
高重阳,浙江大学机械工程学院教学科研岗固聘副教授兼浙江大学高端装备研究院研究员,CAE虚拟制造过程模拟实验室主任。2001年获清华大学航天航空学院固体力学专业博士学位,同年获法国政府中法科技交流奖学金资助,赴法国矿业大学(Ecloe des Mines)从事博士后研究,2003年引进入浙江大学航空航天学院应用力学研究所,2012年调入现代制造工程研究所飞机数字化装配团队致力于我国飞机制造及装配领域共性关键问题的基础性研究。工作期间曾于2006年获澳大利亚政府海外学者奋进(Endeavour)研究奖学金,在悉尼大学航空机械系访问6个月;2011年前往新南威尔士大学(UNSW)与国际知名的多尺度加工塑性领域专家Zhang LC院士开展合作研究取得系统性的学术成果;2018年通过访问UCLA在纳米增强超金属方向上开展了国际前沿的探索研究。同时为2013年浙江省杰出青年基金获得者。 目前主要研究方向包括航空复合材料(碳纤维增强树脂基CFRPs)先进制造技术与多尺度力学建模、石墨烯纳米改性及其产业化应用、CAE动态过程有限元模拟与AI算法融合技术等。工作期间主持承担国家基金面上项目、国家部委重点课题、国家重点实验室开放基金、国家留学基金委回国人员启动基金等纵向项目,并参加完成国家基金重大项目、国家科技支撑计划、国防军工等重点科研项目。发表包括学科TOP期刊的SCI/EI学术论文三十多篇,现为国际计算力学学会会员、中国复合材料学会青年委员会委员,担任《Int. J. Plasticity》、《Compos Sci Tech》、《Mat Sci Eng A》、《Int. J. Advanced Manufacturing Technology》、《Science China -E》、《航空学报》等国内外核心学术期刊审稿人。
研究领域
纳米复合材料制造工艺与优化设计 石墨烯纳米改性技术与产业化应用 力学建模理论与生物自修复技术 CAE有限元模拟与机器学习算法
近期论文
2011-2017以第一作者或通讯作者发表的SCI论文 - C.Y. Gao, L.C. Zhang. Constitutive modeling of plasticity of fcc metals under extremely high strain rates. International Journal of Plasticity. 2012, 32-33, 121-133. ZJU100, IF=5.987, Citation=30 - C.Y. Gao, B. Zhan, L.Y. Chen, X.C. Li. A micromechanical model of graphene-reinforced metal matrix nanocomposites with consideration of graphene orientations, Composites Science and Technology, 152 (2017) 120-128. SCI-TOP, IF=5.2 - C.Y. Gao, J.G. Jia, Factor Analysis of Key Parameters on Cutting Force in Micromachining of Graphene Reinforced Magnesium Matrix Nanocomposites Based on FE simulation, International Journal of Advanced Manufacturing Technology, October 2017, Volume 92, Issue 9–12, pp 3123–3136. - C.Y. Gao, J.Z. Xiao, Y.L. Ke. An analytical approach to cutting force prediction in milling of carbon fiber reinforced polymer laminates, Machining Science and Technology. 2018, 22: 1012-1028. - L.L. Zhu, C.S. Wen, C.Y. Gao*, X. Guo, J. Lu. A study of dynamic plasticity in austenite stainless steels with a gradient distribution of nanoscale twins. Scripta Materialia 133 (2017) 49–53. - C.Y. Gao, J.Z. Xiao, L.C. Zhang, Y.L. Ke. On the static and dynamic properties of fiber-reinforced polymer composites: A three-phase constitutive model. Journal of Thermoplastic Composite Materials. 2017, 30, 1560-1577. - C.Y. Gao, J.Z. Xiao, J.H. Xu, Y.L. Ke. Factor analysis of machining parameters of fiber-reinforced polymer composites based on finite element simulation with experimental investigation. International Journal of Advanced Manufacturing Technology. 2016, 83, 1113-1125. - C.Y. Gao, L.C. Zhang, P.H. Liu. The role of material model in the finite element simulation of high-speed machining of Ti6Al4V. IMechE Part C: Journal of Mechanical Engineering Science. 2016, 230, 2959–2967. - C. Y. Gao*, W. R. Lu, X. C. Li, Y. L. Ke. A physically-based plastic constitutive model considering nanoparticle cluster effect for metal matrix nanocomposites, Materials Science and Engineering A, 201508, 641, 172-180. SCI-TOP, IF=2.567 - C. Y. Gao, Y. Lu, Y.T. Zhu. A new micromechanical model of CNT-metal nanocomposites with random clustered distribution of CNTs, Fracture and Structural Integrity, 2015, 33, 471-484. - C. Y. Gao*, X. M. Zhao. Factor analysis of machining parameters of SiC nanoparticle-reinforced magnesium matrix composites with consideration of cluster effect, International Journal of Machining and Machinability of Materials, 201504, 17, 165-181. - C.Y. Gao, L.C. Zhang*, W.G. Guo, Y.L. Li, W.R. Lu, Y.L. Ke. Dynamic plasticity of AZ31 magnesium alloy: Experimental investigation and constitutive modeling. Materials Science & Engineering A, 201409, 613, 379–389. SCI-TOP, IF=2.567 - W.R. Lu, C.Y. Gao*, Y.L. Ke. Constitutive modeling of two-phase metallic composites with application to tungsten-based composite 93W–4.9Ni–2.1Fe. Materials Science and Engineering A. 201401, 592, 136-142. SCI-TOP, IF=2.567, 1 - C.Y. Gao*, J.Z. Xiao, Y.L. Ke. FE Analysis of Stress Concentrations in Composite Plates with Multiple Holes for Zigzag Multi-Fastened Joints. Mater Sci Forum. 2014, 770, 17-20. - C.Y. Gao, L.C. Zhang*. Effect of cutting parameters on the serrated chip formation in high speed cutting: A finite element analysis. Machining Science and Technology: An International Journal. 201301, 17, 26-40. SCI, IF=0.703, 3 - C.Y. Gao*, W.R. Lu. A constitutive description of the yield strength and strain hardening behaviors of nano-twinned metals. Key Eng. Mater. 2013, 535, 109-112. - C.Y. Gao, W.R. Lu, L.C. Zhang*, H.X. Yan. A constitutive description of the thermo-viscoplastic behaviour of body-centered cubic metals. Materials and Design. 201204, 36, 671-678. SCI, IF=4.525, 8 - C.Y. Gao, P.H. Liu, L.C. Zhang*. An explicit integration algorithm for introducing user-defined thermo-viscoplastic constitutive models in FE simulations. Mater Sci Forum. 2012, 697-698, 204-207. - C.Y. Gao*, W.R. Lu. Thermomechanical Response of Commercially Pure Titanium under Large Plastic Deformation at High Strain Rates. Adv. Mater. Res. 201205, 548, 174-178. - C.Y. Gao, L.C. Zhang*, H.X. Yan. A new constitutive model for HCP metals. Materials Science and Engineering A. 201105, 528, 4445-4452. SCI, IF=2.567, 4 - C.Y. Gao*, B. Fang, Y.T. Gu. Theoretical analysis of serrated chip formation based on ideal models in high speed cutting. Adv. Mater. Res. 201101, 154, 239-245. - C.Y. Gao, L.C. Zhang. Dislocation-Based Constitutive Descriptions of Dynamic Plasticity of FCC, BCC and HCP Metals: An Overview. Proc. of the 3rd Int Symposium on Plasticity and Impact, 201112, Hong kong, 115-120. - C.Y. Gao, L.C. Zhang. A constitutive model for dynamic plasticity of FCC metals. Materials Science and Engineering A 527 (2010) 3138–3143.