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个人简介

教育背景 2015.01-2019.05 新加坡国立大学 机械工程系 博士 2010.09-2014.06 中国科学技术大学 精密机械与精密仪器系 学士 工作经历 2023.02-至今 上海交通大学 元知机器人研究院,机械与动力工程学院 副教授 2020.11-2022.09 香港科技大学 机械与航空航天工程系 博士后 2019.04-2020.11 新加坡科技局 新加坡制造技术研究院(SIMTech) 博士后研究员(Scientist) 科研项目 1. 香港研究资助局General Research Fund “Open-Cell Plate-Lattice Mechanical Metamaterials Made with Additive Manufacturing Techniques” ,2021-2024,参与 2. 香港创新科技署Innovation and Technology Support Programme “Development of Ultra-Light and High-Strength Shellular Materials: Design and Additive Manufacturing”,2020-2021,参与 3. 新加坡科技局科学与工程研究委员会“Design, Modelling and Simulation of 3D Additive Manufacturing Components”,2015-2020,子课题完成人 荣誉奖励 • 2020-2021 受香港创新科技署研究人才库项目资助(Research Talent Hub) • 2021 新加坡科技局 研究亮点:A new angle on 3D-printed metal (https://research.a-star.edu.sg/articles/highlights/building-a-new-wave-of-lightweight-structural-panels/) • 2018 新加坡科技局 研究亮点:Building a new wave of lightweight structural panels (https://research.a-star.edu.sg/articles/highlights/a-new-angle-on-3d-printed-metal/) • 2015-2019 新加坡国立大学研究奖学金

研究领域

致力于结合固体力学、结构优化、微分几何、材料科学等多学科知识和增材制造(Additive Manufacturing,AM)技术,研究轻量化高性能点阵结构的设计和制造方法。 理论与技术研究: • 点阵结构设计与优化(Design and optimization of lattice structures):形状/拓扑优化(Shape and topology optimization),多层级和梯度点阵结构(Hierarchical and graded lattice structures) • 面向增材制造的结构设计(Design for AM):点阵结构打印缺陷表征与建模(Characterization and modelling of AM defects of lattice structures),几何补偿设计(Geometry compensation design) • 增材制造及后处理(AM and post-processing):微米级激光选区熔化技术(Micro selective laser melting),激光路径规划(Laser path planning),电化学精密抛光(Precision electrochemical polishing) 应用研究: • 轻质高强抗冲击航空航天器零部件(Lightweight, high-strength, and impact-resistant aerospace components) • 仿生骨支架(Biomimetic bone scaffolds) *PRP项目开放报名,题目:超轻高强蒙皮点阵结构一体化设计和高速3D打印,报名时间:2023-5-22~6-2, 9-11~9-21。 *2024年硕/博研究生名额未满。 *欢迎数理基础扎实,对结构优化、增材制造感兴趣的研究生和本科生加入!

近期论文

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在结构优化、增材制造及应用等领域发表期刊论文22篇,包括增材制造旗舰期刊Additive Manufacturing(7篇)、Materials & Design(5篇)、PNAS(1篇)、Journal of the European Ceramic Society(1篇)、International Journal of Solids and Structures(1篇),其中一作/通讯(含共同)10篇,ESI高被引论文1篇,Additive Manufacturing、Materials & Design期刊高被引论文各1篇。 Highly Cited Journal Publications (#Authors contributing equally *Corresponding author) 1. Zhang, L., Feih, S., Daynes, S., Chang, S., Wang, M.Y., Wei, J., Lu, W.F.* (2018). Energy absorption characteristics of metallic triply periodic minimal surface sheet structures under compressive loading. Additive Manufacturing, 23, 505-515. (ESI高被引论文,ESI研究前沿、TPMS结构领域5篇核心论文之一,期刊自2018年高被引论文,提出金属曲壳TPMS点阵结构设计方法,实现超轻、高刚、高强、高吸能的优异力学性能) 2. Wang, Y., Zhang, L., Daynes, S., Zhang, H., Feih, S., Wang, M.Y.* (2018). Design of graded lattice structure with optimized mesostructures for additive manufacturing. Materials & Design, 142, 114-123. (期刊自2018年高被引论文,提出微结构可光滑连接的梯度点阵结构宏微观一体化拓扑优化方法) Other Journal Publications [2023] 3. Cang, M.#, Zhang, L.#, Wang, Y*, Fu, J., Luo, Z., Kang, Z., Fu, M.W., Wang, M.Y. (2023) An efficient method for design of lattice core sandwich structures with superior buckling strength under compression. Engineering Optimization, 1-19 4. Fu, J., Ding, J., Zhang, L., Qu, S., Song, X.*, Fu, M.W.* (2023) Development of conformal shell lattices via laser powder bed fusion and unraveling their mechanical responses via modeling and experiments. Additive Manufacturing, 62, 103406. [2022] 5. Zhang, L., Lifton, J., Hu, Z., Hong, R., Feih, S.* (2022). Influence of geometric defects on the compression behaviour of thin shell lattices fabricated by micro laser powder bed fusion, Additive Manufacturing, 58, 103038. 6. Zhang, L., Ma, Q., Ding, J., Qu, S., Fu, J., Fu, M.W., Song, X.*, Wang, M.Y.* (2022). Design of elastically isotropic shell lattices from anisotropic constitutive materials for additive manufacturing. Additive Manufacturing, 59, 103185. 7. Yang, Y.#, Xu, T.#, Bei, H.P., Zhang, L., Tang, C.Y., Zhang, M., Xu, C., Bian, L., Yeung, K.W.K*, Fuh, J.Y.H*, Zhao, X.* (2022). Gaussian curvature-driven direction of cell fate towards osteogenesis with triply periodic minimal surface scaffolds. The Proceedings of the National Academy of Sciences, 119(41), e2206684119. 8. Ma, Q.#, Yan, Z.#, Zhang, L.*, Wang, M.Y. (2022). The family of elastically isotropic stretching-dominated cubic truss lattices. International Journal of Solids and Structures, 239-240, 111451. 9. Chen, F.*, Miao, Y., Zhang, L.*, Chen, S., Zhu, X. (2022). Triply Periodic Channels Enable Soft Pneumatic Linear Actuator with Single Material and Scalability. IEEE Robotics and Automation Letters, 7(2), 2668-2675 10. Ding, J., Qu, S., Zhang, L., Wang, M.Y., Song, X.* (2022) Geometric deviation and compensation for thin-walled shell lattice structures fabricated by high precision laser powder bed fusion. Additive Manufacturing, 58, 103061. 11. Ma, Q., Zhang, L., Wang, M.Y.* (2022). Elastically isotropic open-cell uniform thickness shell lattices with superior stiffness via shape optimization. Materials & Design, 215, 110426. 12. Hu, Z., Gao, S., Zhang, L., Shen, X., Seet, H.L., Nai, S.M.L., Wei, J. (2022). Micro laser powder bed fusion of stainless steel 316L: Cellular structure, grain characteristics, and mechanical properties. Materials Science and Engineering: A, 848, 143345. 13. Fu, J., Ding, J., Qu, S., Zhang, L., Wang, M.Y., Fu, M.W.*, Song, X.* (2022). Improved light-weighting potential of SS316L triply periodic minimal surface shell lattices by micro laser powder bed fusion. Materials & Design, 222, 111018. [2021] 14. Zhang, L., Hu, Z., Wang, M. Y., Feih, S.* (2021). Hierarchical sheet triply periodic minimal surface lattices: design, geometric and mechanical performance. Materials & Design, 209, 109931. 15. Ma, Q., Zhang, L., Ding, J., Qu, S., Fu, J., Zhou, M., Fu, M.W., Song, X., Wang, M.Y.* (2021). Elastically-isotropic open-cell minimal surface shell-lattices with superior stiffness via variable thickness design. Additive Manufacturing, 47, 102293. 16. Hong, R., Zhang, L., Lifton, J., Daynes, S., Wei, J., Feih, S.*, Lu, W.F.* (2021). Artificial neural network-based geometry compensation to improve the printing accuracy of selective laser melting fabricated sub-millimetre overhang trusses. Additive Manufacturing, 37, 101594. 17. Chang, S.#, Zhang, Y.#, Zhang, B.#, Cao, X., Zhang, L., Huang, X.*, Lu, W., Ong, C.Y.A., Yuan, S., Li, C., Huang, Y., Zeng, K., Li, L., Yan, W.*, Ding, J.* (2021). Conductivity Modulation of 3D-Printed Shellular Electrodes through Embedding Nanocrystalline Intermetallics into Amorphous Matrix for Ultrahigh-Current Oxygen Evolution. Advanced Energy Materials, 11(28) 2100968. [2020] 18. Zhang, L., Feih, S., Daynes, S., Chang, S., Wang, M.Y., Wei, J., Lu, W.F.* (2020). Pseudo-ductile fracture of 3D printed alumina triply periodic minimal surface structures. Journal of the European Ceramic Society, 40(2), 408-416. [2019] 19. Chang, S., Liu, A., Ong, C.Y.A., Zhang, L., Huang, X., Tan, Y.H., Zhao, L., Li, L. and Ding, J.* (2019). Highly effective smoothening of 3D-printed metal structures via overpotential electrochemical polishing. Materials Research Letters, 7(7), 282-289. [2016-2018] 20. Zhang, L., Feih, S., Daynes, S., Wang, Y., Wang, M.Y., Wei, J., Lu, W.F.* (2018). Buckling optimization of Kagome lattice cores with free-form trusses. Materials & Design, 145, 144-155. 21. Vijayavenkataraman, S.#*, Zhang, L.#, Zhang, S., Fuh, J.Y.H., Lu, W.F. (2018). Triply periodic minimal surfaces sheet scaffolds for tissue engineering applications: An optimization approach toward biomimetic scaffold design. ACS Applied Bio Materials, 1(2), 259-269. 22. Wang, Y., Zhang, L., Wang, M.Y.* (2016). Length scale control for structural optimization by level sets. Computer Methods in Applied Mechanics and Engineering, 305, 891-909.

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