电子科技大学深圳高等研究院导师教师师资介绍简介-张东星

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导师代码： 20493
导师姓名：张东星
性别：男
特称：

职称：副研究员
学位：哲学博士学位
属性：专职
电子邮件： zhangdongxing@uestc.edu.cn

学术经历： 2021-03 - 特聘副研究员电子科技大学
5G与智能制造协同技术
2018/03 -2021-02, 博士后西安大略大学(UWO)
5G与智能制造协同技术
应用于5G通讯的频率选择表面/结构的3D打印技术
频率选择表面/结构的模拟及设计
3D打印功能材料和机械超材料。
2013/09 -2017/09 西安大略大学 (UWO), 工学博士，专业：机械与材料工程
2010/09 -2013/06 北京航空航天大学 (BUAA), 工学硕士，专业：航空宇航制造工程
2006/09 -2010/06 华中科技大学 (HUST), 工学学士，专业：材料成型及控制工程

个人简介： 张东星，电子科技大学副研究员。2017年于加拿大Western University获得博士学位，方向为先进智能制造。目前研究内容包括5G驱动下的智能制造，精准材料的智能设计/制备，生物医疗器械，3D打印无绳机器人以及微纳打印血管机器人等，在先进（智能）制造领域积累了丰富的科研成果。发表SCI论文20余篇，专利5项。相关研究成果发表于Natrure Communication,ACS App. Mat. Int., Nanotechnology, Journal of Materials Science, IEEE transactions系列等国际知名期刊。出版专著《5G赋能智能制造》。承担加拿大自然基金项目两项，项目金额15万加元。研究方向包括：先进智能制造技术，包括打印电子，工厂模拟及数字孪生技术；3D打印技术及超材料研究；3D打印无接触控制制动器/机器人；基于双光子光刻技术的微纳3D打印技术。课题组常年开放机械设计、数据挖掘、电子电器、信息通讯方向的博士后、博士、硕士招生。

科研项目： 2019/03 - 2021/03
A React-on-Demand (RoD) Process for Printed Electronics; MITACS Accelerate program ($ 110,000)
主持人
2018/03 -2019-02
3D printing of electrochemically driven point-of-care test (POCT) device for heavy metal ions detection, MITACS Accelerate program ($ 45,000)
主持人

研究成果： 论文
Zhang, D., Xiao, J., Qiu, Y., Yang, J., & Guo, Q. (2017). Initiator-integrated 3-D printing of magnetic object for remote controlling application. IEEE Transactions on Magnetics, 53(5), 1-9.
Zhang, D., Xiao, J., Guo, Q., & Yang, J. (2019). 3D-printed highly porous and reusable chitosan monoliths for Cu (II) removal. Journal of Materials Science, 54(8), 6728-6741.
Zhang, D., Xiao, J., Moorlag, C., Guo, Q., & Yang, J. (2017). Development of ultralight, super-elastic, hierarchical metallic meta-structures with i3DP technology. Nanotechnology, 28(45), 455708.
Zhang, D., Xiao, J., Yu, W., Guo, Q., & Yang, J. (2018). Hierarchical metal/polymer metamaterials of tunable negative Poisson’s ratio fabricated by initiator-integrated 3D printing (i3DP). Nanotechnology, 29(50), 505704.
Zhang, D., Yang, J., & Guo, Q., (2018) Printing technology and process study of flexible electronic devices based on a laser reverse printing method. Printed Circuits Information. 12, 40-45.
Zhang, D., Xiao, J., Bai, Y., Guo, Q., & Yang, J. (2020)Introducing Bioinspired Initiator into Resins for In-situ Repairing of 3D Printed Metallic Structures. ACS Appl Mater Interfaces, 12(43), 49073-49079.
Zhang, D., Gao, J., et, al. DRoD method for fabricating frequency selective engineering structures. (submitting).
Zhang, D., Guo, Q., & Yang, J. I3DP of lightweight, high compressive strength, metallic cellular materials and the strength-enhanced property”. (submitting)
Zhang, D., Xiao, J., Qiu, Y., Yang, J., & Guo, Q. 3D printing of mechanical metamaterials of dual negative Poisson's ratios. (proceeding) .
Zhang, D., Xiao, J., Qiu, Y., Yang, J., & Guo, Q. 3D printing of volumetric engineering frequency selective structures (EFSS). (proceeding)
Zhang, D., Xiao, J., Qiu, Y., Yang, J., & Guo, Q. Selective large-area fabrication of highly conductive metal-polymer porous structures for flexible electronics. (proceeding)
Cai G, Fu J, Zhang D （通讯作者）, et al. A Novel Approach to Predict Wrinkling of Aluminum Alloy During Warm/Hot Sheet Hydroforming Based on an Improved Yoshida Buckling Test. Materials (Basel). 2020;13(5):1165.
Shen, T., Zhang, D., Huang, L., & Wang, J. (2016). An automatic-recovery inertial switch based on a gallium-indium metal droplet. Journal of Micromechanics and Microengineering, 26(11), 115016.
Bai, Y., Zhang, D., et al. A Study of Enzyme Activity Change due to Inkjet Printing for Biosensor Fabrication. (2021), ACS Biomaterials Science & Engineering，ACS Biomaterials Science & Engineering 7 (2), 787-793.
Fantino, E., Roppolo, I., Zhang, D., Xiao, J., Chiappone, A., Castellino, M., ... & Yang, J. (2018). 3D printing/interfacialpolymerization coupling for the fabrication of conductive hydrogel. Macromolecular Materials and Engineering, 303(4), **.
Cai, X., Hu, M., Zhang, D., Hu, G., & Yang, J. (2018). Experimental Study on Tunable Electromagnetic Shielding by Microlattice Materials with Organized Microstructures. Advanced Engineering Materials, 20(7), **.
Cai, G., Wu, C., & Zhang, D. (2018). Investigation on the effect of type of cooling on the properties of aluminum alloy during warm/hot hydromechanical deep drawing. Symmetry, 10(9), 362.
Li, X., Deng, S., Banis, M. N., Doyle-Davis, K., Zhang, D., Zhang, T., ... & Sun, X. (2019). Suppressing corrosion of aluminum foils via highly conductive graphene-like carbon coating in high-performance lithium-based batteries. ACS applied materials & interfaces, 11(36), 32826-32832.
Huo, H., Gao, J., Zhao, N., Zhang, D., Holmes, N., Li, X., ... & Sun, X. (2021). A Flexible Electron-blocking Interfacial Shield for Dendrite-free Solid Lithium Metal Batteries. Nature Communication.12 (1), 1-10
Cai, G., Lang, L., Liu, K., Alexandrov, S., Zhang, D., Yang, X., & Guo, C. (2015). Research on the effect of flow stress calculation on aluminum alloy sheet deformation behavior based on warm bulging test. Metals and Materials International, 21(2), 365-373.
专利:
CNA, A kind of photocuring 3D printing photosensitive resin and its preparation method and application.
CNA, A method for rapid fabrication of large area circuit based on desktop printing.
CNA, A printing electronic method based on laser reverse printing.
In-situ repair method for surface metal coating of 3D printed antenna array (proceeding).
A direct 3D printing method for preparing functionally repairable super-hydrophobic porous membrane(proceeding).
书&章节：
5G赋能智能制造，人民邮电出版社，5G Enabled Intelligent Manufacturing. POSTS & TELECOM PRESS. (2020)

专业研究方向： 专业名称研究方向招生类别
085400电子信息 16软件工程硕士