唐昀青
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唐昀青,教授、博士生导师,山东省优青、泰山学者青年专家,山东大学齐鲁青年学者(第一层次)。担任Prog. Nat. Sci.、金属学报、Tungsten青年编委,Symmetry、Metals、Nanomaterials、Lubricants、Front. Chem.等期刊客座编辑,Wear、STAR Protoc.、Langmuir、Cryst. Growth Des.、Phys. Lett. A、Phys. Status Solidi A、物理学报等期刊审稿人。
国内外学习和工作经历
2023-至今 教授、博士生导师,机械工程学院,山东大学
2018-2023 博士后 材料与化学工程系 加拿大阿尔伯塔大学
合作导师:加拿大工程院院士Dongyang Li教授
2012-2017 工学博士 机械工程 江苏大学 导师:杨平教授
2008-2012 工学学士 工程力学 中国矿业大学
主要研究方向
(1) 磨损机理与控制技术
(2) 材料力学性能与失效机制
(3) 半导体器件可靠性物理
(4) 电子封装热管理
(5) 光电/传感材料与器件设计
主要学术成绩
发表学术论文70余篇,其中以第一作者/通讯作者发表论文30余篇(包括Science子刊1篇,Cell子刊2篇);获授权国家发明专利9项,申请PCT专利1项;主持国家自然科学基金、山东省自然科学基金等国家和省部级项目5项,作为学术骨干参与中国和加拿大国家重点科研项目多项。
承担科研项目情况
[1] 2024-2026 国家自然科学基金青年科学基金,基于电子功函数理论的金属材料强韧耐磨机制与设计策略研究,负责人
[2] 2024-2026 山东省优秀青年科学基金项目(海外),面向极端工况的新一代半导体器件关键材料/结构可靠性设计和制造,负责人
[3] 2024-2026 中央引导地方科技发展资金,多功能特种作业机器人关键技术研发及产业化,负责人(校方)
[4] 2024-2026 国家自然科学基金重大研究计划项目,难加工材料与构件能场辅助高效低损伤加工研究,项目骨干
[5] 2023-2025 山东省外专双百计划,高端海工装备结构材料智能设计与制造,负责人(中方)
[6] 2023-2025 山东省泰山学者青年专家项目,新一代半导体器件物理可靠性设计和制造,负责人
[7] 2023-2028 山东大学齐鲁青年学者启动基金,负责人
[8] 2021-2023 加拿大自然科学与工程研究基金,Computational design - development of advanced low cost multi element lightweight alloys,项目骨干
[9] 2020-2023 国家自然科学基金面上项目,微纳制造中石墨烯异质界面传热行为进化构筑与调控研究,项目骨干
[10] 2018-2022 加拿大自然科学与工程研究基金,Develop new carbides for effective high-Cr cast irons (HCCIs) with optimized combination of fracture toughness and hardness used under harsh operation conditions,项目骨干
[11] 2018-2021 加拿大自然科学与工程研究基金,Development of high-performance nano-additive incorporated lubricating fluids and database for drilling systems in the oil and gas industries,项目骨干
[12] 2015-2019 加拿大自然科学与工程研究基金,Development of an electron work function - based microstructure diagnosis technique for developing advanced structural materials,项目骨干
[13] 2016-2019 国家自然科学基金面上项目,复合环境LED车灯集成构造与可靠性评估机制研究,项目骨干
[14] 2015-2017 江苏省普通高校研究生科研创新计划,石墨烯NEMS传热界面的构筑与关键热力学行为研究,负责人
[15] 2011-2013 国家自然科学基金面上项目,微纳电子制造高密度集成结构跨尺度构筑与物理可靠性研究,项目骨干
代表性论文、著作和专利
期刊论文(*通讯作者,#共同一作)
[30] Diao, G., Tang, Y.*, He, A., Wu, M., Zhang, D., Fraser, D., ... & Li, D.* (2024). Tune Al/Ti to adjust FCC+ L21 hetero-structured Ni-based high-entropy alloys for improved mechanical properties and wear resistance. Acta Materialia, 281, 120399. (中科院一区,Top期刊)
[29] Gao, S., Li, L., Tang, Y.*, & Yang, P.* (2024). Tailored Air Annealing Strategy to Promote the Photoelectric Performance of AZO-Based Multilayer Films. Crystal Growth & Design, 24(18), 7415-7423. (中科院一区)
[28] Yang, B., Tang, Y., Xin, Z., Zheng, H., Qi, D., Zhang, N., Tang, Y.*, & Wu, X.* (2024). Modulation of the interfacial thermal resistances of the w-AlN/Graphene/3C-SiC interface by nanoscale nonplanar feature structures. Applied Surface Science, 659, 159905. (中科院二区,Top期刊)
[27] Shen, Y., Li, D., Cheng, Z., Tang, Y.*, & Yang, P.* (2024). Coupling field optimization to improve the thermal transport of Gr/h-BN heterostructure. Diamond and Related Materials, 111226.
[26] Li, L., Zhang, Z., Tang, Y.*, & Yang, P.* (2024). Manipulating photoelectric properties at ZnO/Ag/ZnO sandwich structure by Ag intercalation. Vacuum, 228, 113462.
[25] Liu, Z., Lu, J., Fang, Z., Liu, D., Yang, P., Yang, S.*, & Tang, Y.* (2024). Study on mechanical properties of ZnO/Si interface under thermal shock. Materials Today Communications, 40, 109874.
[24] Chen, K., & Tang, Y.* (2024). Research Progress on the Design of Surface Texture in Tribological Applications: A Mini-Review. Symmetry, 16(11), 1523.
[23] Tang, Y. Q., & Li, D. Y.* (2023). Influences of C, Si and Mn on the wear resistance of coiled tubing steel. Wear, 524, 204854. (中科院一区,Top期刊)
[22] Tang, Y. Q., Kumar, A., Chen, D. L., Li, D. Y.*, Li, Q. Y., & Li, W. (2023). Bauschinger effect on wear of cold-worked Cu and Mg–A study combining molecular dynamics modeling and experimental investigation. Wear, 522, 204726. (中科院一区,Top期刊)
[21] Yang, H., Tang, Y.#*, & Yang, P.* (2023). Building efficient interfacial property with graphene heterogeneous interface. International Journal of Mechanical Sciences, 237, 107782. (中科院一区,Top期刊)
[20] Tang, Y., & Li, D. Y.* (2022). Dynamic response of high-entropy alloys to ballistic impact. Science Advances, 8(31), eabp9096. (Science子刊)
(材料科学与工程报道:https://www.163.com/dy/article/HGQKL6BM05118KMO.html
材料学网报道:https://mp.weixin.qq.com/s/iddnGB0L0gPJOuV05KsUtg
两江科技评论报道:https://mp.weixin.qq.com/s/5K1iT2HqXMWar1mnRHD44w
唯理计算报道:https://mp.weixin.qq.com/s/2iMLPbjXdipGttt4AjyKGQ
今日论文报道:https://mp.weixin.qq.com/s/a8B7P25h7_xPNy8ASxuaiA)
[19] Tang, Y.*, Zhang, D., Liu, R., & Li, D.* (2022). Protocol to predict mechanical properties of multi-element ceramics using machine learning. STAR protocols, 3(3), 101552. (Cell子刊,邀稿)
[18] Xu, K., Tang, Y.#*, Wu, C., Zhao, Z., Sun, L., & Li, Y. (2022). Achieving optical phosphine sensitive h-BN nanosheets through transition metal doping. Applied Surface Science, 585, 152700. (中科院一区,Top期刊)
(AZONANO报道:https://www.azonano.com/news.aspx?newsID=38634)
[17] Tang, Y., Zhang, Z., Li, L., Guo, J., & Yang, P.* (2022). Thermal transport enhancement resolution for graphene/Si and graphene/SiC interfaces. International Journal of Thermal Sciences, 171, 107231.
[16] Xu, K., Chen, C., Tang, Y.*, Zhang, X., Wu, C., Geng, M., & Sun, L. (2022). Improving the Performance of All-Solid-Stated Planar pH Sensor With Heat Treated Process. IEEE Sensors Journal, 22(9), 8410-8417.
[15] Kong, L., Sun, X., Mo, Z., Liu, Z.*, & Tang, Y.* (2022). Study on the Effect of Thermal Shock on Al‐Doped ZnO Films. physica status solidi (a), 219(19), 2200085.
[14] Tang, Y., Zhang, D., Liu, R., & Li, D.* (2021). Designing high-entropy ceramics via incorporation of the bond-mechanical behavior correlation with the machine-learning methodology. Cell Reports Physical Science, 2(11), 100640. (Cell子刊,封面论文)
(Cell出版社微信公众号报道:https://mp.weixin.qq.com/s/ppUqOP6xiES-Q15tOi6MSA
Cover)
[13] Tang, Y., Pan, H., & Li, D. Y.* (2021). Contribution of cold-work to the wear resistance of materials and its limitation–a study combining molecular dynamics modeling and experimental investigation. Wear, 476, 203642. (中科院一区,Top期刊)
[12] Tang, Y., & Li, D. Y.* (2021). Nano-tribological behavior of high-entropy alloys CrMnFeCoNi and CrFeCoNi under different conditions: A molecular dynamics study. Wear, 476, 203583. (中科院一区,Top期刊)
[11] Guo, L., Tang, Y.#, Cui, J., Li, J., Yang, J. R., & Li, D. Y. (2021). Tailoring M7C3 carbide via electron work function-guided modification. Scripta Materialia, 190, 168-173. (中科院一区,Top期刊)
[10] Li, J., Tang, Y.#, Tang, X., & Li, D. Y.* (2021). Promoting in situ formation of core‐shell structured carbides in high‐Cr cast irons by boron addition. Journal of the American Ceramic Society, 104(9), 4891-4901. (中科院一区,Top期刊)
[9] Liu, Z., & Tang, Y.* (2021). An approach for hydrophobic fixed abrasive pad based on layer-by-layer method. Microelectronic Engineering, 238, 111505.
[8] Zhang, H., Tang, Y.#, Liu, Z.*, Zhu, Z., Tang, X.*, & Wang, Y. (2020). Study on optical properties of alkali metal doped g-C3N4 and their photocatalytic activity for reduction of CO2. Chemical Physics Letters, 751, 137467.
[7] Yang, H., Tang, Y.#*, & Yang, P.* (2019). Factors influencing thermal transport across graphene/metal interfaces with van der Waals interactions. Nanoscale, 11(30), 14155-14163. (中科院一区,Top期刊)
[6] Tang, Y., Yang, H., & Yang, P.* (2017). Investigation on the contact between graphdiyne and Cu (111) surface. Carbon, 117, 246-251. (中科院一区,Top期刊)
[5] Tang, Y., Yang, B., Yang, H., Yang, P.*, Yang, J., & Hu, Y. (2017). Numerical investigation on mechanical properties of graphene covering silicon nanofilms. Computational Materials Science, 126, 321-325.
[4] Tang, Y., Li, J., Wu, X., Liu, Q., Liu, Y., & Yang, P.* (2016). Tunable thermal property in edge hydrogenated AA-stacked bilayer graphene nanoribbons. Applied Surface Science, 362, 86-92. (中科院一区,Top期刊)
[3] Tang, Y., Liu, D., Yang, H., & Yang, P.* (2016). Thermal effects on LED lamp with different thermal interface materials. IEEE Transactions on Electron Devices, 63(12), 4819-4824. (中科院二区,Top期刊)
[2] Tang, Y., Li, J., Yang, B., Wu, X., Li, T., Mao, W., & Yang, P.* (2016). Mechanical characteristics approach on W/Cr nano-interface structure. Composite Interfaces, 23(7), 549-556.
[1] Tang, Y., Zhang, L., Yang, H., Guo, J., Liao, N., & Yang, P. (2015). Numerical simulation of thermal properties at Cu/Al interfaces based on hybrid model. Engineering Computations, 32 (3), 574-584.
发明专利
[2] Li, D., Tang, Y., Liu, R., Zhang, D., & Tang, X. COMPLEX MATERIALS, 2021-11-30, WIPO, PCT/AU2021/051429 (PCT专利)
[1] 杨平, 唐昀青, 杨兵, 刘志响. 一种非对称内嵌结构纳米薄膜热整流器的设计方法, 2019-12-31, 中国, ZL201710273047.9 (授权发明专利)
会议报告
[4] Tang, Y. Bauschinger effect on wear of cold-worked Cu and Mg – A study combining molecular dynamics modeling and experimental investigation, The 24rd International Conference on Wear of Materials, Banff, Alberta, Canada (O25.4), 2023. (材料磨损领域顶级国际会议,Oral Presentation)
[3] Tang, Y. Influences of C, Si and Mn on the wear resistance of coiled tubing steel, The 24rd International Conference on Wear of Materials, Banff, Alberta, Canada (P1.24), 2023. (材料磨损领域顶级国际会议,Poster Presentation)
[2] Tang, Y. Contribution of cold-work to the wear resistance of materials and its limitation – A study combining molecular dynamics modeling and experimental investigation, The 23rd International Conference on Wear of Materials, Banff, Alberta, Canada (WO35.1), 2021. (材料磨损领域顶级国际会议,Oral Presentation)
[1] Tang, Y. Sliding wear of high-entropy alloys CrMnFeCoNi and CrFeCoNi: A molecular dynamics study, The 23rd International Conference on Wear of Materials, Banff, Alberta, Canada (WO35.2), 2021. (材料磨损领域顶级国际会议,Oral Presentation)
获得荣誉
2018年江苏大学优秀博士学位论文
2018年江苏大学优秀毕业研究生
2017年博士研究生国家奖学金
招生情况
欢迎有机械、力学、材料、传热、半导体等相关背景学生报考!欢迎本科同学加入课题组学习!优秀学生可推荐至加拿大阿尔伯塔大学等国际知名高校交流、深造。
常年招聘相关方向博士后,待遇参考山东大学博士后政策。课题组会努力协助申请学校高等级资助和相关基金支持。
联系方式
地址:山东省济南市经十路17923号山东大学千佛山校区机械工程学院
邮编:250061
邮箱:tangyunqing@sdu.edu.cn
2023.03 -- 至今
山东大学 机械工程学院 教授
2018.08 -- 2023.01
University of Alberta Department of Chemical and Materials Engineering Postdoctoral fellow