邵佳佳 - 北京雁栖湖应用数学研究院

办公室: A3-3-308

邮箱: shaojiajia@bimsa.cn

研究方向: 曲面电磁计算, 共形结构, 多物理场建模与动态仿真

个人简介

邵佳佳，北京雁栖湖应用数学研究院副教授; 2019年获中国科学院大学理学博士学位, 凝聚态物理专业, 期间2018年9月至2019年3月在瑞典访学; 2019年6月至2021年7月在中科院北京纳米能源所进行博士后研究; 2021年-2026年, 任中科院北京纳米能源所/中国科学院大学副研究员/副教授、青年研究员。主要研究方向：曲面电磁计算、共形结构、多物理场建模与仿真。近年来在Nat. Rev. Methods Primers.、Sci. Adv.、Appl. Phys. Rev.等期刊上发表SCI论文80余篇, 多篇Featured/Tutorials/ESI高被引论文, 中英文合著10章, 谷歌引用7200余次、H-index 43 (截止05. 2026)。主持或参与国自然、科技部、中科院、国科大等项目12项，并担任多个国际期刊青年编委与组织负责人。

研究兴趣

曲面电磁计算
共形结构
多物理场建模与动态仿真

教育经历

2016 - 2019 中国科学院大学 凝聚态物理 Ph.D

工作经历

2026 - 北京雁栖湖应用数学研究院 副教授
2021 - 2026 中科院北京纳米能源与系统研究所/中国科学院大学 副研究员/副教授、青年研究员
2019 - 2021 中科院北京纳米能源与系统研究所 博士后

荣誉与奖项

2024 国科大青年教师教学奖
2023 国科大领雁奖
2022 中科院青促会会员
2021 中国科学杂志社高影响力论文奖 (中科院建院70周年)
2021 国科大优秀个人

出版物

[1] X Guo, S Wang, D Wei, C Zhang, S Dai, L Ding, ZL Wang, J Shao, Figure-of-merit for tribovoltaic nanogenerators, Matter (2026)
[2] J Zhu, X Pan, Y Shi, B Sun, ZB Zhang, L Ding, ZL Wang, J Shao, Electromagnetic radiation from a magnet-based mechanical antenna, Nano Energy, 111837 (2026)
[3] J Zhang, J Shao, H Monluc, D Wei, J You, L Ma, L Ding, ZL Wang, S Dai, Dynamic Modeling of a Stream-Current-Based Microfluidic Nanogenerator, ACS nano, 19(48), 41330-41341 (2025)
[4] Y Zhao, J Shao, J Zhang, X Guo, B Sun, ZL Wang, S Dai, The universal model for metal–semiconductor tribovoltaic nanogenerators, Applied Physics Reviews, 12(4) (2025)
[5] X Pan, J Gravesen, M Willatzen, X Guo, ZL Wang, J Shao, Triboelectric-enabled self-powering mechanical antenna, Cell Reports Physical Science, 6(6) (2025)
[6] C Su, J Shao, Z Yu, AM Hasan, C Bao, CR Bowen, C Li, ZL Wang, Y Yang, Miniature and cost‐effective self‐powered triboelectric sensing system toward rapid detection of puerarin concentration, InfoMat, 7(2), e12624 (2025)
[7] J You, J Shao, Y He, B Sun, KW See, ZL Wang, X Wang, Interface triboelectricity, EcoEnergy, 3(1), 105-130 (2025)
[8] X Guo, J You, D Wei, J Shao, ZL Wang, A generalized model for tribovoltaic nanogenerator, Applied Physics Reviews, 11(2) (2024)
[9] B Sun, X Guo, Y Zhang, ZL Wang, J Shao, A generalized model for a triboelectric nanogenerator energy harvesting system, Nano Energy, 126, 109637 (2024)
[10] J Shao, ZL Wang, Displacement current theory of triboelectric nanogenerators, Handbook of Triboelectric Nanogenerators, 1-64 (2023)
[11] J Gravesen, M Willatzen, J Shao, ZL Wang, Modeling and optimization of a spherical triboelectric generator, Nano Research, 16(9), 11925-11931 (2023)
[12] J Gravesen, M Willatzen, J Shao, ZL Wang, Quantitative Calculation of Output Power and Spherical Triboelectric Nanogenerators, Handbook of Triboelectric Nanogenerators, 203-241 (2023)
[13] Y Nan, J Shao, D Li, X Guo, M Willatzen, Z Wang, Physical mechanisms of contact-electrification induced photon emission spectroscopy from interfaces, Nano research, 16(9), 11545-11555 (2023)
[14] C Fan, J Shao, X Guo, M Willatzen, ZL Wang, Field-circuit coupling model of triboelectric nanogenerators, Materials Today Physics, 35, 101124 (2023)
[15] T Cheng, J Shao, ZL Wang, Triboelectric nanogenerators, Nature Reviews Methods Primers, 3(1), 39 (2023)
[16] J You, J Shao, Y He, X Guo, KW See, ZL Wang, X Wang, Simulation model of a non‐contact triboelectric nanogenerator based on electrostatic induction, EcoMat, 5(10), e12392 (2023)
[17] X Guo, J Shao, M Willatzen, X Wang, ZL Wang, Quantifying output power and dynamic charge distribution in sliding mode freestanding triboelectric nanogenerator, Advanced Physics Research, 2(2), 2200039 (2023)
[18] J Gravesen, M Willatzen, J Shao, ZL Wang, Energy optimization of a mirror‐symmetric spherical triboelectric nanogenerator, Advanced Functional Materials, 32(18), 2110516 (2022)
[19] J Gravesen, M Willatzen, J Shao, ZL Wang, Modeling and optimization of a rotational symmetric spherical triboelectric generator, Nano Energy, 100, 107491 (2022)
[20] X Guo, J Shao, M Willatzen, Y Yang, ZL Wang, Three-dimensional mathematical modelling and dynamic analysis of freestanding triboelectric nanogenerators, Journal of Physics D: Applied Physics, 55(34), 345501 (2022)
[21] ZH Guo, HL Wang, J Shao, Y Shao, L Jia, L Li, X Pu, ZL Wang, Bioinspired soft electroreceptors for artificial precontact somatosensation, Science Advances, 8(21), eabo5201 (2022)
[22] X Guo, J Shao, M Willatzen, Y Yang, ZL Wang, Theoretical model and optimal output of a cylindrical triboelectric nanogenerator, Nano Energy, 92, 106762 (2022)
[23] Y Nan, J Shao, M Willatzen, ZL Wang, Understanding contact electrification at water/polymer interface, Research (2022)
[24] J You, J Shao, Y He, FF Yun, KW See, ZL Wang, X Wang, High-electrification performance and mechanism of a water–solid mode triboelectric nanogenerator, ACS nano, 15(5), 8706-8714 (2021)
[25] J Shao, Y Yang, O Yang, J Wang, M Willatzen, ZL Wang, Designing rules and optimization of triboelectric nanogenerator arrays, Advanced Energy Materials, 11(16), 2100065 (2021)
[26] J Shao, M Willatzen, ZL Wang, Theoretical modeling of triboelectric nanogenerators (TENGs), Journal of Applied Physics, 128(11) (2020)
[27] J Shao, D Liu, M Willatzen, ZL Wang, Three-dimensional modeling of alternating current triboelectric nanogenerator in the linear sliding mode, Applied Physics Reviews, 7(1) (2020)
[28] J Shao, M Willatzen, T Jiang, W Tang, X Chen, J Wang, ZL Wang, Quantifying the power output and structural figure-of-merits of triboelectric nanogenerators in a charging system starting from the Maxwell's displacement current, Nano Energy, 59, 380-389 (2019)
[29] J Shao, M Willatzen, Y Shi, ZL Wang, 3D mathematical model of contact-separation and single-electrode mode triboelectric nanogenerators, Nano Energy, 60, 630-640 (2019)
[30] J Shao, T Jiang, W Tang, X Chen, L Xu, ZL Wang, Structural figure-of-merits of triboelectric nanogenerators at powering loads, Nano Energy, 51, 688-697 (2018)
[31] JJ Shao, W Tang, T Jiang, XY Chen, L Xu, BD Chen, T Zhou, CR Deng, ..., A multi-dielectric-layered triboelectric nanogenerator as energized by corona discharge, Nanoscale, 9(27), 9668-9675 (2017)
[32] J Shao, X Zhou, Q Liu, R Zou, W Li, J Yang, J Hu, Mechanism analysis of the capacitance contributions and ultralong cycling-stability of the isomorphous MnO 2@ MnO 2 core/shell nanostructures for supercapacitors, Journal of Materials Chemistry A, 3(11), 6168-6176 (2015)
[33] J Shao, W Li, X Zhou, J Hu, Magnetic-field-assisted hydrothermal synthesis of 2× 2 tunnels of MnO 2 nanostructures with enhanced supercapacitor performance, CrystEngComm, 16(43), 9987-9991 (2014)

更新时间: 2026-06-14 14:02:46