邵佳佳 - 北京雁栖湖应用数学研究院

邮箱: shaojiajia@bimsa.cn

个人简介

邵佳佳，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月在瑞典交流访学；2019年6月至2021年6月在纳米能源所进行博士后研究，2023年1月晋升为青年研究员。主要研究方向：纳米发电机物理基础、计算电磁学、多物理场建模与动态仿真等。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7100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10项，Frontiers in Materials、Nanoenergy Advances等期刊客座主编和青年编委。

研究兴趣

纳米发电机物理基础
多物理系统的建模与动力学计算
理论计算与仿真

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 副研究员
2023 - 2026 北京纳米能源与系统研究所 青年研究员
2021 - 2022 北京纳米能源与系统研究所 副研究员
2019 - 2021 北京纳米能源与系统研究所, 中国科学院大学 博士后
2018 - 2019 瑞典吕勒奥理工大学 访问学者

荣誉与奖项

2018 Elsevier优秀审稿人

学术服务

2023 - Nanoenergy Advance 编委
2022 - 中国物理学会 会员
2020 - Frontires in Materials 客座主编

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] Y Wei, X Li, B Sun, L Yang, J Shao, ZL Wang, D Wei, Triboelectric-induced polarization directing molecular self-assembly without chemical functionalization, Nano Energy, 111991 (2026)
[4] T An, X Pan, Z Wang, K Jin, Y Xie, X Meng, G Nie, Z Wang, X Sun, R Chen, ..., Designing Nonplanar Electron Acceptors for High-Performance Organic Photodetectors: Mechanism Analysis and Application in Gesture Recognition, ACS nano, 19(31), 28268-28279 (2025)
[5] 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)
[6] J You, J Shao, Y He, B Sun, KW See, ZL Wang, X Wang, Interface triboelectricity, EcoEnergy, 3(1), 105-130 (2025)
[7] J Shao, S Niu, SRP Silva, M Willatzen, Theory of nanogenerators and Maxwell’s equations for a mechano-driven system, Mrs Bulletin, 50(3), 283-294 (2025)
[8] 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)
[9] H Monluc, D He, X Pan, J Zhang, L Ding, J Shao, ZL Wang, J Bai, Dynamic modelling of charge transport in solid–liquid systems, Nano Energy, 111536 (2025)
[10] 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)
[11] 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)
[12] JS ERPING Li, ZHONGLIN WANG, Chapter 1, Classical Maxwell’s Equations, New Advances in Maxwell’s Equations and Applications, 1, 1-28 (2024)
[13] J Liu, Z Yang, S Li, Y Du, Z Zhang, J Shao, M Willatzen, ZL Wang, D Wei, Nonaqueous contact-electro-chemistry via triboelectric charge, Journal of the American Chemical Society, 146(46), 31574-31584 (2024)
[14] C Li, Y Bai, J Shao, H Meng, Z Li, Strategies to improve the output performance of triboelectric nanogenerators, Small Methods, 8(10), 2301682 (2024)
[15] X Guo, J You, D Wei, J Shao, ZL Wang, A generalized model for tribovoltaic nanogenerator, Applied Physics Reviews, 11(2) (2024)
[16] C Li, R Luo, Y Bai, J Shao, J Ji, E Wang, Z Li, H Meng, Z Li, Molecular doped biodegradable triboelectric nanogenerator with optimal output performance, Advanced Functional Materials, 34(29), 2400277 (2024)
[17] H Zhao, H Wang, H Yu, Q Xu, X Li, J Guo, J Shao, ZL Wang, M Xu, W Ding, Theoretical modeling of contact-separation mode triboelectric nanogenerators from initial charge distribution, Energy & Environmental Science, 17(6), 2228-2247 (2024)
[18] Y Wei, X Li, Z Yang, J Shao, ZL Wang, D Wei, Contact electrification at the solid–liquid transition interface, Materials Today, 74, 2-11 (2024)
[19] 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)
[20] EP Li, ZL Wang, New Advances in Maxwell's Equations and Applications, Springer (2024)
[21] JS ERPING Li, ZHONGLIN WANG, Chapter 6, Electromagnetism of Moving Observers in Free-Space, New Advances in Maxwell’s Equations and Applications, 1, 199-233 (2024)
[22] Z Yu, Y Zhang, M Willatzen, J Shao, ZL Wang, Momentum transfer in triboelectric nanogenerators, Advanced Physics Research, 3(4), 2300115 (2024)
[23] J Shao, ZL Wang, Displacement current theory of triboelectric nanogenerators, Handbook of Triboelectric Nanogenerators, 1-64 (2023)
[24] J Gravesen, M Willatzen, J Shao, ZL Wang, Quantitative Calculation of Output Power and Spherical Triboelectric Nanogenerators, Handbook of Triboelectric Nanogenerators, 203-241 (2023)
[25] ZL Wang, J Shao, Recent progress on the Maxwell's equations for describing a mechano-driven medium system with multiple moving objects/media, Electromagnetic Science, 1(2), 1-16 (2023)
[26] T Cheng, J Shao, ZL Wang, Triboelectric nanogenerators, Nature Reviews Methods Primers, 3(1), 39 (2023)
[27] X Li, S Li, X Guo, J Shao, ZL Wang, D Wei, Triboiontronics for efficient energy and information flow, Matter, 6(11), 3912-3926 (2023)
[28] ZL Wang, Y Yang, J Zhai, J Wang, Handbook of triboelectric nanogenerators, Springer Nature (2023)
[29] ZL WANG, JJ SHAO, Theory of Maxwell’s equations for a mechano-driven media system for a non-inertia medium movement system, SCIENTIA SINICA Technologica, 53(6), 803-819 (2023)
[30] X Bai, Y Nan, K Yang, B Deng, J Shao, W Hu, X Pu, Zn ionophores to suppress hydrogen evolution and promote uniform Zn deposition in aqueous Zn batteries, Advanced Functional Materials, 33(42), 2307595 (2023)
[31] J Gravesen, M Willatzen, J Shao, ZL Wang, Modeling and optimization of a spherical triboelectric generator, Nano Research, 16(9), 11925-11931 (2023)
[32] 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)
[33] 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)
[34] C Fan, J Shao, X Guo, M Willatzen, ZL Wang, Field-circuit coupling model of triboelectric nanogenerators, Materials Today Physics, 35, 101124 (2023)
[35] ZL WANG, JJ SHAO, From Faraday’s law to the expanded Maxwell’s equations for a mechano-driven media system that moves with acceleration, SCIENTIA SINICA Technologica, 53(3), 430-444 (2023)
[36] 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)
[37] 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)
[38] Z Zhang, J Shao, Y Nan, M Willatzen, ZL Wang, Theory and shape optimization of acoustic driven triboelectric nanogenerators, Materials Today Physics, 27, 100784 (2022)
[39] Y Nan, J Shao, M Willatzen, ZL Wang, Understanding contact electrification at water/polymer interface, Research (2022)
[40] L Zu, D Liu, J Shao, Y Liu, S Shu, C Li, X Shi, B Chen, ZL Wang, A self‐powered early warning glove with integrated elastic‐arched triboelectric nanogenerator and flexible printed circuit for real‐time safety protection, Advanced Materials Technologies, 7(5), 2100787 (2022)
[41] 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)
[42] J Gravesen, M Willatzen, J Shao, ZL Wang, Modeling and optimization of a rotational symmetric spherical triboelectric generator, Nano Energy, 100, 107491 (2022)
[43] ZL WANG, JJ SHAO, Maxwell’s equations for a mechano-driven varying-speed motion media system under slow motion and nonrelativistic approximations, SCIENTIA SINICA Technologica, 52(8), 1198-1211 (2022)
[44] ZL WANG, JJ SHAO, Maxwell’s equations for a mechano-driven varying-speed-motion media system for engineering electrodynamics and their solutions, Scientia Sinica Technologica, 52(9), 1416-1433 (2022)
[45] 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)
[46] J Gravesen, M Willatzen, J Shao, ZL Wang, Energy optimization of a mirror‐symmetric spherical triboelectric nanogenerator, Advanced Functional Materials, 32(18), 2110516 (2022)
[47] W Gao, J Shao, K Sagoe-Crentsil, W Duan, Investigation on energy efficiency of rolling triboelectric nanogenerator using cylinder-cylindrical shell dynamic model, Nano Energy, 80, 105583 (2021)
[48] 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)
[49] Y Nan, D Tan, J Shao, M Willatzen, ZL Wang, 2D materials as effective cantilever piezoelectric nano energy harvesters, ACS Energy Letters, 6(6), 2313-2319 (2021)
[50] 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)
[51] C Jiang, L Wang, J Shao, H Jing, X Ye, C Jiang, H Wang, C Ma, Screening and identifying of α‐amylase inhibitors from medicine food homology plants: Insights from computational analysis and experimental studies, Journal of food biochemistry, 44(12), e13536 (2020)
[52] J An, Z Wang, T Jiang, P Chen, X Liang, J Shao, J Nie, M Xu, ZL Wang, Reliable mechatronic indicator for self-powered liquid sensing toward smart manufacture and safe transportation, Materials Today, 41, 10-20 (2020)
[53] J Shao, M Willatzen, ZL Wang, Theoretical modeling of triboelectric nanogenerators (TENGs), Journal of Applied Physics, 128(11) (2020)
[54] H Liu, Y Feng, J Shao, Y Chen, ZL Wang, H Li, X Chen, Z Bian, Self-cleaning triboelectric nanogenerator based on TiO2 photocatalysis, Nano Energy, 70, 104499 (2020)
[55] D Liu, B Chen, J An, C Li, G Liu, J Shao, W Tang, C Zhang, ZL Wang, Wind-driven self-powered wireless environmental sensors for Internet of Things at long distance, Nano Energy, 73, 104819 (2020)
[56] F Zhan, AC Wang, L Xu, S Lin, J Shao, X Chen, ZL Wang, Electron transfer as a liquid droplet contacting a polymer surface, ACS nano, 14(12), 17565-17573 (2020)
[57] JJ Shao, T Jiang, ZL Wang, Theoretical foundations of triboelectric nanogenerators (TENGs), Science China Technological Sciences, 63(7), 1087-1109 (2020)
[58] Z Wang, J An, J Nie, J Luo, J Shao, T Jiang, B Chen, W Tang, ZL Wang, A self‐powered angle sensor at nanoradian‐resolution for robotic arms and personalized medicare, Advanced Materials, 32(32), 2001466 (2020)
[59] 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)
[60] Y Hao, X Zhou, J Shao, Y Zhu, The influence of multiple fillers on friction and wear behavior of epoxy composite coatings, Surface and coatings technology, 362, 213-219 (2019)
[61] J Nie, Z Ren, Y Bai, J Shao, T Jiang, L Xu, X Chen, ZL Wang, Long distance transport of microdroplets and precise microfluidic patterning based on triboelectric nanogenerator, Advanced Materials Technologies, 4(1), 1800300 (2019)
[62] W Zhong, L Xu, X Yang, W Tang, J Shao, B Chen, ZL Wang, Open-book-like triboelectric nanogenerators based on low-frequency roll–swing oscillators for wave energy harvesting, Nanoscale, 11(15), 7199-7208 (2019)
[63] C Wu, TW Kim, JH Park, B Koo, S Sung, J Shao, C Zhang, ZL Wang, Self-powered tactile sensor with learning and memory, ACS nano, 14(2), 1390-1398 (2019)
[64] 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)
[65] 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)
[66] Z Ren, J Nie, J Shao, Q Lai, L Wang, J Chen, X Chen, ZL Wang, Fully elastic and metal‐free tactile sensors for detecting both normal and tangential forces based on triboelectric nanogenerators, Advanced Functional Materials, 28(31), 1802989 (2018)
[67] J Nie, Z Ren, J Shao, C Deng, L Xu, X Chen, M Li, ZL Wang, Self-powered microfluidic transport system based on triboelectric nanogenerator and electrowetting technique, Acs Nano, 12(2), 1491-1499 (2018)
[68] B Chen, W Tang, T Jiang, L Zhu, X Chen, C He, L Xu, H Guo, P Lin, D Li, ..., Three-dimensional ultraflexible triboelectric nanogenerator made by 3D printing, Nano energy, 45, 380-389 (2018)
[69] TX Xiao, X Liang, T Jiang, L Xu, JJ Shao, JH Nie, Y Bai, W Zhong, ..., Spherical triboelectric nanogenerators based on spring‐assisted multilayered structure for efficient water wave energy harvesting, Advanced functional materials, 28(35), 1802634 (2018)
[70] L Xu, T Jiang, P Lin, JJ Shao, C He, W Zhong, XY Chen, ZL Wang, Coupled triboelectric nanogenerator networks for efficient water wave energy harvesting, ACS nano, 12(2), 1849-1858 (2018)
[71] TX Xiao, T Jiang, JX Zhu, X Liang, L Xu, JJ Shao, CL Zhang, J Wang, ..., Silicone-based triboelectric nanogenerator for water wave energy harvesting, ACS applied materials & interfaces, 10(4), 3616-3623 (2018)
[72] BD Chen, W Tang, C He, CR Deng, LJ Yang, LP Zhu, J Chen, JJ Shao, ..., Water wave energy harvesting and self-powered liquid-surface fluctuation sensing based on bionic-jellyfish triboelectric nanogenerator, Materials today, 21(1), 88-97 (2018)
[73] J Wen, B Chen, W Tang, T Jiang, L Zhu, L Xu, J Chen, J Shao, K Han, ..., Harsh‐environmental‐resistant triboelectric nanogenerator and its applications in autodrive safety warning, Advanced Energy Materials, 8(29), 1801898 (2018)
[74] BD Chen, W Tang, C He, T Jiang, L Xu, LP Zhu, GQ Gu, J Chen, JJ Shao, ..., Ultrafine capillary‐tube triboelectric nanogenerator as active sensor for microliquid biological and chemical sensing, Advanced Materials Technologies, 3(1), 1700229 (2018)
[75] J Shao, T Jiang, W Tang, L Xu, TW Kim, C Wu, X Chen, B Chen, T Xiao, ..., Studying about applied force and the output performance of sliding-mode triboelectric nanogenerators, Nano Energy, 48, 292-300 (2018)
[76] 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)
[77] Y Bai, CB Han, C He, GQ Gu, JH Nie, JJ Shao, TX Xiao, CR Deng, ..., Washable Multilayer Triboelectric Air Filter for Efficient Particulate Matter PMRemoval, Advanced Functional Materials, 28(15), 1706680 (2018)
[78] J Nie, T Jiang, J Shao, Z Ren, Y Bai, M Iwamoto, X Chen, ZL Wang, Motion behavior of water droplets driven by triboelectric nanogenerator, Applied Physics Letters, 112(18) (2018)
[79] C Wu, TW Kim, JH Park, H An, J Shao, X Chen, ZL Wang, Enhanced Triboelectric Nanogenerators Based on MoSMonolayer Nanocomposites Acting as Electron-Acceptor Layers, ACS nano, 11(8), 8356-8363 (2017)
[80] X Chen, Y Wu, J Shao, T Jiang, A Yu, L Xu, ZL Wang, On‐skin triboelectric nanogenerator and self‐powered sensor with ultrathin thickness and high stretchability, Small, 13(47), 1702929 (2017)
[81] 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)
[82] 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)
[83] W Li, G He, J Shao, Q Liu, K Xu, J Hu, IP Parkin, Urchin-like MnO2 capped ZnO nanorods as high-rate and high-stability pseudocapacitor electrodes, Electrochimica Acta, 186, 1-6 (2015)
[84] W Li, J Shao, Q Liu, X Liu, X Zhou, J Hu, Facile synthesis of porous Mn2O3 nanocubics for high-rate supercapacitors, Electrochimica Acta, 157, 108-114 (2015)
[85] Z Wu, D Lei, G Yuan, J Shao, Y Zhang, Z Wang, Structural reliability analysis of parabolic trough receivers, Applied energy, 123, 232-241 (2014)
[86] 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)
[87] X Zhou, J Shao, B Wan, A One-Step Electrochemical Method for the Production of TiONNanotubes, Journal of the Electrochemical Society, 160(6), H335-H337 (2013)

更新时间: 2026-05-25 12:27:44