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游检卫,教授、博导、东南大学青年首席教授、国家级高层次青年人才、IEEE高级会员。长期从事“电磁超构材料”和“计算电磁学”的软硬件开发,相关研究成果发表了70余篇学术论文、专著/章节5部,包括第一作者发表Science子刊、Nature子刊、IEEE Trans. 旗舰期刊等。拥有自主知识产权的软硬件平台服务于我国军民重点单位,获中国高等学校十大科技进展、中央高校优秀青年团队、江苏省科学技术一等奖等。主持和参与欧盟地平线计划欧洲研究理事会(ERC)重大项目、英国工程与自然科学研究理事会(EPSRC)项目、国家自然科学基金项目、国家重点研发计划项目、江苏省自然科学基金项目、南京市留学人员科技创新择优资助项目等。
在研:
国家自然科学基金项目:项目负责人,“电磁多物理计算模型及其应用”,2022/6 ~ 2025/6;
国家自然科学基金项目:项目负责人,“拓扑保护的可编程电磁超表面及其智能调控”,2022/1 ~ 2024/12;
江苏省自然科学基金项目:项目负责人,“智能编码的拓扑光电器件研究”,2021/7 ~ 2024/6;
已结题:
南京市留学人员科技创新择优资助项目:项目负责人,“电磁多物理计算的软件化和智能化”,2021/8 ~ 2022/7;
欧盟地平线计划欧洲研究理事会(ERC)重大项目:第二完成人,2016/1 ~ 2021/3;
英国工程与自然科学研究理事会(EPSRC)项目:第二完成人,2016/1 ~ 2017/1;
www.researchgate.net/profile/Jian-Wei-You/research
代表性学术专著及论文专著:
[1]
Jian Wei You, Zhihao Lan, and Nicolae C. Panoiu, Nonlinear topological photonics. In: Fundamentals and Applications of Nonlinear Nanophotonics, Elsevier Press, Cambridge, United States, 2023.
[2]
Jian Wei You, and Nicolae C. Panoiu, Nonlinear optical properties of 2D materials. In: Encyclopedia of Nanomaterials, pp.562-599. Oxford: Elsevier Press, Kidlington, United Kingdom, 2023.
[3]
Nicolae C. Panoiu, and Jian Wei You, Theory and applications of nonlinear optical interactions in 2D materials. In: Advances in Nonlinear Photonics, pp.247-286. Oxford: Elsevier Press, Kidlington, United Kingdom, 2023.
[4]
Ming Fang, Qun Ren, Jian Wei You, Zhihao Lan, Zhixiang Huang, Wei E. I. Sha, Advanced applications of nonlinear plasmonics. In: Plasmon-enhanced Light-matter Interactions, pp.117-135. Springer Nature, Switzerland, 2022.
[5]
游检卫,电磁超材料,第七章,超材料前沿进展:量子超材料,东南大学出版社,2022.
代表性论文:
*代表通信作者
[1]部分学术期刊论文
[1] You JW, Ma Q, Zhang L, Liu C, Zhang J, Liu S, Cui T. Electromagnetic Metamaterials: From Classical to Quantum. Electromagnetic Science. 2023 Mar;1(1):1-33.
[2] Chen L, Lan Z, Wu XW, Ma Q, You JW*, Cui TJ. Analog Quantum Valley–Hall and Quantum Spin Hall Plasmons in Graphene Metasurfaces with Low Point Group Symmetry. Advanced Physics Research.2023:2200076.
[3] You J.W.,Lan Z, Ma Q, Gao Z, Yang Y, Gao F, Xiao M, Cui TJ. Topological metasurface:From passive toward active and beyond. Photonics Research. 11(3):B65-102,2023.
[4] Zhang J, You J.W.*,Feng F, Na W, Lou ZC, Zhang QJ, Cui TJ. Physics-Driven Machine-Learning Approach Incorporating Temporal Coupled Mode Theory for Intelligent Design of Metasurfaces. IEEE Transactions on Microwave Theory and Techniques. 2023.
[5] Lan Z, Chen ML, You JW*,Wei EI. Large-area quantum-spin-Hall waveguide states in a three-layer topological photonic crystal heterostructure. Physical Review A. 2023Apr 12;107(4):L041501.
[6] Lou Z, Wu X, Hou J, Zhang J, You JW*,Cui T. Numerical Modelling of Dynamic Electromagnetic Problems Based on the Time-Domain Finite Integration Technique. Electronics. 2022 Nov26;11(23):3912.
[7] Xie, G., Huang, Z., You, J.W., Lan, Z., Panoiu, N.C.and Wei, E.I., Universal Vector-Scalar Potential Framework for Inhomogeneous Electromagnetic System and Its Application in Semiclassical Quantum Electromagnetics. IEEE Transactions on Plasma Science,2021.
[8] You, J.W., Ma, Q., Lan, Z., Xiao,Q., Panoiu, N.C. and Cui, T.J., Reprogrammable plasmonic topological insulators with ultrafast control. Nature communications, 12(1),pp.1-7, 2021.
[9] Zhang, Z., You, J.W., Lan, Z. and Panoiu, N.C.,Lattice topological edge and corner modes of photonic crystal slabs. Journal of Optics, 23(9), p.095102, 2021.
[10] Sekulic, I., You, J.W. and Panoiu, N.C., T-matrix method for calculation of second-harmonic generation in clusters of spherical particles. Journal of Quantitative Spectroscopy and Radiative Transfer, 268, p.107643,2021.
[11] Lan, Z., You, J.W., Ren, Q., Wei, E.I. and Panoiu,N.C., Second-harmonic generation via double topological valley-Hall kink modes in all-dielectric photonic crystals. Physical Review A, 103(4),p.L041502, 2021.
[12] Li, F., Chen, H., Zhou, Y., You, J. W., Panoiu, N.C.,Zhou, P. and Deng, L., Generation and Focusing of Orbital Angular Momentum Based on Polarized Reflectarray at Microwave Frequency. IEEE Transactions on Microwave Theory and Techniques, 69(3),pp.1829-1837,2020.
[13] You, J.W. and Panoiu, N.C.,Tunable and dual-broadband giant enhancement of second-harmonic and third-harmonic generation in an optimized graphene-insulator-graphene metasurface. Physical Review B, 102(12),p.121403, 2020.
[14] Wang, Y., You, J.W., Lan, Z. and Panoiu, N.C.,Topological valley plasmon transport in bilayer graphene metasurfaces for sensing applications. Optics Letters, 45(11),pp.3151-3154, 2020.
[15] Lan, Z., You, J.W. and Panoiu, N.C., Nonlinear one-way edge-mode interactions for frequency mixing in topological photonic crystals. Physical Review B, 101(15), p.155422,2020.
[16] You, J.W., Lan, Z., Bao, Q. and Panoiu, N.C., Valley-Hall topological plasmons in a graphene nanohole plasmonic crystal waveguide. IEEE Journal of Selected Topics in Quantum Electronics, 26(6), pp.1-8, 2020.
[17] You, J.W., Lan, Z. and Panoiu, N.C.,Four-wave mixing of topological edge plasmons in graphene metasurfaces. Science advances, 6(13), p.eaaz3910, 2020.
[18] You, J.W. and Panoiu, N.C.,Plasmon-induced nonlinearity enhancement and homogenization of graphene metasurfaces. Optics letters, 44(12),pp.3030-3033, 2019.
[19] Ren, Q., You, J.W. and Panoiu, N.C., Large enhancement of the effective second-order nonlinearity in graphene metasurfaces. Physical Review B, 99(20),p.205404,2019.
[20] You, J.W. and Panoiu,N.C., Analysis of the interaction between classical and quantum plasmons via FDTD–TDDFT method. IEEE Journal on Multiscale and Multiphysics Computational Techniques, 4, pp.111-118,2019.
[21] You, J.W., Bongu, S.R., Bao, Q. and Panoiu, N.C., Nonlinear optical properties and applications of 2D materials:theoretical and experimental aspects. Nanophotonics, 8(1),pp.63-97, 2018.
[22] You, J.W., Threlfall, E., Gallagher,D.F. and Panoiu, N.C., Computational analysis of dispersive and nonlinear 2D materials by using a GS-FDTD method. JOSA B, 35(11),pp.2754-2763, 2018.
[23] You, J.W. and Panoiu, N.C.,Polarization control using passive and active crossed graphene gratings. Optics express, 26(2), pp.1882-1894, 2018.
[24] Manrique DZ, You, J.W., Deng H, Ye F, Panoiu NC. Quantum plasmon engineering with interacting graphene nanoflakes. The Journal of Physical Chemistry C. 2017 Dec 14;121(49):27597-602.
[25] You, J.W., Zhang JF, Gu WH, Cui WZ,Cui TJ. Numerical analysis of passive intermodulation arisen from nonlinear contacts in HPMW devices. IEEE Transactions on Electromagnetic Compatibility. 2017 Oct 24;60(5):1470-80.
[26] You, J.W., You J, Weismann M, PanoiuNC. Double-resonant enhancement of third-harmonic generation in graphene nanostructures. Philosophical Transactions of the Royal Society A: Mathematical,Physical and Engineering Sciences. 2017 Mar 28;375(2090):20160313.
[27] You, J.W., Zhang JF, Jiang WX, MaHF, Cui WZ, Cui TJ. Accurate analysis of finite-volume lumped elements in metamaterial absorber design. IEEE transactions on microwave theory and techniques. 2016 Jun 10;64(7):1966-75.
[28] You, J.W., Cui TJ. Efficient approach to accurately analyze wireless propagation and fading in time domain. IEEE Antennas and Wireless Propagation Letters. 2016 Feb 26;15:1767-70.
[29] You, J.W., Wang HG, Zhang JF, Li Y,Cui WZ, Cui TJ. Highly efficient and adaptive numerical scheme to analyze multipactor in waveguide devices. IEEE Transactions on Electron Devices.2015 Feb 17;62(4):1327-33.
[30] You, J.W., Tan SR, Cui TJ. Novel adaptive steady-state criteria for finite-difference time-domain method. IEEE Transactions on Microwave Theory and Techniques. 2014 Nov13;62(12):2849-58.
[31] You, J.W., Wang HG, Zhang JF, TanSR, Cui TJ. Accurate numerical analysis of nonlinearities caused by multipactorin microwave devices. IEEE Microwave and Wireless Components Letters. 2014 Aug 6;24(11):730-2.
[32] You, J.W., Wang HG, Zhang JF, TanSR, Cui TJ. Accurate numerical method for multipactor analysis in microwave devices. IEEE Transactions on Electron Devices. 2014 Apr 3;61(5):1546-52.
[33] You, J.W., Tan S, Zhang J, Cui W,Cui T. A uniform time-domain finite integration technique (TDFIT) using an efficient extraction of conformal information. IEEE Antennas and Propagation Magazine. 2014 Jun 17;56(2):63-75.
[34] You, J.W., Tan SR, Zhou XY, Yu WM,Cui TJ. A new method to analyze broadband antenna-radome interactions in time-domain. IEEE transactions on antennas and propagation. 2013 Nov11;62(1):334-44.
[35] You, J.W., Wang HG, Zhang JF, CuiWZ, Cui TJ. The conformal TDFIT-PIC method using a new extraction of conformal information (ECI) technique. IEEE Transactions on Plasma Science.2013 Oct 4;41(11):3099-108.
代表性成果一:非线性电磁数值计算及器件设计
为有源光电器件的仿真建立了多个Maxwell方程的非线性耦合模型,并提出了相应的GS-FDTD数值求解算法,该算法被著名仿真软件Photon Design集成为独立的计算引擎,现已被全球30多个国家100多家科研机构使用。基于该自主开发的GS-FDTD数值仿真平台,成功设计了首款拓扑保护的太赫兹四波混频器件,相关成果以第一作者发表在Science子刊Science Advances (IF=13.7)。
代表性成果二:拓扑电磁数值计算及器件设计
为可编程电磁信息超材料的仿真巧妙设计了场路耦合模型,并提出了FVLE-FDTD数值求解算法,该算法可以有效考虑电磁模型和电路模型的强耦合过程,因而可以对电控光电器件进行准确分析。基于自主开发的FVLE-FDTD数值仿真工具,成功设计了首款导波型可编程拓扑超表面,相关第一作者成果发表在Nature子刊Nature Communications (IF=12.1),拓扑光子学先驱Alexander Khanikaev教授(OSA Fellow)评价该项工作为“拓扑光子学的一个重要里程碑”。
代表性成果三:多物理数值计算及软件开发
为高功率微波器件的仿真建立了电磁粒子耦合模型,并提出了共形PIC-FDTD数值求解算法,该算法可以有效模拟带电粒子和电磁波之间的相互作用,因而可以对高功率微波器件进行高效分析。基于PIC-FDTD算法为我国重要部门自主研发了多款电磁仿真软件,相关工作获得了XX科学技术进步一等奖。
2023 中央高校优秀青年团队(2/10)
2022 江苏省科学技术一等奖(2/7)
2022 中国高等学校十大科技进展 (青年骨干2/8)
2021 Nature Communications Editors' Highlight paper
2020 ESI Top1% 高被引论文奖
2019 美国光学学会OL编辑部精选论文奖 (OSA OL Top10 Editor’s Pick Papers)
2019 IEEEJMMCT编辑部推出的最受欢迎论文奖(Top50 Popular Articles)
2017 美国光学学会青年科学家提名奖
2017 XX科学进步一等奖
2017 江苏省优秀博士论文
2016 中国电子学会优秀博士论文提名奖
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