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长期从事超材料等人工电磁材料的基础和应用研究。基础研究中,着重利用微结构对称性设计突破人工电磁材料工作带宽、效率技术瓶颈,并发展了可实现电磁波各基本属性任意调控的多自由度微结构设计方法。作为第一作者或/和通讯作者在Phys. Rev. Lett,Photonics Research,IEEE T ANTENN PROPAG,Appl. Phys. Lett,Opt. Lett.等国际核心刊物发表论文十余篇,共发表论文35篇,总被引530余次。
所在团队长期从事新型人工电磁材料的理论和应用研究,有着充实的理论和实验积累。团队重点开展电磁透明、波束整形、模式调控等方向机理探索,以及在通讯器件、装备应用等领域的自动化器件设计研究。团队拥有包括微波暗室、矢量网络分析仪、大功率激光器在内的丰富实验条件,还构建了包括自编算法和多种主流商用电磁仿真软件的设计计算平台。
承担项目:
[1] 军委科技委国防科技创新特区重点项目,xxxxxx技术研究,600万元,2020.06~2022.06。
[2] 自然科学基金面上项目(11874286),基于几何相位调控的电磁超表面设计研究,63万元,2019.01~2022.12。
[3] 东莞同济大学研究院横向课题,基于超材料宽带波束调控的新型相控阵天线设计技术体系研究,360万元,2020.1~2023.12.
[4] 自然科学基金青年基金项目(61205041),手征特异材料电磁波偏振态调控特性研究,28万元,2013.01~2015.12。
[5] 第52批中国博士后基金面上资助(2012M520922),手征电磁超材料设计与偏振控制特性研究,5万元,2012.10~2016.04。
[6] 第6批中国博士后基金特别资助(2013T60460),手征超材料界面及拓扑效应研究,15万元,2013.06~2016.04。
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支持扩展名:.rar .zip .doc .docx .pdf .jpg .png .jpeg在应用研究中,利用幅相独立调控机制,研制了超宽带紧耦合超材料天线阵,应用于新型模拟相控前端和自适应感知装备,获军委科技委集成创新重点项目支持,主持其中总体技术课题,经费600万元,并获校地合作项目1项,经费360万元。研制了几何相涡旋波束宽带超材料天线,应用于探索一代重点项目研究中,近期探索结合MIMO技术实现空地高速数传,并申请国防项目支持。主持基金面上项目1项,已结题青年基金,博士后基金项目3项,作为主要发明人申请专利26项,已获授权专利16项。
主要论文列表
[1] Zhang, Z., C.Wu, Q. Li, S. Zhao and H. Li., Complex-amplitudemodulation of surface waves based on a metasurface coupler, Optics Express 31(6): 9620-9630. (2023)
[2] Li, Q., C.Wu, Z. Zhang, S. Zhao, B. Zhong, S. Li, H. Li and L. Jin, High-Purity Multi-Mode Vortex BeamGeneration With Full Complex-Amplitude-Controllable Metasurface, IEEE Transactions on Antennas andPropagation 71(1): 774-782. (2023).
[3] Li, Q., C.Wu, S. Zhao, Z. Zhang, B. Zhong, S. Li, H. Li and L. Jin, Compact Anisotropic Metasurface for FullRange and Arbitrary Complex-Amplitude Control, IEEE Photonics Journal 14(1): 1-6. (2022).
[4] Wu,C., Q. Li, S. Zhao, Z.-H. Zhang, and H.-Q. Li, Control of phase, polarization and amplitude based on geometric phasein a racemic helix array. PhotonicsResearch (2021) Accepted, Early Posting.
[5] Wu,C., Q. Li, S. Zhao, Z.-H. Zhang, S.-J. Wei, and H.-Q. Li, Analytical full complex-amplitude controlstrategy for metasurface. New Journalof Physics, 23(8): p. 083023. (2021).
[6] Wu, C., Q. Li, S. Zhao, Z.H.Zhang, X. Liu, S.J. Wei, and H.Q. Li, BroadbandEfficient Polarization-Pure Airy Beam Generation Based on Three-LayerMetasurface. Physica Status SolidiB-Basic Solid State Physics, 2100002. (2021).
[7] Wu, C., Q. Li, S. Zhao, Z.Zhang, X. Liu, S. Wei, and H. Li, BroadbandEfficient Dual-Polarization Airy Beam Generation with Reflective Metasurface.Physica Status Solidi B-Basic SolidState Physics, 258(5): p. 2100002.(2021).
[8] C. Wu, H. Li, X.Yu, F. Li, H. Chen, and C. T. Chan, MetallicHelix Array as a Broadband Wave Plate. PhysicalReview Letters 107, 177401(2011).
[9] C. Wu, H. Li, Z. Wei, X. Yu, and C. T. Chan, Theory and Experimental Realization ofNegative Refraction in a Metallic Helix Array. Physical Review Letters 105,247401 (2010).
[10] Li,Q., C. Wu*, X. Liu, S. Zhao,Z.H. Zhang, X.B. Shang, Z.Y. Wei, and H.Q. Li, Geometric Phase Based Circular Array for Multimode Vortex BeamGeneration. Annalen Der Physik, 531(12): p. 8 (2019).
[11] Z. Gong, C. Wu*, C. Fang, S. Zhao, A.Sun, Z. Wei, and H. Li, Broadbandefficient vortex beam generation with metallic helix array. Applied Physics Letters 113, 071104 (2018).
[12] C. Fang, C.Wu*, Z. Gong, S. Zhao, A. Sun, Z. Wei, and H. Li, Broadband and high-efficiency vortex beam generator based on a hybridhelix array. Optics Letters 43, 1538-1541 (2018).
[13] Z.Gong, C. Wu*, Q. Li, Z. Wei,and H. Li, A Design of Functional Layerwith Robust Constitutive Parameters for Multilayer Metamaterials. Advances in Materials Science andEngineering 2017, 13 (2017).
[14] Cheng, K.,W. Zhang, Z. Wei, Y. Fan, C. Xu, C.Wu, X. Zhang, and H. Li, SimulateDeutsch-Jozsa algorithm with metamaterials. Optics Express, 28(11):p. 16230-16243. (2020).
[15] P. Wang, W.Yang, S. Shen, C. Wu, L. Wen,Q. Cheng, B. Zhang, and X. Wang, DifferentialDiagnosis and Precision Therapy of Two Typical Malignant Cutaneous Tumors LeveragingTheir Tumor Microenvironment: A Photomedicine Strategy. ACS. Nano, 13, 11168−11180 (2019).
[16] Xiaobing,S., C. Dieter, C. Fang, X. Chaowei, L. Quan, W. Chao, L. Hongqiang, J. Changjun, and S. Herbert De, Dual-frequency liquid crystal-polymergrating for fast response optical beam steering. Smart Materials andStructures, (2019).
[17] Cheng, K.,Z. Wei, Y. Fan, X. Zhang, C. Wu,and H. Li, Realizing BroadbandTransparency via Manipulating the Hybrid Coupling Modes in Metasurfaces forHigh-Efficiency Metalens. AdvancedOptical Materials, 0(0): p.1900016 (2019).
[18] Zhang,W.X., K.Y. Cheng, C. Wu, Y.Wang, H.Q. Li, and X.D. Zhang, ImplementingQuantum Search Algorithm with Metamaterials. Advanced Materials, 30(1)(2018).
[19] Yin, X., H.Zhu, H.J. Guo, M. Deng, T. Xu, Z.J. Gong, X. Li, Z.H. Hang, C. Wu, H.Q. Li, S.Q. Chen, L. Zhou, and L. Chen, Hyperbolic Metamaterial Devices for Wavefront Manipulation. Laser & Photonics Reviews, 13(1) (2018).
[20] W. Zhang, K. Cheng, C. Wu, Y. Wang, H. Li, and X. Zhang, Implementing Quantum Search Algorithm with Metamaterials. Advanced Materials 30, 1703986 (2018).
[21] X. Su, Z. Wei, C. Wu, Y. Long, and H. Li, Negative reflection from metal/graphene plasmonic gratings. Optics Letters 41, 348-351 (2016).
[22] Y. Bian, C.Wu, H. Li, and J. Zhai, A tunablemetamaterial dependent on electric field at terahertz with barium strontiumtitanate thin film. Applied PhysicsLetters 104, 042906 (2014).
[23] Z. Wei, Y. Cao, Z. Gong, X. Su, Y. Fan, C. Wu, J. Zhang, and H. Li, Subwavelength imaging with a fishnet flatlens. Physical Review B 88, 195123 (2013).
[24] Y. Cao, Z. Wei, C. Wu, H. Li, H. Chen, and K. Cai, Collimation effect inside complete bandgap of electromagnetic surfaceresonance states on a metal plate perforated with a triangular array of airholes. Optics Express 20, 25520-25529 (2012).
[25] J. Han, H. Li, Y. Fan, Z. Wei, C. Wu, Y. Cao, X. Yu, F. Li, andZ. Wang, An ultrathin twist-structurepolarization transformer based on fish-scale metallic wires. Applied Physics Letters 98, 151908 (2011).
[26] Y. Fan, J. Han, Z. Wei, C. Wu, Y. Cao, X. Yu, and H. Li, Subwavelength electromagnetic diode: One-way response of cascadingnonlinear meta-atoms. Applied PhysicsLetters 98, 151903 (2011).
[27] Z. Wei, H. Li, Y. Cao, C. Wu, J. Ren, Z. Hang, H. Chen, D. Zhang, and C. T. Chan, Spatially coherent surface resonance statesderived from magnetic resonances. NewJournal of Physics 12, 093020(2010).
[28] Z. Wei, H. Li, C. Wu, Y. Cao, J. Ren, Z. Hang, H. Chen, D. Zhang, and C. T.Chan, Anomalous reflection from hybridmetamaterial slab. Optics Express18, 12119-12126 (2010).
[29] Z. Wei, Y. Cao, J. Han, C. Wu, Y. Fan, and H. Li, Broadband negative refraction in stacked fishnet metamaterial. Applied Physics Letters 97, 141901 (2010).
已授权专利列表
[1] 基于超材料模块实现涡旋波束编码、解码及通信的方法,201710366020.4,发明人中排名第4,已授权,申请/授权日2020.09.29
[2] 一种喷涂机的喷涂方法,ZL 201610670916.7,发明人中排名第4,已授权,申请/授权日 2019.04.26
[3] 一种星地通信系统和方法,ZL 201510111357.1,发明人中排名第3,已授权,申请/授权日 2019.04.16
[4] 一种同轴线测试方法,ZL 201610799191.1,发明人中排名第4,已授权,申请/授权日 2019.02.22
[5] 一种光刻机及方法, ZL 201610670785.2,发明人中排名第4,已授权,申请/授权日 2018.11.30
[6] 一种X…X数据传输方法和系统,ZL 201418009340.1,发明人中排名第3,已授权,申请/授权日2017.02.15
[7] 一种基于金属螺旋线的宽频带波片,ZL201110044348.7,发明人中排名第2,已授权,申请/授权日2017.09.26
[8] 一种基于一维复式光栅结构的高定向平面天线,ZL200810034702.6,发明人中排名第2,已授权,申请/授权日2015.11.25
[9] 一种X…X方法,ZL201318004141.7,发明人中排名第3,已授权,申请/授权日2015.08.26
[10] 一种电磁波波束调控装置,ZL201310146377.3,发明人中排名第3,已授权,申请/授权日2015.07.22
[11] 一种X…X吸波体,ZL 201218000964.8,发明人中排名第3,已授权,申请/授权日2014.08.06
[12] 一种X…X吸波体,ZL 201218000963.3,发明人中排名第3,已授权,申请/授权日2014.08.06
[13] 一种平面结构闪耀光栅,ZL201010169432.7,发明人中排名第4,已授权,申请/授权日2013.10.16
[14] 一种太赫兹或红外频段灵敏光子探测器,ZL201010169415.3,发明人中排名第4 ,已授权,申请/授权日2013.06.26
[15] 一种宽频带空间相干热辐射光源,ZL201010169422.3,发明人中排名第4,已授权,申请/授权日2013.05.01
[16] 一种双频超薄高定向谐振腔天线,ZL200710171727.6,发明人中排名第3,已授权,申请/授权日2011.06.22
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同济大学
