姓名:任群 
邮箱:renqun@tju.edu.cn
职务:通信系副主任
职称:副教授
政治面貌:中共党员
天津大学长聘副教授、通信系副主任,教育部海外引才专项入选者。本科连续四年成绩全班第一获天津大学工学学士学位,后国家公派直博获伦敦大学学院(QS世界前10)工学博士学位。以“归国即报国”为初心,面向极端应急场景下北斗空天地6G量子增强通感算一体化互联网络的国家重大需求,攻关量子电磁互联(太赫兹量子接口、折纸微波量子调控),合著出版Springer Nature、Springer、中国工程院蓝皮书、科学出版社行业白皮书学术专著/章节4部(专著2部、专著章节2章),发表Science Advances、Advanced Materials等63篇学术论文,当选2026年IEEE纳米技术学会(NTC)青年专业人才大使(2026年全球4人)、提名国际应用计算电磁大会青年女科学家奖(2024年全国唯一)。科教融汇、立德树人方面,获教创赛、青椒赛等4项教学讲课类奖项,作为第一指导教师,带领学生获“互联网+”“西门子杯”国赛银奖、华北特等奖等4项国省部级创业奖项;以第二指导教师,带领学生获“挑战杯”天津市特等奖。主持国自然、国际交流引进、重点研发子课题、毫米波国家重点实验室、天津市面上、产教融合等10项项目。
主要经历:
(1) 2022-今 天津大学,电气自动化与信息工程学院,长聘副教授/副研究员、系副主任
(2) 2020-2022 天津大学,电气自动化与信息工程学院,讲师、教育部海外引才专项
(3) 2019-2019 英国 伦敦大学学院(UCL),研究助理
(4) 2015-2019 英国 伦敦大学学院(UCL),公派全奖,工学博士
(5) 2014-2014 新加坡 南洋理工大学(NTU),淡马锡基金,访问学士
(6) 2011-2015 天津大学,电子信息工程学院,工学学士
讲授课程:
《应用机器学习(主讲)》(全英文,专业核心课程)
《基于优化理论的机器学习》(专业基础课程)
《光通信工程前沿技术及行业标准(主讲)》(全英文,天大华为智能基座产教融合课程)
《电磁场理论(主讲)》(专业基础课程)
《电磁场与电磁波(授课成员)》(专业基础课程)
主要奖励及荣誉:
(1) 2026:IEEE纳米技术学会NTC青年学者大使(全球4人)
(2) 2026:第二届成像探测与信息处理学术会议 优秀青年科技奖
(3) 2026:指导学生梁永珊获第二届成像探测与信息处理学术会议 优秀墙报奖
(4) 2025:天津大学自动化学院十佳教工
(5) 2025:天津大学2025年青年教工示范岗
(6) 2025:ICAN大学生创新创业大赛天津市一等奖 第一指导教师
(7) 2025:教育部“互联网+”大学生创新创业大赛国家银奖 第一指导教师
(8) 2025:教育部“西门子杯”中国智能制造挑战赛华北赛区 特等奖 第一指导教师
(9) 2025:共青团 第十八届“挑战杯”全国大学生课外学术科技竞赛天津市特等奖第二指导教师
(10) 2025:第十八届天津“挑战杯”天津大学课外学术科技作品竞赛特等奖第一指导教师
(11) 2025:天津大学第五届教师教学创新大赛二等奖
(12) 2024:天津大学电气自动化与信息工程学院新工科项目式课程优秀案例优秀奖
(13) 2024:天津大学-华为“智能基座”产教融合协同育人基地(联接领域)奖教金
(14) 2024:国际应用计算电磁大会(ACES)青年女科学家荣誉提名奖(年度全国1人)
(15) 2024:天津大学本科毕业设计优秀指导教师
(16) 2023/2025:天津高校第十七、十八届青年教师教学竞赛选拔赛三等奖
(17) 2023:教育部——天津大学优质发展潜力青年导师
(18) 2023:天津大学科技创新领军人才培育“启明计划”
(19) 2020:教育部——国家海外引才专项计划
(20) 2015~2019:教育部——国家留学基金委公派直博
(21) 2015~2019:伦敦大学学院院长奖
(22) 2015:潍柴动力奖学金
(23) 2014:新加坡淡马锡基金会奖学金
(24) 2013:教育部——国家奖学金
(25) 2012:教育部——国家奖学金
科研项目:
(1) 2025-2029 产教融合项目,光电融合方向,项目负责人
(2) 2025-2028 天津市自然科学基金面上项目,太赫兹方向,项目负责人
(3) 2024-2026 产教融合项目,光电人工智能方向,项目负责人
(4) 2023-2026 国家重点研发计划项目,超材料方向,子课题负责人
(5) 2023-2024 天津大学科技创新领军人才培育“启明计划”项目,智能超材料方向,项目负责人
(6) 2022-2024 国家自然科学基金青年项目,量子超表面方向,项目负责人
(7) 2022-2023 东南大学毫米波国家重点实验室开放课题,电磁超表面方向,项目负责人
(8) 2022-2023 中国博士后科学基金面上资助项目,电磁超表面方向,项目负责人
(9) 2021-2022 产教学研融合项目,光电融合方向,项目负责人
(10) 2020-2022 中国博士后国际交流计划引进项目,光量子方向,项目负责人
(11) 2020-2020 天津大学自主创新基金,B5G通信方向,项目负责人
(12) 2015.09-2019.09 国家留学基金委公派项目,光量子方向,项目负责人
(13) 2015.09-2019.09 伦敦大学学院院长奖项目,计算电磁方向,项目负责人
(14) 2014.01-2014.05 新加坡淡马锡基金项目,模型控制方向,项目负责人
(15) 2021.08-2023.07 国家重点研发计划“战略性科技创新合作”重点专项,B5G通信方向,项目骨干
(16) 2022.01-2025.12 国家自然科学基金面上项目,人工智能方向,参与成员
(17) 2022.01-2025.12 国家自然科学基金面上项目,光量子方向,参与成员
(18) 2015.05-2020.05 欧盟研究委员会(ERC)项目,电磁与应用光学方向,参与成员
教学项目:
(1) 2025-2027 首批天津市级新形态教材建设项目,负责人
(2) 2024-2024 新工科项目式教改项目,负责人
(3) 2024-2024教育部天大—华为“智能基座”产教融合协同育人基地(联接领域)项目负责人
(4) 2024-2024 电磁场课程思政建设项目负责人
(5) 2023-2023 新工科教学改革项目,电磁场模块负责人
教学论文:
(1) 产教学研融合背景下的智能电磁场项目式课程探索,中国信息界,2024
(2) 基于AI+生态的电磁场课程项目式教学改革探索,《中国教育技术装备》,2026
学术论著:
(1) Plasmon-enhanced Light-matter Interactions, Chapter: Advanced Applications of Nonlinear Plasmonics,Springer, ISBN 978-3-030-87543-5,2022
(2) New Advances on Maxwell’s Equations and Applications, Chapter: Quantum Effects in Maxwell’s Equations,Springer Nature,ISBN978-3-031-75785-3,2025
(3) 麦克斯韦方程新拓展和应用,第二章 麦克斯韦方程量子化,科学出版社《中国电子信息工程科技发展研究》ISBN:9787030821690,2025
(4) 后摩尔时代微纳新器件电磁场专题, 第一章,第二章,科学出版社《中国电子信息工程科技及发展研究》工作组系列专题书ISBN 978-7-03-082817-0,2025
学术论文(待更新):
1) Terahertz Microfluidic Metasensors for Precise Determination of Organic Aqueous Solutions Based on Wavelet-Assisted Convolutional Neural Networks,submitted.
2) Optical vortices induced by quasi-continuum bound states,submitted.
3) Programmable metamaterial brain based on dual hybrid BIC for terahertz anti-interference, submitted.
4) Achievement of Interface-dependent Manipulation for Topological Edge States in Valley Photonic Crystals, submitted.
5) Deep learning-optimized bilayer metasurface based on robust magnetic dipole coupling for MRI Enhancement at 70mT, submitted.
6) Conformal MRI decoupling isolator inspired by omnidirectional polarization conversion of ultrahigh-Q metamaterial, submitted.
7) Nonlinear-Enhanced Programmable High-Q BIC Metasurfaces for Intelligent Terahertz Electromagnetic Computing via Neural Network Inverse Design, submitted.
8) L. He, Z. Lan, J. Yao, Q. Ren, J. W. You, Wei E. I. Sha, and L. Wu, Transport of topological large-area hybrid waveguide states in magnetic photonic crystals, submitted.
9) Xiuyu Wang, Haoran Xu, Qun Ren, Jiangtao Xu, Zhijian Wang, Changyue Wang, Sensitivity improvement of ZnSnO3-based UV detector: Strengthened light absorption, spectrum red shift and dark current inhibition, Journal of Alloys and Compounds 1063, 187634, 2026.
10) High-Q factor terahertz metasurface based on topological protection. Chinese journal of radio science 41(1): 148-154 (2026).
11) Experimental observation of valley Hall topological waveguide based on interface engineering, Frontiers of Physics 21(10), 103203 (2026).
12) Optical Computation-in-Communication enables low-latency, high-fidelity perception in telesurgery,Nature Communications,minor corrections (2025).
13) Reconfigurable modular origami for tunable 2D symmetry groups, Science Advances 11.46: eady3812 (2025). Deep learning-optimized bilayer metasurface based on robust magnetic dipole coupling for MRI Enhancement at 70mT, Optics Express 33.20: 42617-42629 (2025).
14) Y Jia, Y Pang, R Jin, Y Liu, X Xiao, Q Ren, Zhenchang Wang, A Unified Circular-Polarization Metamaterial-Resonator for Increasing SNR of Breast MRI, Magnetic Resonance Imaging, 121, 110403 (2025).
15) Ren, Q., Jia, S., et al. Integrated plasmonic ruler using terahertz multi-BIC metasurface for digital biosensing. Moore. More 2, 5 (2025).
16) Qun Ren, Yongjing Dang, XiuYu Wang, Huang hao, Yuxin Lang, Yongshan Liang, Dening Fan, Jianan Zhang, Jian Wei You, and Yanwei Pang, Phantom-metasurface cooperative system trained by deep learning network driven by bound state for magnetic-resonance-enhanced system, Optics Letters 50, 1723-1726 (2025).
17) Hao Li, Jia Nan Zhang, Ming Rui Su, Yunping Qi, Qun Ren, Jian Wei You and Yanwei Pang, All-dielectric metasurfaces: generating optical vortices through quasi-bound states in the continuum and thermal tunability, Journal of Physics D: Applied Physics, 58 (2025) 145001
18) Liu He, Yuting Yang, Qun Ren, Xiuyu Wang, Liang Wu & Jianquan Yao, Achievement splitting for one-way helical edge states in phase modulation by using gyromagnetic photonic crystals, Scientific Reports 14, 17253 (2024).
19) Xiuyu Wang, Xiaoman Wang, Qun Ren, Kaiwen Zou, Boxiang Yang, Zhihao Lan, Liu He, Jianwei You, Liu He, Wei E. I. Sha and Jianquan Yao, Realization of secure robotic brain via programmable metasurface with robust high-order BIC, Advanced Optical Materials, 12(33), 2401611 (2024).
20) L. He, Q. Ren, Z. Lan, Wei E. I. Sha, J. W. You, Y. Zhang, and J. Yao, Reprogrammable location of light source for achieving tunable multi-switching of unidirectional helical edge states in topological photonic crystals, Optics Communications, 566, 130718 (2024).
21) L. He, Z. Lan, Y. Yang, Q. Ren, J. W. You, Wei E. I. Sha, L. Wu, and J. Yao, “Wavelength division multiplexing based on coupling effect of helical edge states in two-dimensional dielectric photonic crystals,” Optics Express 32, 11259-11270 (2024).
22) Q. Ren, Y. Lang, Y. Jia, X. Xiao, Y. Liu, X. Kong, R. Jin, Y. He, J. Zhang, J. You, Wei E. I. Sha, and Y. Pang, “High-Q metasurface signal isolator for 1.5T surface coil magnetic resonance imaging on the go,” Optics Express 32, 8751-8762 (2024).
23) L. He, Z. Lan, B. Yang, J. Yao, Q. Ren, J. W. You, Wei E. I. Sha, Y. Yang, and L. Wu, “Experimental observation of topological large-area pseudospin-momentum locking waveguide states with exceptional robustness,” Advanced Photonics Nexus 3, 016009 (2024).
24) X. Wang, X. Wang, Z. Yao, G. Guo, Y. Jia, Y. He, R. Jin, J. You, Q. Ren, Q. Xu, Wei E. I. Sha, and Y. Pang, “Digital imaging through terahertz multifrequency programmable metasurface based on BIC,” Optical Materials 143, 114154 (2023).
25) X. Wang, X. Wang, J. Xin, J. Li, Q. Ren, H. Cai, Y. Lang, Z. Lan, Y. Jia, R. Jin, Y. He, J. W. You, Wei E.I. Sha, and Y. Pang, “Tailoring the bound states in the multi-channel nonlinear plasmonic metasurfaces,” Optics Communications 549, 129834 (2023).
26) L. He, Q. Ren, Z. Lan, Wei E. I. Sha, J. W. You, Y. Zhang, and J. Yao, “Coexistence of slow light states and valley-polarized kink states in all-dielectric valley photonic crystals with triangular lattice,” Optics and Laser Technology 167, 109790 (2023).
27) X. Wang, T. Wang, Q. Ren, J. Xu, and Y. Cui, “Construction of localized state levels and near-infrared light absorption of silicon: B/P doping and first-principles calculations,” Micro and Nanostructures 184, 207695 (2023).
28) X. Wang, X. Wang, Q. Ren, H. Cai, J. Xin, Y. Lang, X. Xiao, Z. Lan, J. W. You, and Wei E. I. Sha, “Temperature-controlled Optical Switch Metasurface with Large Local Field Enhancement Based On FW-BIC,” Front. Nanotechnol. 5.1112100 (2023).
29) X. Wang, X. Wang, Q. Ren, H. Cai, J. Xin, Y. Lang, X. Xiao, Z. Lan, J. W. You, and Wei E. I. Sha, “Polarization Multiplexing Multichannel High-Q Terahertz Sensing System,” Front. Nanotechnol. 5.1112346 (2023).
30) C. Liu, X. Wang, Q. Ren, Z. Yang, Y. Cui, and J. Xu, “Enhanced UV detection of ZnSnO3 hollow spheres: Dark current inhibition from excitons and homostructures based on excitation of oxygen vacancies,” Ceramics International 49, 14459-14469 (2023).
31) L. He, Q. Ren, Z. Lan, Wei E. I. Sha, J. W. You, Y. Zhang, and J. Yao, “Steering of One-Way Large-Area Waveguide Modes in Topological Heterostructures with Gyromagnetic Photonic Crystals,” Optik 272, 170323 (2023).
32) L. He, Q. Ren, Y. Zhang, and J. Yao, “Manipulation for One-way Large-Area Helical Waveguide States in Topological Heterostructure,” Optical Materials 135, 113320 (2023).
33) S. Chen, Q. Ren, K. Zhang, Wei E. I. Sha, T. Hao, W. Wang, H. Xu, J. Zhao, and Y. Li, “A highly sensitive and flexible photonic-crystal oxygen sensor,” Sensors and Actuators B: Chemical 355, 131326 (2022).
34) X. Wang, B. Leng, Q. Ren, Z. Yang, J. Xin, and X. Wang, “Formation and dissociation of excitons in La3+-doped BaSnO3 and improvement of ethanol sensitivity: Heating, nano-CdSnO3 decoration and UV illumination,” Journal of Alloys and Compounds 926, 166812 (2022).
35) X. Wang, J. Xin, Q. Ren, H. Cai, J. Han, C. Tian, P. Zhang, L. Jiang, Z. Lan, J. W. You, and Wei E. I. Sha, “Plasmon hybridization stimulated by quasi bound state in the continuum of graphene metasurfaces oriented for high-accuracy polarization-insensitive two-dimensional sensors,” Chinese Optics Letters 20, 042201 (2022).
36) X. Lai, Q. Ren, F. Vogelbacher, Wei E. I. Sha, X. Hou, Y. Song, and M. Li, “Bioinspired Quasi-3D Multiplexed Anti-counterfeit imaging via Self-assembled and Nanoimprinted Photonic Architectures,” Advanced Materials, 34, 2107243 (2022).
37) X. Wang, J. Ma, Q. Ren, M. Wang, Z. Yang, and J. Xin, “Effects of Fe3+-doping and nano-TiO2/WO3 decoration on the ultraviolet absorption and gas-sensing properties of ZnSnO3 solid particles,” Sensors and Actuators B: Chemical 344, 130223 (2021).
38) Q. Zhang, D. Liu, Q. Ren, N. C. Panoiu, L. Lin, J. Ye, Y. Huang, S. Liu, C. W. Leung and D. Lei, “Probing electron transport in plasmonic molecular junctions with two-photon luminescence spectroscopy,” Nanophotonics 10, 2467–2479 (2021).
39) Q. Ren, F. Feng, X. Yao, Q. Xu, M. Xin, Z. Lan, J. W. You, X. Xiao, and Wei E. I. Sha, “Multiplexing-oriented plasmon-MoS2 hybrid metasurfaces driven by nonlinear quasi bound states in the continuum,” Optics Express 29, 5384-5396 (2021).
40) T. Wang, Q. Ren, K. Şafak, F. X. Kärtner, and Ming Xin, “Attosecond-precision balanced linear-optics timing detector,” Optics Express 29, 38140-38149 (2021).
41) Z. Lan, J. W. You, Q. Ren, Wei E. I. Sha, and N. C. Panoiu, “Second-harmonic generation via double topological valley-Hall kink modes in all-dielectric photonic crystals,” Physical Review A 103, 4 (2021).
42) S. Yu, X. Li, L. Zhao, M. Wu, Q. Ren, B. Gong, L Li, and H. Shi, “Simultaneously improved Conductivity and Adhesion of Flexible Ag NW Networks Via Hot Lamination Process,” Synthetic Metals 267, 116475 (20).
43) Q. Ren, J. W. You, and N. C. Panoiu, “Comparison between the linear and nonlinear homogenization of graphene and silicon metasurfaces,” IEEE Access 8, 175753-175764 (2020).
44) Q. Ren, J. W. You and N. C. Panoiu, “Large enhancement of the effective second-order nonlinearity in graphene metasurfaces,” Physical Review B 99, 205404 (2019).
45) Q. Ren, J. W. You and N. C. Panoiu, “Giant enhancement of the effective Raman susceptibility in metasurfaces made of silicon photonic crystal nanocavities,” Optics Express 26, 30383-30392 (2018).
46) L. Li, H. Cai, Q. Ren, H. Sun and Z. Gao, “Microstructure and microwave dielectric characteristics of ZnTi (Nb1-xSbx)2O8 ceramics,” Ceramics International 40, 12213–12217 (2014).
47) L. Li, Z. Gao, Q. Ren, H. Cai and S. Li, “Effect of Zn-excess on sintering behavior and microwave dielectric properties in Mg0.97Zn0.03TiO3 ceramics,” Journal of Alloys and Compounds 617, 841–844 (2014).
48) Design of a Bound State in the Continuum Metasurface for Photonic Computing Applications ISEMC 2025.
49) Symmetry-Protected Dual Bound States in Continuum Metasurfaces for Terahertz Photonic Applications ISEMC 2025.
50) Study on High-Q Nonlinear Metasurfaces Based on Symmetry-Breaking-Induced Quasi-BIC ISEMC 2025.
51) Excitation and Verification of Multi-Channel BICs in Metasurfaces Based on Structural Symmetry Breaking ISEMC 2025.
52) High-Field Enhancement Isolator for 1.5T MRI Surface Coil-Metamaterial Decoupling ISEMC 2025.
53) Design of a Three-Layer Isolator for Decoupling MRI Surface Coils and Metamaterials, and Its Magnetic Field Enhancement Effect IEEE NEMO 2025.
54) High-Q Metasurface via Quasi-BIC Resonance for Optical Differentiation IEEE NEMO 2025.
55) Terahertz neural network based on bound states in the continuum IEEE NEMO 2025.
56) Qun Ren, Yongjing Dang, Zhaoyang Zhang, Ruiqi Jin, Xiaohan Liu, Yanwei Pang, Magnetic resonance-driven deep learning of electromagnetic metamaterials, 13242-42, SPIE 13242-42, 2024.
57) Qun Ren, Yuxin Lang, Zher Yian Ooi, Yaoyin Zhang, Haoyang Sun, Yanwei Pang, Decoupling isolator inspired by conformal metasurface for significant MRI enhancement, Proceedings Volume 13418, Fifteenth International Conference on Information Optics and Photonics (CIOP 2024); 1341806 (2024).
58) 基于连续域束缚态的共形电磁超表面隔离器--用于便携式医疗磁共振成像,第三届中国超材料大会,浙江,乌镇互联网国际会展中心,5.9-5.12,2024
59) 基于残差神经网络的全波段电磁超材料智能设计与调控,第三届中国超材料大会,乌镇,浙江,乌镇互联网国际会展中心,5.9-5.12,2024
60) Ren Qun, Lang Yuxin, Jia Sheng, Liang Yongshan, Ren Haoyang Sha Wei E.I. Conformal metamaterial isolator for 1.5T MRl system, The 14th International Symposium on Antennas, Propagation and EM Theory, IEEE 2024.
61) Q. Ren, X. Wang, Y. Liang, L. Zhang, X. Wang and W. E. I. Sha, "Security Device Based on Terahertz Metasurface with Robust High-Order BIC," 2024 14th International Symposium on Antennas, Propagation and EM Theory (ISAPE), Hefei, China, 2024, pp. 1-4, doi: 10.1109/ISAPE62431.2024.10840748..
62) Q. Ren, Y. Dang, X. Wu, K. -V. Ling, W. E. I. Sha and Y. Pang, "Design and Manipulation of Electromagnetic Metasurface Based on Bidirectional Deep Neural Network," 2024 14th International Symposium on Antennas, Propagation and EM Theory (ISAPE), Hefei, China, 2024, pp. 1-4, doi: 10.1109/ISAPE62431.2024.10841319.
63) Y. Dang, Y. Zheng, Q. Ren, X. Xiao, Y. He, and Y. Pang, “In-series Deep Learning Techniques for Magnetic Resonance Imaging (MRI) Computation Electromagnetics”, PIERS, 21-25 April, Chengdu, China (2024).
64) [Invited] Y. Lang, Q. Ren, X. Xiao, Y. He, and Y. Pang, “E-type Resonator Metasurface Based on BIC for Controllable Multi-band Filtering”, PIERS, 21-25 April, Chengdu, China (2024).
65) X. Wang, T. Wei, H. Huang, K. Zou and Q. Ren, "BIC-based breaking symmetry E-type resonator," 2024 International Applied Computational Electromagnetics Society Symposium (ACES-China), Xi'an, China, 2024, pp. 1-3, doi: 10.1109/ACES-China62474.2024.10699892., (ACES-China 2024)
66) [Invited] Qun Ren, Xiaoman Wang, Xiuyu Wang, Fangmiao Wang, Yongiing Dang, Jianwei You, and Wei E. I. Sha, Higher order BIC of metasurface excited by magnetic EIT, 2024 International Applied Computational Electromagnetics Society Symposium, pp. 1-3, doi: 10.1109/ACES-China62474.2024.10699822
67) [Invited] Q. Ren, J. W. You and N. C. Panoiu, “Large Enhancement of effective Raman susceptibility of a metasurface made of silicon photonic crystal cavities,” PIERS, 1-4 August, Toyama, Japan (2018).
68) Q. Ren, J. W. You and N. C. Panoiu, “Enhanced optical nonlinearity of metasurfaces made of patterned graphene nanoribbons,” Advanced Photonics, 2-5 July, ETH Zurich, Switzerland (2018).
69) Q. Ren, J. W. You and N. C. Panoiu, “Enhancement of effective second- and third-order optical nonlinearities of graphene-based metasurfaces,” 3-6 September, Photon 2018, Birmingham, UK (2018).
70) V. M. F. Laguna, Q. Ren and N. C. Panoiu, “Pulsed dynamics in a system of coupled silicon photonic crystal cavity-waveguide nanostructures,” 11 - 15 August, SPIE Optics + Photonics, San Diego, California, United States, Proceedings Volume 11081, Active Photonic Platforms XI; 110812D (2019)
71) V. M. F. Laguna, Q. Ren and N. C. Panoiu, “Optical Pulse Dynamics in a Silicon Photonic Crystal Waveguide Coupled with a set of Photonic Crystal Optical Cavities,” International Workshop on Optical Wave & Waveguide Theory and Numerical Modelling, 10-11 May, Málaga, Spain (2019).
72) J. W. You, Q. Ren, and N. C. Panoiu, “Strongly Enhanced Second- and Third-harmonic Generation in Graphene Metasurfaces,” 19th IEEE International Conference on Nanotechnology, 22-26 July, Parisian Macao, Macau, China 19th IEEE International Conference on Nanotechnology, Macau SAR, China, July 22-26, Volume: (2019).
73) Qun Ren, Xiaoman Wang, Wang Xiuyu, Yuxin Lang, A Terahertz High-intensity Temperature-switching Plasmonic Metasurface Based on FW-BIC, PIERS, Prague, Czech, 2023. DOI: 10.1109/PIERS59004.2023.10221239
74) Manipulation of the Nonlinear Plasmonic Bound State in the Continuum of Metasurfaces, PIERS, Prague, Czech, 2023.
75) 超构表面非线性连续域束缚态,第二十一届全国基础光学与光物理学术讨论会,2023
76) 基于连续域束缚态的非线性光学超表面多路定向调控,第三届全国光子技术论坛(GZLT2023)
77) Qun Ren, Xiuyu Wang, Xiaoman Wang, Yuxin Lang, A terahertz high-intensity-field temperature-switching plasmonic metasurface based on FW-BIC, The 14th International Conference on Information Optics and Photonics (CIOP2023)
78) [Invited]Bound states in the continuum of metamaterials, CMMC, Nanjing, China, 2023.
79) 基于连续域束缚态的非线性光学超表面多路定向调控,第二十五届全国激光学术会议(Laser2022)
80) 王童,李明哲,于子航,张祎,任群,辛明,高精度光学定时探测技术及其应用研究,[J]. 计测技术. 2022 (05)
81) T. Wang, Q. Ren, K. Şafak, F. X. Kärtner, and M. Xin, “An attosecond-precision balanced linear timing detector,” Conference on Lasers & Electro-Optics (CLEO), STh1C.4 (2021).
82) M. Li, T. Wang, Y. Zhang, Q. Ren, and M. Xin, “A compact 90-degree bending waveguide constructed using an intelligent inverse design algorithm,” Conference on Lasers & Electro-Optics (CLEO), JW2A.110 (2023).
83) Manipulation of the nonlinear plasmonic bound state in the continuum of metasurfaces with a quantum oscillator, PIERS, Hangzhou, China, 2021.
84) Linear and Nonlinear Homogenization of plasmonic and all-dielectric Metasurfaces, PIERS, Hangzhou, China, 2021.
85) Q. Ren, D. Zs. Manrique and N. C. Panoiu, “Design of two-mode quantum waveguide made of silicon photonic crystal nanocavities,” Barlow Memorial Lecture, Department of Electronic and Electrical Engineering, UCL, London, UK (2017).
86) Q. Ren, J. W. You and N. C. Panoiu, “Homogenization of Si-based and graphene-based metasurfaces,” Barlow Memorial Lecture, Department of Electronic and Electrical Engineering, UCL, London, UK (2018).
发明专利:
(1) 针对少模光纤表征系统精准模式激发与时间标定的方法,2025110420943
(2) 低压光电倍增式微光CMOS图像传感器像素单元,2024106000846
(3) 基于三角晶格拓扑光子晶体大宽度波导波分复用分束器,CN202310363314.7
(4) 一种基于超材料、表面线圈和去耦超表面的磁场增强器,ZL202311421300.2
(5) 一种智能超材料结构,ZL202311411431.2
(6) 高量子效率宽光谱吸收CIS新型像素设计和工艺实现方法,2023106494184
(7) 基于CMOS图像传感器应用的宽光谱吸收光电二极管设计,2023106494184
(8) 一种基于三角晶格谷光子晶体的慢光波导态,CN115903332A
(9) 一种基于三角晶格拓扑谷光子晶体的双带宽谷霍尔偏振扭态波导,CN115826136A
(10) 面向B5G通信的多通道可调控非线性电磁超构表面构建方法,202211174943.7
(11) 一种基于多通道调控非线性超表面的滤波器结构,202211176006.5
(12) 一种基于超构表面连续域束缚态的非线性响应调控方法,202104243869
(13) 一种面向高度集成化的拉曼高阶拓扑激光源的设计方法,202011103370.X
软件著作权:
(1) 基于COMSOL with MATLAB的光波段低损耗模型BIC求解软件,2023SR0214538
