副教授 硕士生导师
电子邮箱:
所在单位:微波光子技术国家级重点实验室
职务:党支部副书记
学历:博士研究生毕业
办公地点:电子信息工程学院办公室110
孔祥鲲,考证系孔子七十五代血脉;博士,副教授,硕导;协助国家级领军人才团队指导博士生;电子科学与技术系党支部副书记;南航直升机动力学全国重点实验室、天元实验室、雷达成像与微波光子技术教育部重点实验室固定组成人员;国际电气电子工程师学会 (IEEE)高级会员(Senior Member)(全球会员占比7%);中国电子学会高级会员;国家自然科学基金评审专家;教育部学位中心评审专家;中航工业行业标准制定专家;Nature子刊《Scientific Reports》编委;英国圣安德鲁斯大学公派访问学者。获江苏省教育科学研究成果奖,南京市自然科学优秀论文奖,南京航空航天大学教学优秀奖,教育成果奖等。主持国家自然科学面上项目、军委装备预研项目、海军装备预研项目、航空科学基金项目等60余项;在中科院期刊分区1区、JCR分区1区、行业顶刊等发表SCI学术论文240余篇,被引3500余次(2025谷歌学术统计)。研究成果得到中国工程院贲德院士,IEEE Fellow、北京理工大学长三角研究院战略科学家沈忠祥教授,IEEE Antennas and Propagation Magazine主编F. Andriulli教授等国内外知名专家成果鉴定与推荐。
课题组特色:
2017年以来就业深造率100%,整体就业去向统计
强调课题组之间、师生之间合作共赢,为学生提供从设计到验证的全流程训练,杜绝大组人才“内卷”和“赛马制”;
个性化定制培养模式,人均资源占比高;
课题组管理制度化,避免因导师好恶产生学生偏见;
互联网协作思维,体验“字节跳动”运营模式。
教师个人主页:
http://faculty3.nuaa.edu.cn/~UnM3Ir/zh_CN/index.htm
个人学术网页:
https://www.researchgate.net/profile/Xiang-Kun-Kong-2/research
http://scholar.google.com/citations?hl=en&user=TqIs8B4AAAAJ
微信公众号:电磁隐身与智能结构课题组,分享课题组新闻,科研学习资料,社会服务信息。
主讲课程:
(1) 《天线原理》,本科必修课程;
(2) 《高级电磁仿真与微波测量》,研究生选修课程(双语);
(3) 《电磁仿真与微波电路CAD》,本科选修课;
研究方向:
(1) 人工电磁结构与材料特性,频率选择表面设计;(学术研究为主,工程实践辅助,潜在就业方向:升学深造,国防与航空航天领域,如“十大军工集团”)
(2) 射频集成电路设计与测试;(国家级领军人才课题组集成电路芯片方向联合培育)(工程实践为主,学术研究为辅,潜在就业方向:升学深造,半导体与芯片设计领域,如思佳讯(Skyworks)、威讯联合半导体(Qorvo)等芯片设计公司,台积电、中芯国际、力芯微电子、卓胜微电子、新洁能、SK海力士、中科芯、格科微电子、苏州国芯、杭州士兰等集成电路制造企业)
(3) 雷达天线罩设计与应用;(工程实践为主,学术研究为辅,潜在就业方向:国防与航空航天领域,如“十大军工集团”)
(4) 电磁兼容与防护评估;(工程实践为主,学术研究为辅,潜在就业方向:国防与航空航天领域,如“十大军工集团”,电磁兼容测试领域研究所及相关企业)
(5) 雷达目标散射特性分析;(工程实践为主,学术研究为辅,潜在就业方向:国防与航空航天领域,如“十大军工集团”)
(6) 可重构智能超表面通信系统;(学术研究工程实践并举,潜在就业方向:通信领域及电子设备制造领域,如华为、中兴、荣耀等设备制造企业、苹果、小米等手机终端厂商;移动、电信、联通等无线通信运营企业)
(7) 电磁智能结构与天线一体化设计。(学术研究工程并举,潜在就业方向:通信领域及电子设备制造领域,如华为、中兴、荣耀等设备制造企业、苹果、小米等手机终端厂商;移动、电信、联通等无线通信运营企业)
科研平台建设:
一、材料电性能参数测试系统
二、电磁波传输特性测试系统
三、雷达目标特性(RCS)测量系统
四、智能超表面通信平台(与工信部“天地一体频谱认知智能实验室”联合研发)
学术会议组织与特邀报告:
[1] IEEE International Conference on Computational Electromagnetics (ICCEM 2019), Mar. 20-22, Shanghai, China. Session Co-Chair;
[2] 2019年全国超材料大会分会场特邀报告,2019年11月24-27日,中国西安;
[3] 微波领域旗舰会议:IEEE Asia-Pacific Microwave Conference (APMC2019), Singapore;
[4] 2020达索系统SIMULIA CST电磁仿真应用研讨会特邀报告,2020年9月10日,中国南京;
[5] IEEE 3rd International Conference on Electronic Information and Communication Technology (ICEICT 2020),Shenzhen,China. Invited Talk;
[6] 国防科技大学,湘江论坛——“电磁调控新技术”特邀报告,2020年12月5日,中国长沙;
[7] 微波领域旗舰会议: IEEE 2021 International Conference on Microwave and Millimeter Wave Technology (ICMMT 2021),Nanjing,China. Sesstion Chair.
[8] 微波领域旗舰会议: IEEE 2022 International Conference on Microwave and Millimeter Wave Technology (ICMMT 2022),Harbin,China. Invited Talk; Sesstion Co-Chair.
[9] 2022 International Applied Computational Electromagnetics Society (ACES-China) Symposium, Xuzhou,China. Sesstion Co-Chair.
[10] 微波领域旗舰会议: IEEE International Conference on Computational Electromagnetics (ICCEM2024), Nanjing, China. Sesstion Chair.
[11] 天线领域旗舰会议: IEEE Asia-Pacific Conference on Antennas and Propagation(APCAP'2024),Nanjing, China. Invited Talk;
[12] 微波领域旗舰会议: IEEE 2025International Conference on Microwave and Millimeter Wave Technology (ICMMT 2025),Xi'an, China. Sesstion Chair& Invited Talk;
[13] 天线领域旗舰会议: IEEE Asia-Pacific Conference on Antennas and Propagation(APCAP'2025),Christchurch(基督城), New Zealand. Sesstion Chair.
[14] IEEE MTT-S International Microwave Workshop Series on Advanced Materials and Processes for RF and THz Applications (IMWS-AMP 2025), Wuxi,China. Technical Program Committee Member.
发表学术论文,出版专著情况:
一、 专著
[1] 孔祥鲲,刘志明,卞博锐,刘少斌. 新型电磁超材料及其在低散射天线中的应用。北京:电子工业出版社,2022.
[2] 刘少斌,章海锋,莫锦军,孔祥鲲,刘崧. 等离子体光子晶体理论. 北京:科学出版社,2016.
二、 期刊论文
2025年
[1] Zou, Y., Kong, X., Hou, Z., Wang, L., Chen, Q., Zhao, Y., ... & Gao, S., "A Wideband Amplifying Frequency-Selective Rasorber Based on a 2.5-D Antenna-Circuit-Antenna Structure," IEEE Transactions on Antennas and Propagation, vol. 73, no. 8, pp. 5600-5609, Aug. 2025, doi: 10.1109/TAP.2025.3564693. (行业顶刊, 中科院1区)
[2] Hou, Z., Cheng, J., Kong, X., Zou, Y., Pan, H., Pang, X., & Zhao, S. (2025). Design of Ultra-Broadband Metamaterial Absorber with Angle-insensitive Characteristics Covering the L, S, C, X, and Ku Bands. IEEE Antennas and Wireless Propagation Letters.
[3] Wang, L., Zhu, M., Wang, X., Liu, S., Zhou, Y., Huang, Z., & Fu, S. (2025). The Integrated Design of Broadband Frequency Selective Surface and Distributed Lightning Diversion Layer. IEEE Antennas and Wireless Propagation Letters.
[4] Huang, Y., Liu, Z., Kong, X., Zhou, H., Lei, Z., & Wang, Y. (2025). A Dual-Polarized 3D Radiation Pattern Reconfigurable Fabry–Perot Antenna Based on Liquid-Based Partially Reflective Surface. IEEE Antennas and Wireless Propagation Letters., doi: 10.1109/LAWP.2025.3615294
[5] Yu, D., Kong, X., Wang, L., Hou, Z., & Zhou, S. (2025). Wideband Multifunctional Metasurface With Integrated Polarization Conversion and Low in sertionloss Transmission. Microwave and Optical Technology Letters, 67(9), e70382.
2024年
[1] Zhang, X., Kong, X., Zhou, S., Liu, P., Zou, Y., Chen, J., ... & Gao, S. (2024). High-Accuracy Beam Generation and Scanning Using Reconfigurable Coding Metasurface. Journal of Physics D: Applied Physics.
[2] Sajjad, M., Kong, X., Liu, S., & Irshad Khan, M. (2024). Multifunction and switchable hybrid metasurface based on graphene and gold. Applied Optics, 63(12), 3099-3107.
[3] Zou, Y., Kong, X., Zhou, S., Wang, L., Zhao, Y., & Gao, S. (2024). A 3-D Wideband and High-selectivity Amplifying Frequency Selective Surface Based on Slot line and Microstrip line. IEEE Transactions on Antennas and Propagation.(行业顶刊,中科院1区刊物,IEEE视频在线报道)
视频链接:https://mp.weixin.qq.com/s/efXoirG3z_5MqOGyvclLFQ
[4] Liu, P., Kong, X., Cao, Z., Zhang, X., Zhou, S., Zou, Y., ... & Zhao, S. (2024). All-liquid frequency selective absorber design with flexibility and wide-angle stability. Journal of Physics D: Applied Physics, 57(24), 245102.
[5] Wang, Y., Liu, Z., Zhou, H., Bornemann, J., Wang, Y., & Kong, X. (2024). A High‐Gain Wideband Fabry‐Pérot Antenna Employing a Water‐Based Frequency Selective Surface for Polarization‐and RCS‐Reconfigurability. International Journal of RF and Microwave Computer‐Aided Engineering, 2024(1), 1804375.
[6] Zhou, S., Kong, X., Wu, W., Cheng, J., Zou, Y., Zhang, X., & Gao, S. (2024). Forced Convection Cooling Antenna Array with Reduced Radar Cross Section. IEEE Antennas and Wireless Propagation Letters.
[7] 程健来,孔祥鲲,费钟阳,等. 吸波材料覆盖直升机强散射源RCS缩减分析[J]. 南京航空航天大学学报,2024,56(2):217-226. DOI:10.16356/j.1005-2615.2024.02.003.
2023年
[1] Wang, X., Kong, X., Kong, L., Zhang, X., Zhou, S., Xing, L., & Zhu, D. (2023). Bifunctional Water-based Frequency Selective Absorber Regulated by Gravity Field. IEEE Antennas and Wireless Propagation Letters.
[2] Zou, Y., Kong, X., Cao, Z., Zhang, X., & Zhao, Y. (2023). Reconfigurable integrated structures with functions of Fabry–Perot antenna and wideband liquid absorber for radar system stealth. Scientific Reports, 13(1), 14678.
[3] Sajjad, M., Kong, X., Liu, S., Rahman, S. U., & Khan, Z. (2023). Ultra-wideband Terahertz Absorber Based on E Shape Graphene Pattern. The Applied Computational Electromagnetics Society Journal (ACES), 129-136.
[4] Kong, X., Cao, Z., Wang, X., Lin, W., Zou, Y., Wang, H., ... & Gao, S. (2023). Wide-passband reconfigurable frequency selective rasorber design based on fluidity of EGaIn. IEEE Antennas and Wireless Propagation Letters, 22(8), 1922-1926.
[5] Lin, W., Kong, X., Xu, Q., Fang, F., Xia, W., & Qi, W. (2023). Improving working volume and total scattering cross section using polarization convertor stirrer in a reverberation chamber. Microwave and Optical Technology Letters, 65(7), 1865-1872.
[6] 张馨予,孔祥鲲,刘子庆,等.加载可重构智能超表面的无人机通信系统设计与验证(2023).电波科学学报, DOI: 10.12265/j.cjors.2023242
2022年
[1] Liao, K., Sun, S., Zheng, X., Shao, X., Kong, X., & Liu, S. (2022). A novel polarization converter based on the band-stop frequency selective surface. Chinese Physics B, 31(2), 024211.
[2] Zou, Y., Kong, X., Xing, L., Jiang, S., Wang, X., Wang, H., ... & Bornemann, J. (2022). A Slot Antenna Array with Reconfigurable RCS Using Liquid Absorber. IEEE Transactions on Antennas and Propagation.(行业顶刊, 中科院1区)
[3] Liao, K., Liu, S., Zheng, X., Zhang, X., Shao, X., Kong, X., & Hao, Z. (2022). A polarization converter with single‐band linear‐to‐linear and dual‐band linear‐to‐circular based on single‐layer reflective metasurface. International Journal of RF and Microwave Computer‐Aided Engineering, 32(2), e22955.
[4] Kong, L., Kong, X., Jiang, S., Li, Y., Xing, L., & Bian, B. (2022). A Great Wall-Inspired, Water-Based, Switchable Frequency-Selective Rasorber With Polarization Selectivity: Multifunctional, polarization selective, independent working states. IEEE Antennas and Propagation Magazine, 64(5), 30-42. (封面论文,主编编者按评价,入选2022年度十大天线热门文章)
[5] Jin, X., Kong, X., Wang, X., Lin, W., Jiang, S., Wang, H., & Xu, Q. (2022). Band‐notched frequency‐selective absorber with linear polarization rotation function. International Journal of RF and Microwave Computer‐Aided Engineering, e23175.
[6] Liao, K., Liu, S., Shao, X., Zhang, X., Zheng, X., & Kong, X. (2022). An ultra‐wideband dual‐band hybrid frequency‐selective rasorber. International Journal of RF and Microwave Computer‐Aided Engineering, e23197.
[7] Wang, H., Kong, X., & Zhang, X. (2022). A Dual-Polarized Frequency-Selective Rasorber With a Switchable Wide Passband Based on Characteristic Mode Analysis. Frontiers in Materials, 9, 912913.
[8] Yu, Q., Liu, S., Monorchio, A., Kong, X., Brizi, D., Wu, C., & Wen, Y. (2022). A Highly Selective Rasorber With Ultraminiaturized Unit Based on Interdigitated 2.5-D Parallel Resonator. IEEE Transactions on Electromagnetic Compatibility.
[9] Wang, L., Liu, S., Kong, X., Yu, Q., Zhang, X., & Zhang, H. (2022). A Multifunctional Hybrid Frequency-Selective Rasorber With a High-Efficiency Cross-Polarized Passband/Co-Polarized Specular Reflection Band. IEEE Transactions on Antennas and Propagation, 70(9), 8173-8183.(行业顶刊,中科院1区)
[10] Kong, X., Jin, X., Wang, X., Lin, W., Wang, H., Cao, Z., & Gao, S. (2022). Design of Switchable Frequency-Selective Rasorber With ARAT or ATAR Operating Modes. IEEE Antennas and Wireless Propagation Letters.
[11] Kong, X., Wang, X., Jin, X., Lin, W., Kong, L., Jiang, S., & Xing, L. (2022). Liquid Based Wideband and Switchable 3-D Frequency-Selective Rasorber. IEEE Transactions on Electromagnetic Compatibility.
[12] Cheng, E., Wang, X., & Kong, X. (2022). A wideband parallel‐plate waveguide design for FSS/FSR measurement. Microwave and Optical Technology Letters, 64(11), 1906-1910.
[13] Liao, K., Liu, S., Zheng, X., Zhang, X., Shao, X., & Kong, X. (2022). An ultra‐wide passband frequency‐selective rasorber with high transmission. Microwave and Optical Technology Letters, 64(11), 1911-1916.
2021年
[1] Yu, Q., Liu, S., Monorchio, A., Kong, X., Brizi, D., Zhang, X., & Wang, L. (2021). Miniaturized Wide-Angle Rasorber with a Wide Inter-absorption High Transparent Bandpass based on Multiple 2.5-D Resonators. IEEE Antennas and Wireless Propagation Letters.
[2] Kong, X., Lin, W., Wang, X., Xing, L., Jiang, S., Kong, L., & Liu, M. (2021). Liquid reconfigurable stealth window constructed by a metamaterial absorber. JOSA B, 38(11), 3277-3284.
[3] Sun, F., Xing, L., Xu, Q., Kong, X., Wang, H., & Zhang, G. (2021). An Attitude Independent Liquid Dielectric Resonant Antenna. IEEE Antennas and Wireless Propagation Letters.
[4] Kong, X., Kong, L., Jiang, S., Wang, X., Zou, Y., & Xing, L. (2021). Low-Profile and Dual-Polarization Water-Based Frequency Selective Rasorber With Ultrawideband Absorption. IEEE Antennas and Wireless Propagation Letters, 20(12), 2534-2538.
[5] Jiang, S., Kong, X., Kong, L., Jin, X., & Yuan, J. (2021). Switchable Polarization-Insensitive Frequency-Selective Surface Reflector/Absorber With Low Profile by Using Magnetic Material. IEEE Antennas and Wireless Propagation Letters, 20(10), 2078-2082.
[6] Liu, Z., Bornemann, J., Mamedes, D. F., Liu, S., Kong, X., & Zhao, X. (2021). A Wideband Fabry-Pérot Antenna With Enhanced Gain in the High-Frequency Operating Band by Adopting a Truncated Field Correcting Structure. IEEE Transactions on Antennas and Propagation, 69(12), 8221-8228.(行业顶刊,中科院1区)
[7] Yuan, J., Kong, X., Wang, X., Jiang, S., & Kong, L. (2021). Polarization‐independent reconfigurable frequency selective rasorber/absorber with low‐insertion loss. Microwave and Optical Technology Letters, 63(5), 1339-1345.
[8] Wang, X., Kong, X., Jiang, S., Kong, L., & Yuan, J. (2021). Wideband transverse electromagnetic cell design and its application in frequency selective surface measurement. International Journal of RF and Microwave Computer‐Aided Engineering, 31(7), e22690.
[9] 孔祥鲲,孔令奇,姜顺流,胡豪斌,张翔.电磁超材料在超宽带雷达隐身微小卫星设计中的应用.宇航学报,2021,42(06):775-782.
[10] 胡豪斌,张翔,廖文和,孔祥鲲. 卫星隐身技术研究进展及发展趋势. 国防科技大学学报,2021,43(2)(2023年度优秀论文提名,详见 https://mp.weixin.qq.com/s/T8YMrOyTC9Pz5JMCcQAQ5w )
2020年
[1] Yuan, J., Kong, X., Chen, K., Shen, X., Wang, Q., & Wu, C. (2020). Intelligent Radome Design with Multilayer Composites to Realize Asymmetric Transmission of Electromagnetic Waves and Energy Isolation. IEEE Antennas and Wireless Propagation Letters.
[2] Xue, F., Liu, S., & Kong, X. (2020). Single‐layer high‐gain flat lens antenna based on the focusing gradient metasurface. International Journal of RF and Microwave Computer‐Aided Engineering, 30(6), e22183.
[3] Sajjad, M., Kong, X., Liu, S., Ahmed, A., Rahman, S. U., & Wang, Q. (2020). Graphene-based THz tunable ultra-wideband polarization converter. Physics Letters A, 126567.
[4] Yu, Q., Liu, S., Kong, X., Qin, J., Wen, Y., Wang, L., & Xu, Y. (2020). Bandwidth enhancement of a circularly polarized tapered crossed slot antenna with corner parasitic directors. International Journal of RF and Microwave Computer‐Aided Engineering, 30(5), e22173.
[5] Liu, Z., Liu, S., Zhao, X., Kong, X., Huang, Z., & Bian, B. (2020). Wideband Gain Enhancement and RCS Reduction of Fabry-Perot Antenna Using Hybrid Reflection Method. IEEE Transactions on Antennas and Propagation.(行业顶刊,中科院1区)
[6] Liu, Z., Liu, S., Bornemann, J., Zhao, X., Kong, X., Huang, Z., ... & Wang, D. (2020). A Low-RCS, High-GBP Fabry–Perot Antenna With Embedded Chessboard Polarization Conversion Metasurface. IEEE Access, 8, 80183-80194.
[7] Yan, X., Kong, X., Wang, Q., Xing, L., Xue, F., Xu, Y., ... & Liu, X. (2020). Water-based Reconfigurable Frequency Selective Rasorber with Thermally Tunable Absorption Band. IEEE Transactions on Antennas and Propagation. (行业顶刊,中科院1区)
[8] Yuan, S., Kong, X., Yu, Q., & Liu, S. (2020). Miniaturization of frequency‐selective rasorber based on 2.5‐D knitted structure. International Journal of RF and Microwave Computer‐Aided Engineering, 30(2), e22066.
[9] Kong, X., Jiang, S., Kong, L., Wang, Q., Hu, H., Zhang, X., & Zhao, X. (2020). Transparent metamaterial absorber with broadband radar cross-section (RCS) reduction for solar arrays. IET Microwaves, Antennas & Propagation, 14(13), 1580-1586.
[10] Yuan, J., Kong, X., Wang, X., Jiang, S., & Kong, L. (2020). Polarization‐independent reconfigurable frequency selective rasorber/absorber with low‐insertion loss. Microwave and Optical Technology Letters.
[11] Song, H., Zhang, Q., Liu, S., Kong, X., Zhao, X., & Huang, Z. (2020). A six-port path-reconfigurable circulator based on Y-type plasma photonic crystal. Photonics and Nanostructures-Fundamentals and Applications, 41, 100831.
[12] Kong, X., Wang, Q., Jiang, S., Kong, L., Yuan, J., Yan, X., ... & Zhao, X. (2020). A metasurface composed of 3-bit coding linear polarization conversion elements and its application to RCS reduction of patch antenna. Scientific Reports, 10(1), 1-10.
[13] Wu, C., Liu, S., Yu, Q., Kong, X., Yuan, J., & Liao, K. (2020). A low profile miniaturized widely‐spaced triband bandpass FSS using coupled resonance. International Journal of RF and Microwave Computer‐Aided Engineering, 30(11), e22389.
五年前的代表性工作
[1] Kong X, Liu S, Zhang H, et al. A novel tunable filter featuring defect mode of the TE wave from one-dimensional photonic crystals doped by magnetized plasma[J]. Physics of Plasmas, 2010, 17(10): 103506. (等离子体权威学术期刊,被引108次)
[2] Yan, X., Kong, X., Wang, Q., Xing, L., Xue, F., Xu, Y., ... & Liu, X. (2020). Water-based reconfigurable frequency selective rasorber with thermally tunable absorption band. IEEE Transactions on Antennas and Propagation, 68(8), 6162-6171.(行业顶刊,中科院1区,被引89次)
[3] Li, H. M., Liu, S. B., Liu, S. Y., Wang, S. Y., Zhang, H. F., Bian, B. R., & Kong, X. K. (2015). Electromagnetically induced transparency with large delay-bandwidth product induced by magnetic resonance near field coupling to electric resonance. Applied Physics Letters, 106(11), 114101.(中科院物理1区,被引56次)
[4] Wang, L., Liu, S., Kong, X., Zhang, H., Yu, Q., & Wen, Y. (2019). Frequency-selective rasorber with a wide high-transmission passband based on multiple coplanar parallel resonances. IEEE antennas and wireless propagation letters, 19(2), 337340. (中科院2区TOP,被引93次)
[5] Bian, B., Liu, S., Wang, S., Kong, X., Zhang, H., Ma, B., & Yang, H. (2013). Novel triple-band polarization-insensitive wide-angle ultra-thin microwave metamaterial absorber. Journal of Applied Physics, 114(19), 194511.(应用物理权威刊物,被引87次)
成果获奖:
第十八届“挑战杯”全国大学生课外学术科技作品竞赛“揭榜挂帅”专项赛国赛三等奖(2023)
第十九届“挑战杯”全国大学生课外学术科技作品竞赛“人工智能+”专项赛国赛三等奖(2025)
研究生国家奖学金(邹余坤(博士)、姜顺流(硕士)、孔令奇(硕士)、张馨予(硕士))
ACES-China 2021 最佳学生论文奖(张馨予)
IEEE MTT-S IMWS-AMP 2025 Ph.D Travel Grant Award (邹余坤)
IEEE APCAP 2025 优秀学生论文奖(刘沛淇)
江苏省教育科学研究成果奖(2016)
南京市自然科学优秀学术论文奖(2011)
南京航空航天大学教学成果奖(2024)、教学优秀二等奖(2021)
中国国际大学生创新大赛省赛二等奖(2024,2025)(张馨予、朱嘉琦、江晨睿)
中国研究生电子设计大赛华东赛区一等奖、二等奖(2019、2020)(王奇、严祥熙、袁警、孔令奇、李元鑫)
2021第五届磁性材料与器件大会 研究生学术新锐奖 (姜顺流)
南京航空航天大学苏州工业园区特别奖学金(王奇、袁警、曹祖威)
授权专利:
专利转化:
(1)发明专利,基于电磁诱导透明的可重构射频识别标签(授权公告号CN104408506B)发明人:孔祥鲲 刘少斌 丁国文 陈琳 刘思源
发明专利:
(1)发明专利,一种中频宽频带透波、高频和低频极化转换的隐身天线罩(授权公告号CN110265780B)发明人:王玲玲 刘少斌 孔祥鲲
(2)发明专利,吸透可重构实现电磁波非对称传输和能量隔离的天线罩(授权公告号CN111725626B)发明人:袁警;孔祥鲲
(3)发明专利,一种基于水的极化可重构多功能频率选择吸波体(授权公告号CN112117545B)发明人:孔令奇; 孔祥鲲; 姜顺流; 李元鑫
(4)发明专利,一种角度不敏感的可共形宽带反射型线极化转换器(授权公告号CN109378591B)发明人:孔祥鲲;王奇;严祥熙
(5)发明专利,一种基于液体的低散射可重构缝隙天线(授权公告号CN113629410B)发明人:孔祥鲲;邹余坤
实用新型专利:(略)
承担的科研项目情况:
国家自然科学基金面上项目(62071227) 结题
Chinese Natural Science Foundation (Grant No. 62071227)
江苏省自然科学基金面上项目(BK20201289) 结题
Natural Science Foundation of Jiangsu Province of China (BK20201289)
科技部外专局“高端外国专家引进计划”项目(011951G2309)结题
装备预研共用技术和领域基金(61402090103),(南京理工大学、南京航空航天大学联合申报)结题
海军装备预研项目(30203)结题
中国国防基础科学研究计划项目(JCKY2021DC05)结题
National Defense Basic Scientific Research Program of China under Grant JCKYS2021DC05
航空基金(20220018052002(在研),20161852016优秀结题)
火箭军工程预研项目(在研)
中国兵工集团装备委托项目(在研)
直升机动力学全国重点实验室开放基金 (结题);
毫米波国家重点实验室开放课题(K202323在研;K202027结题;K201609结题)
Open Research Program in China's State Key Laboratory of Millimeter Waves (Grant No.K2020127)
中国博士后面上项目(2016M601802) (结题)
China Postdoctoral Science Foundation (Grant No. 2016M601802)
江苏省博士后面上项目(1601009B) (结题)
Jiangsu Planned Projects for Postdoctoral Research Funds (Grant No. 1601009B)
南京航空航天大学科研远景布局基金 (结题)
The Fund of Prospective Layout of Scientific Research for NUAA
军事科学院电磁防护工程项目 (结题)
华为技术有限公司横向课题 (结题)
中航工业611所飞行器天线罩设计项目 (结题)
南京华成微波技术有限公司天线设计项目 (结题)
镇江航空航天产业科技园委托项目(在研)
指导研究生情况(全员登记):
目前指导在读硕士9名,参与协同指导2名博士生。毕业硕士10人,毕业博士1人(留学生)。
2017级
王奇(中国研究生电子设计大赛华东赛区一等奖,队长,苏州工业园区奖学金获得者;南京航空航天大学研究生创新基金优秀结题,校优秀毕业研究生。毕业去向:中电55所(南京));
严祥熙(中国研究生电子设计大赛华东赛区一等奖;发表电信学顶刊论文;校优秀硕士论文;校优秀毕业研究生。毕业去向:紫金山实验室(南京))
2018级
袁警(中国研究生电子设计大赛华东赛区一等奖,苏州工业园区奖学金获得者;获南京航空航天大学研究生创新基金;校优秀硕士论文;校优秀毕业研究生。毕业去向:中兴南京研究院)
2019级
孔令奇(中国研究生电子设计大赛华东赛区二等奖,队长;国家奖学金获得者;获南京航空航天大学研究生创新基金。毕业去向:英国利物浦大学全奖攻博,师从IEEE Fellow);
姜顺流(第五届全国磁性材料与器件大会“研究生学术新锐奖”,国家奖学金获得者; 获江苏省研究生研究与实践创新项目。毕业去向:中航工业607研究所(无锡))
Mohammed Sajjad (巴基斯坦籍博士研究生, 毕业去向:华南理工大学博士后)
2020级
王雪孟(获南京航空航天大学研究生创新基金;毕业去向:中电13所(石家庄))
林伟豪(获江苏省研究生研究与实践创新项目;毕业去向:深圳市振华微电子有限公司)
金鑫 ( 发表AWPL行业2区论文;毕业去向:中电55所(南京))
2021级
邹余坤(南航“英才计划”直博生,大四阶段发表电信学顶刊论文;国家奖学金获得者;IEEE MTT-S IMWS-AMP2025 Ph.D. Travel Grant Award;南京航空航天大学-意大利比萨大学联合培养博士)
曹祖威(获南京航空航天大学研究生创新基金,发表AWPL行业2区论文;18届全国“挑战杯-揭榜挂帅”专项赛三等奖,苏州工业园区奖学金获得者;毕业去向:荣耀终端有限公司(深圳))
王贺(获江苏省研究生研究与实践创新项目;毕业去向:中电13所(石家庄))
2022级
张馨予(南航“英才计划”本硕连读,十八届全国“挑战杯-揭榜挂帅”专项赛三等奖,全国大学生物联网技术与应用“三创”大赛一等奖、ACES-China 最佳学生论文奖提名, 国家奖学金获得者;获南京航空航天大学研究生创新实验竞赛培养项目;毕业去向:苏州汰砾微波技术公司)
周少春 (十八届全国“挑战杯-揭榜挂帅”专项赛三等奖;校优秀毕业研究生; 毕业去向:杭州长川科技股份有限公司(A股上市))
程健来 (承担的工程研究项目被中国兵器研究所采用;校优秀毕业研究生; 毕业去向:航天三院35所(北京))
聂士涛(“校企联合培养计划”;毕业去向:凯迈(洛阳)测控有限公司(航空工业中国空空导弹研究院控股,专精特新小巨人企业))
2023级
王霄鹏 (南航“英才计划”直博生,十八届全国“挑战杯-揭榜挂帅”专项赛三等奖, 队长)
刘沛淇 (南航硕博连读,获南京航空航天大学研究生创新基金;IEEE APCAP2025 Student Paper Award)
余 冬 (“校企联合培养计划”;毕业去向:南京埃斯顿自动化股份有限公司(A股上市))
2024级
侯喆芃(南航“英才计划”本硕博贯通计划)
2025级
朱嘉琦(十九届全国“挑战杯”人工智能+专项赛国赛三等奖, 队长;中国国际大学生创新大赛省赛二等奖,校内选拔赛一等奖 )
江晨睿(中国国际大学生创新大赛省赛二等奖,校内选拔赛一等奖 )
董羽丰(十九届全国“挑战杯”人工智能+专项赛国赛三等奖)
备注:
导师标签:“唯物主义者”、"科学、自由、平等、健康"、“洋务派”、“学院派”、“师范生”、“懂心理”、“热爱教育事业”、“强调理论联系实际”、“接地气”、“百科杂书”、“闲暇时有小资情调”、“文人气”、“体育盲”、“重理工、鄙视商业炒作”、“憎恶动嘴不动手”......
欢迎品学兼优,有实干精神,阳光有活力,能静下心来钻研学问的同学报考。专业不限于电子科学与技术,物理类,电子类,材料类均欢迎报考。
办公室地址:学院办公楼110,办公电话:025-84896491-4110,邮箱:xkkong@nuaa.edu.cn
[1]可重构智能超表面通信系统
[2]雷达目标散射特性分析
[3]电磁兼容与防护评估
[4]雷达天线罩设计与应用
[5]射频集成电路设计与测试
[6]人工电磁智能结构及天线设计;
南航EMUlab实验室依托电子信息工程学院雷达成像与微波光子技术教育部重点实验室,面向电磁场与微波技术国际前沿与航空航天工程需求,围绕微波与无线器件技术、射频集成电路、天线和电磁波无线传播及电磁兼容技术展开研究,同时与学校三航特色相结合,与航空航天专业融合形成电磁隐身交叉专业、与材料学、化学、人工智能专业融合形成智能结构交叉学科。实验室导师继承南航人的“红色基因,蓝色梦想”,秉承“经纬天地、 慧通时空” 院训, 传承“航空报国” 精神, 坚持立德树人根本任务, 扎根教育科研一线,形成了团结奋进、良师益友的导学关系,奋勇争先。
