2023年论文
1.Hao Chen, Weibing Lu, Mingyang Geng, Buyun Yu, Chao Zhang, Xinzhi Bo, Mengzi Li, Zhenhao Kou, Junlin Zhan, Zhenguo Liu. Fabric‐Based Smart Metasurface, Advanced Materials Technologies, 2301111.
原文直达:Fabric‐Based Smart Metasurface (wiley.com)
2.Zhipeng Chen, Zhenguo Liu, Shang Zhang, Mengzi Li, Weibing Lu. An Enhanced-Sensitivity Tangential Electric Field Probe with Tunable Resonant Frequency, IEEE Transactions on Instrumentation and Measurement, 2023, 72:8003212.
3.Zhenguo Liu, Mingyang Geng, Hao Chen, Anqi Zhang, Weibing Lu. A Perspective on the Recent Progress of Graphene in Microwave Applications: Problems, Challenges and Opportunities, IEEE Microwave Magazine 24 (6), 40-53.
4.Hao Chen, Mingyang Geng, Zhaomin Chen, Jiayi Chen, Junlin Zhan, Buyun Yu, Lu Ju, Cong Ding, Yingshi Guan, Zhenguo Liu, Weibing Lu, Quan Li. Digitally Controlled Tunable Fabric Microwave Filter Based on Organic Electrochemical Transistors, Advanced Materials Technologies, 2023: 2300428.
5.Xiaoli Peng, Xiangyu Meng, Buyun Yu, Hao Chen, Zhenguo Liu , Mingyu Tang , Yiqun Zheng, Yueming Sun, Weibing Lu, Yunqian Dai. Graphitized and flexible porous textile updated from waste cotton for wearable electromagnetic interference shielding, Carbon, 2023, 207:144–153.
6.Xingce Fan, Xiaohu Zhang, Ya Li, Hongjun He, Qixing Wang, Leilei Lan, Wenzhe Song, Teng Qiu, Weibing Lu. Flexible two-dimensional MXene-based antennas, Nanoscale Horizons 8 (3), 309-319.
原文直达:Flexible two-dimensional MXene-based antennas - Nanoscale Horizons (RSC Publishing)
7.Mingyang Geng, Xiaolu Yang, Hao Chen, Xinzhi Bo, Mengzi Li, Zhenguo Liu, Weibing Lu. Optically transparent graphene-based cognitive metasurface for adaptive frequency manipulation, Photonics Research 11 (1), 129-136.
2022年论文
1.H. Chen,Z.G. Liu, et al. A Study on the Dynamic Tunning Range of CVD Graphene at Microwave Frequency: Determination, Prediction and Application. Nanomaterials, 2022,12,4424-4438.
2.M. Y. Geng, Z.G. Liu, H.Chen, X.Z. Bo, X.L. Yang, and W.B.Lu, Flexible and Dual-Tunable Radar Absorber Enabled by Graphene, Advanced Materials Technologies, 2022, 7, 2200028.
3.H. Chen, X.L. Peng, X.Z. Bo, M.Y. Geng, X.L. Yang, J.L. Zhan, Z.G. Liu, Y.Q. Dai, and W.B.Lu, All-Fabric Flexible Frequency-Selective Rasorber Based on Cutting Transfer Patterning Method, Advanced Materials Interfaces, 2022, 9, 2200651.
4.Z.G. Liu, R.J. Yin, W.B. Lu, A Novel Dual-Band Shared-Aperture Antenna Based on Folded Reflectarray and Fabry–Perot Cavity, IEEE Trans on Antenna and Propag. vol.70, no.11, 2022, pp.11177-11182.
5.Z. G. Liu, C. Zhang, R.J. Yin, W.B. Lu, Multifunctional Low-Profile Fabry-Perot Resonator Antenna Integrated with Solar Cells, IEEE Trans on Antenna and Propag., vol.70, no.8, 2022, pp.7175-7180.
6.Z. P. Chen, Z. G. Liu, L. Ju, W. B. Lu, Beam Scanning Conformal Antenna Array with Planar Integrated Phase Shifter Based on Graphene, Journal of Materials Science: Materials in Electronics, vol. 33, no. 17, pp. 14032-14042, May. 2022.
7. L. Ju, Z. G. Liu, B. Y. Yu, H. Chen, Z. D. Xiao, and W. B. Lu, Stretchable and Dynamically Tunable Attenuator Based on Graphene, IEEE Transactions on Microwave Theory and Techniques, vol. 70, no. 6, pp. 2999-3008, Apr. 2022.
8.B. Y. Yu, Z. H. Wang, L. Ju, C. Zhang, Z. G. Liu, L. Tao, and W. B. Lu, Flexible and Wearable Hybrid RF and Solar Energy Harvesting System, IEEE Transactions on Antennas and Propagation, vol. 70, no. 3, pp. 2223-2233, Mar. 2022.
9.R. Weng, et al. Efficient Broadband Monostatic RCS Computation of Morphing S-shape Cavity Using Artificial Neural Networks. IEEE Antennas and Wireless Propagation Letters, Early Access.
10.W. Xiang, et al. Fast Prediction of Quasi-Periodic Array Using Dynamical Graph Convolutional Neural Networks. IEEE Antennas and Wireless Propagation Letters, vol.21, no.5, 2022, pp.893-897.
11.W. Xiang, et al. Rapid Subentire-Domain Basis Functions Method Based on Adaptive Artificial Neural Networks. IEEE Trans on Antenna and Propag., vol.70, no.7, pp.5156-5164.
12.W. Xiang, W. Yang, W.B. Lu. Fast Sub-Entire-Domain Basis Functions Method for Analysis of Composite Finite Periodic Structures with Dielectric-Conductor Cells, IEEE Antennas and Wireless Propagation Letters, 2022, 1-5.
发明授权专利
1. 陆卫兵;张安琪;刘震国,一种基于石墨烯的基片集成波导动态可调衰减器(已转让),授权日:2022.03.08
2. 刘震国;陈志鹏;陆卫兵,基于石墨烯的波束可扫描印刷偶极子柔性天线,授权日:2022.04.22
3. 陆卫兵;刘震国;耿明扬;陈昊,Ku波段的高透明柔性动态调频吸波表面结构及其制备方法(已转让),授权日:2022.07.05
4. 刘震国;张超;陆卫兵,基于太阳能电池的低剖面高增益谐振天线,授权日:2022.07.26
5.刘震国;应振楠;陆卫兵,圆极化高增益谐振天线作为馈源的多波束反射面天线,授权日:2022.09.23
6.相伟;陆卫兵;杨武,基于子全域基函数方法的大规模准周期结构电磁散射特性分析方法(已转让),授权日:2022.11.08
7.杨武;陆卫兵;李思,一种目标特性数据库可视分析系统,授权日:2023.08.01
8.陆卫兵;陈昊;刘震国,一种基于波导法的二维材料阻抗特性测试方法,授权日:2023.08.18
9. 陆卫兵;张安琪;刘震国,基于石墨烯的半模基片集成波导动态可调衰减器,授权日:2023.10.13
10.陆卫兵;王健;刘震国,制作在玻璃表盘上的缝隙耦合平面四臂螺旋圆极化天线,授权日:2023.12.22
专著
1. 陆卫兵;黄保虎,吴边,刘震国,陈昊;《石墨烯电磁特性与应用》,电子工业出版社