Wideband diffusion metabsorber for perfect scattering field reduction 被引量：3

导出

摘要 Both absorption and diffuse reflection can effectively suppress microwave backward reflection.However,the challenge of designing wideband absorptive elements with anti-phase reflection hinders the simultaneous working of the two principles.With aid of the wideband characteristic of bilateral complementary structure,we propose a strategy to design wideband absorptive elements with large reflection phase differences.For proof of concept,the proposed elements are arranged in a rectangular grid by optimizing scattering field distribution.The proposed diffusion metabsorber achieves over 20-dB scattering field reduction in the range of 8.5–20.3 GHz with good polarization stability and high angular insensitivity of up to±40°,which has been verified by real experiments.Furthermore,the proposed design strategy exhibits the potential to further reduce electromagnetic wave reflection,and the optical transparent characteristic is promising for window applications.

作者 ZICHENG SONG PINGPING MIN JIAQI ZHU LEI YANG FENG HAN LIN

机构地区 Center for Composite Materials and Structures School of Information Science and Technology Research Center of Analysis and Measurement

出处《Photonics Research》 SCIE EI CAS CSCD 2022年第6期1361-1366,共6页 光子学研究（英文版）

基金 Key Project of National Natural Science Foundation of China(52032004) National Natural Science Foundation for Distinguished Young Scholars of China(51625201) Shanghai Pujiang Program(20PJ1411400)。

关键词 SCATTERING DIFFUSION PERFECT

分类号 TN929.5 [电子电信—通信与信息系统] TN03 [电子电信—物理电子学]

引文网络
相关文献

参考文献4

1Tie-Jun Cui,Shuo Liu,Lian-Lin Li.Information entropy of coding metasurface[J].Light(Science & Applications),2016,5(1):403-414. 被引量：32
2CHENG ZHANG,JIN YANG,WENKANG CAO,WEI YUAN,JUNCHEN KE,LIUXI YANG,QIANG CHENG,TIEJUN CUI.Transparently curved metamaterial with broadband millimeter wave absorption[J].Photonics Research,2019,7(4):478-485. 被引量：11
3YAN CHEN,KEJIAN CHEN,DAJUN ZHANG,SHIHAO LI,YELI XU,XIONG WANG,SONGLIN ZHUANG.Ultrabroadband microwave absorber based on 3D water microchannels[J].Photonics Research,2021,9(7):1391-1396. 被引量：3
4Alexander Lerchl.Electromagnetic pollution： another risk factor for nfertility, or a red herring？[J].Asian Journal of Andrology,2013,15(2):201-203. 被引量：5

二级参考文献24

1Repacholi MH, Lerchl A, Roosli M, Sienkiewicz Z, Auvinen A et aL Systematic review of wireless phone use and brain cancer and other head tumors. BioelectromaEnetics 2012; 33: 187-206.
2Feychting M. Mobile phones, radiofrequency fields, and health effects in children:epidemiological studies. ProE Biophys Mol Bio12011; 107: 343-8.
3La Vignera S, Condorelli RA, Vicari E, D'Agata R, Calogero AE. Effects of the exposure to mobile phones on male reproduction: a review of the literature. JAndro12012; 33: 350-6.
4International Commission on Non-Ionizing Radiation Protection. Guidelines for limiting exposure to time- varying electric, magnetic and electromagnetic fields (up to 300 GHz). Heatlh Phys 1998; 74: 494-522.
5Tahvanainen K, Nino J, Halonen P, Kuusela T, Alanko T et al, Effects of cellular phone use on ear canal temperature measured by NTC thermistors. Clin Physiol Funct ImaginE2007; 27: 162-72.
6van Leeuwen GM, Lagendijk J J, van Leersum B J, Zwamborn AP, Hornsleth SN et al. Calculation of change in brain temperatures due to exposure to a mobile phone. Phys Med Bio11999; 44: 2367-79.
7Baan R, Grosse Y, Lauby-Secretan B, El Ghissassi F, Bouvard Vet al. Carcinogenicity of radiofrequency electromagnetic fields. Lancet Oncol 2011; 12: 624-6.
8INTERPHONE Study Group. Brain tumour risk in relation to mobile telephone use: results of the INTERPHONE international case-control study. IntJ Epidemio12010; 39: 675-94.
9Saracci R, Samet J. Commentary: call me on my mobile phone:.or better not?:a look at the INTERPHONE study results. Int J Epidemio12010; 39: 695-8.
10Swerdlow A J, Feychting M, Green AC, Leeka Kheifets LK, Savitz DA eta/. Mobile phones, brain tumors, and the interphone study: where are we now? Environ Health Perspect 2011; 119: 1534-8.

共引文献45

1武攀峰,陆炜,姚颖,王国旗,黄昕.城市射频公众曝露区域监测最优网格尺度研究[J].中国测试,2017,43(8):24-27.
2武攀峰,王国旗,陆炜,姚颖,王悦,黄昕.基于车载移动的区域射频电磁辐射监测方法比较研究[J].辐射防护,2017,37(5):374-379. 被引量：8
3武攀峰,王国旗,陆炜,姚颖,黄昕.基于车载监测法的Ⅱ型大城市射频公众曝露探讨[J].环境监测管理与技术,2017,29(5):60-63. 被引量：4
4吴为,缪明,陆炜,黄昕.经济发达地区乡村环境射频辐射公众曝露研究[J].资源节约与环保,2020,35(7):155-156.
5崔铁军.电磁超材料——从等效媒质到现场可编程系统[J].中国科学：信息科学,2020,50(10):1427-1461. 被引量：24
6崔铁军院士[J].中国科学：信息科学,2020,50(10):1588-1589.
7唐小燕,柯友煌,井绪峰,别寻,李晨霞,洪治.基于透射型几何相位编码超表面的太赫兹波束自由操控[J].光子学报,2021,50(1):142-155. 被引量：8
8李廉林,崔铁军.智能电磁感知的若干进展[J].雷达学报（中英文）,2021,10(2):183-190. 被引量：6
9杨欢欢,曹祥玉,高军,李桐,李思佳,丛丽丽,赵霞.可重构电磁超表面及其应用研究进展[J].雷达学报（中英文）,2021,10(2):206-219. 被引量：11
10贾宇翔,王甲富,陈维,随赛,朱瑞超,邱天硕,李勇峰,韩亚娟,屈绍波.基于智能算法的超材料快速优化设计方法研究进展[J].雷达学报（中英文）,2021,10(2):220-239. 被引量：6

同被引文献9

1SHICHAO SONG,XIAOLIANG MA,MINGBO PU,XIONG LI,YINGHUI GUO,PING GAO,XIANGANG LUO.Tailoring active color rendering and multiband photodetection in a vanadium-dioxide-based metamaterial absorber[J].Photonics Research,2018,6(6):492-497. 被引量：5
2CHENG ZHANG,JIN YANG,WENKANG CAO,WEI YUAN,JUNCHEN KE,LIUXI YANG,QIANG CHENG,TIEJUN CUI.Transparently curved metamaterial with broadband millimeter wave absorption[J].Photonics Research,2019,7(4):478-485. 被引量：11
3杨波,赵培林,蔡三军,周生林,陈川.新一代战斗机座舱盖关键技术与设计方案[J].航空学报,2020,41(6):300-310. 被引量：9
4RUICHAO ZHU,JIAFU WANG,JINMING JIANG,CUILIAN XU,CHE LIU,YUXIANG JIA,SAI SUI,ZHONGTAO ZHANG,TONGHAO LIU,ZUNTIAN CHU,JUN WANG,TIE JUN CUI,SHAOBO QU.Machine-learning-empowered multispectral metafilm with reduced radar cross section,low infrared emissivity,and visible transparency[J].Photonics Research,2022,10(5):1146-1156. 被引量：4
5KUN GAO,XIANGYU CAO,JUN GAO,TONG LI,HUANHUAN YANG,SIJIA LI.Ultrawideband metamaterial absorber for oblique incidence using characteristic mode analysis[J].Photonics Research,2022,10(12):2751-2759. 被引量：1
6MINGYANG GENG,XIAOLU YANG,HAO CHEN,XINZHI BO,MENGZI LI,ZHENGUO LIU,WEIBING LU.Optically transparent graphene-based cognitive metasurface for adaptive frequency manipulation[J].Photonics Research,2023,11(1):129-136. 被引量：2
7高冕,陈强,郑月军,袁方,孙占山,付云起.Design of an optically-transparent ultra-broadband microwave absorber[J].Chinese Physics B,2023,32(8):289-295. 被引量：1
8PINGPING MIN,ZICHENG SONG,TIANYU WANG,VICTOR GRALCHENKO,YURONG HE,JIAQI ZHU.Design strategy of a high-performance multispectral stealth material based on the 3D meta-atom[J].Photonics Research,2023,11(11):1934-1944. 被引量：1
9Zhengang Lu,Yilei Zhang,Heyan Wang,Chao Xia,Yunfei Liu,Shuliang Dou,Yao Li,Jiubin Tan.Transparent Thermally Tunable Microwave Absorber Prototype Based on Patterned VO2 Film[J].Engineering,2023(10):198-206. 被引量：1

引证文献3

1PINGPING MIN,ZICHENG SONG,TIANYU WANG,VICTOR GRALCHENKO,YURONG HE,JIAQI ZHU.Design strategy of a high-performance multispectral stealth material based on the 3D meta-atom[J].Photonics Research,2023,11(11):1934-1944. 被引量：1
2宋梓诚,闵萍萍,张锐聪,贺乔柏,杨磊,王天宇,韩杰才,朱嘉琦.超构透明吸波体的研究前沿与展望[J].中国科学：技术科学,2024,54(6):1021-1035.
3高佳璠,朱昳慧,林丰涵.超构表面的特征模式分析及其在天线中的应用[J].无线电工程,2024,54(9):2074-2081.

二级引证文献1

1宋梓诚,闵萍萍,张锐聪,贺乔柏,杨磊,王天宇,韩杰才,朱嘉琦.超构透明吸波体的研究前沿与展望[J].中国科学：技术科学,2024,54(6):1021-1035.

1储刚,吴静,范华风,付丽婷,贾雅薇,张静,孟竺.掺杂铒改性铝酸镧的制备及荧光性研究[J].光电子．激光,2021,32(11):1235-1240.
2Zhichao Lou,Qiuyi Wang,Xiaodi Zhou,Ufuoma I.Kara,Rajdeep S.Mamtani,Hualiang Lv,Meng Zhang,Zhihong Yang,Yanjun Li,Chenxuan Wang,Solomon Adera,Xiaoguang Wang.An angle-insensitive electromagnetic absorber enabling a wideband absorption[J].Journal of Materials Science & Technology,2022(18):33-39. 被引量：3
3李天宇,周子力,赵晓函,陈丹华,王凯莉.TransP:一种基于WordNet中PartOf关系的知识图谱嵌入方法[J].计算机应用与软件,2022,39(5):241-246.
4Jian-Gong Cui,Ya-Xin Yu,Xiao-Xia Chu,Rong-Yu Zhao,Min Zhu,Fan Meng,Wen-Dong Zhang.Refocusing and locating effect of fluorescence scattering field[J].Chinese Physics B,2021,30(12):459-466.
5ZHOU ZHENG,ZHENGYING LI,XUELEI FU,XIN GUI.Coherent-detection-based distributed acoustic impedance sensing enabled by a chirped fiber Bragg grating array[J].Photonics Research,2022,10(6):1325-1331.
6Jilong Huang,Yongping Liu,Peng Yan,Jie Gao,Yuchi Fan,Wan Jiang.Mechanically exfoliated MoS_(2) nanoflakes for optimizing the thermoelectric performance of SrTiO_(3)-based ceramic composites[J].Journal of Materiomics,2022,8(4):790-798.
7Juhua Luo,Mengna Feng,Ziyang Dai,Chenye Jiang,Wei Yao,Naixin Zhai.MoS_(2) wrapped MOF-derived N-doped carbon nanocomposite with wideband electromagnetic wave absorption[J].Nano Research,2022,15(7):5781-5789. 被引量：12
8Chen Li,Xiaosi Qi,Xiu Gong,Qiong Peng,Yanli Chen,Ren Xie,Wei Zhong.Magnetic-dielectric synergy and interfacial engineering to design yolk-shell structured CoNi@void@C and CoNi@void@C@MoS_(2) nanocomposites with tunable and strong wideband microwave absorption[J].Nano Research,2022,15(7):6761-6771. 被引量：13
9Xiaobao Xu,Yuhang Dong,Yuanzhou Zhang,Zeyao Han,Jiaxin Liu,Dejian Yu,Yi Wei,Yousheng Zou,Bo Huang,Jun Chen,Haibo Zeng.High-definition colorful perovskite narrowband photodetector array enabled by laser-direct-writing[J].Nano Research,2022,15(6):5476-5482. 被引量：4
10Chi Zhang,Wei Xie,Chunguang Li,Jinhao Dai,Yuefeng Yuan,Runbo Jiang,Xu Wang,Jia Wang,Yun Wu,Liang Sun,Yusheng He.Recent progress on high-temperature superconducting filters[J].Superconductivity,2022(2):28-38. 被引量：1

Photonics Research

2022年第6期

浏览历史

内容加载中请稍等...