Terahertz Metamaterial Sensor Based on Electromagnetically Induced Transparency Effect 被引量：2

Terahertz Metamaterial Sensor Based on Electromagnetically Induced Transparency Effect

下载PDF

导出

摘要 A terahertz metamaterial sensor adopting the metamaterial-based electromagnetically induced transparency（EIT） effect is presented for determining the 1,4-dioxane concentration in its aqueous solution. The metamaterial sensor, which consists of an EIT element unit with a cut-wire metallic resonator and two split-ring metallic resonators fabricated on a 490-μm thick silicon substrate, operates in a transmission geometry. The EIT peak was red-shifted and decreased with the increase of the water volume. A maximum redshift about 54 GHz of the EIT peak was detected between the 1,4-dioxane and water. The presented linear behavior and high sensitivity of the EIT peak depending on the water concentration pave a novel avenue for sensor applications. A terahertz metamaterial sensor adopting the metamaterial-based electromagnetically induced transparency（EIT） effect is presented for determining the 1,4-dioxane concentration in its aqueous solution. The metamaterial sensor, which consists of an EIT element unit with a cut-wire metallic resonator and two split-ring metallic resonators fabricated on a 490-μm thick silicon substrate, operates in a transmission geometry. The EIT peak was red-shifted and decreased with the increase of the water volume. A maximum redshift about 54 GHz of the EIT peak was detected between the 1,4-dioxane and water. The presented linear behavior and high sensitivity of the EIT peak depending on the water concentration pave a novel avenue for sensor applications.

作者 Shao-Xian Li Hong-Wei Zhao Jia-Guang Han

机构地区 Center for Terahertz wave Key Laboratory of Interfacial Physics and Technology

出处《Journal of Electronic Science and Technology》 CAS CSCD 2015年第2期117-121,共5页 电子科技学刊（英文版）

基金 supported by the National Basic Research Program of China under Grant No.2014CB339800

关键词 metallic terahertz resonator transparency determining fabrication split shifted aligned lithography metallic terahertz resonator transparency determining fabrication split shifted aligned lithography

分类号 TP212 [自动化与计算机技术—检测技术与自动化装置]

引文网络
相关文献

参考文献29

1K. Fan and W. J. Padilla, “Dynamic electromagnetic metamaterials,” Materials Today, vol. 18, no. 1, pp. 39-50,2015.
2K. Yao and Y.-M. Liu, “Plasmonic metamaterials,” Nanotechnology Reviews, vol. 3, no. 2, pp. 177-210, 2014.
3N. Meinzer, W. L. Barnes, and I. R. Hooper, “Plasmonic meta-atoms and metasurfaces,” Nature Photonics, vol. 8, no. 12, pp. 889-898, 2014.
4N. I. Zheludev and Y. S. Kivshar, “From metamaterials to metadevices,” Nature Materials, vol. 11, no. 11, pp. 917-924, 2012.
5Z.-H. Zhu, X.-Q. Zhang, J.-Q. Gu, R. Singh, Z. Tian, J.-G. Han, et al., “A metamaterial-based terahertz low-pass filter with low insertion loss and sharp rejection,” IEEE Trans. Terahertz Science and Technology, vol. 3, no. 6, pp. 832-837, 2013.
6Q. Li, X.-Q. Zhang, W. Cao, A. Lakhtakia, J. F. O'Hara, J.-G. Han, et al“An approach for mechanically tunable, dynamic terahertz bandstop filters,” Applied Physics, vol. 107, no. 2, pp. 285-291, 2012.
7Y.-M. Yang, R. Huang, L.-Q. Cong, Z.-H. Zhu, J.-Q. Gu, Z. Tian, et al., “Modulating the fundamental inductive-capacitive resonance in asymmetric double-split ring terahertz metamaterials,” Applied Physics Letters, vol. 98, no. 12, pp. 121114, 2011.
8Q. Li, Z. Tian, X.-Q. Zhang, N.-N. Xu, R. Singh, J.-Q. Gu, et al., “Dual control of active graphene-silicon hybrid metamaterial devices,” Carbon, vol. 90, pp. 146-153, Aug.2015.
9L.-X. Liu, X.-Q. Zhang, M. Kenney, X.-Q. Su, N.-N. Xu, C.-M. Ouyang, et al., “Broadband metasurfaces with simultaneous control of phase and amplitude,” Advanced Materials, vol. 26, no. 29, pp. 5031-5036, 2014.
10X.-Q. Zhang, Z. Tian, W.-S. Yue, J.-Q. Gu, S. Zhang, J.-G. Han, et al., “Broadband terahertz wave deflection based on c-shape complex metamaterials with phase discontinuities,” Advanced Materials, vol. 25, no. 33, pp. 4567-4572,2013.

同被引文献10

1李化月,刘建军,韩张华,洪治.基于类电磁诱导透明效应的太赫兹折射率传感器[J].光学学报,2014,34(2):230-234. 被引量：18
2李广森,延凤平,王伟,乔楠.基于三维耦合的多波段宽带电磁诱导透明分析[J].激光与光电子学进展,2018,55(12):423-430. 被引量：4
3孙雅茹,史同璐,刘建军,洪治.太赫兹超材料类EIT谐振无标记生物传感[J].光学学报,2016,36(3):261-266. 被引量：23
4潘武,余璇,张俊,曾威.基于双开口方形薄片的太赫兹超材料吸收器吸收特性分析[J].应用激光,2016,36(3):346-350. 被引量：6
5马长伟,马文英,谭毅,唐雨竹.高Q值THz类EIT超材料及传感特性研究[J].光电工程,2018,45(11):83-90. 被引量：6
6张彩虹,吴敬波,金飚兵.太赫兹超导人工电磁超材料的研究进展[J].中国激光,2019,46(6):42-49. 被引量：5
7张赟佳,王少飞,钟高超,韩森,王培,银珊.微流控-超材料集成多带太赫兹传感器[J].中国激光,2019,46(6):329-335. 被引量：6
8毛前军,冯春早.基于磁激元的嵌套环超材料吸波器的吸收特性[J].光学学报,2019,39(8):247-254. 被引量：8
9李达民,袁苏,杨荣草,田晋平,张文梅.动态光调控多态太赫兹超材料吸收器[J].光学学报,2020,40(8):99-106. 被引量：23
10王娅茹,梁兰菊,杨茂生,王旭娟,王岩.一种光控的电磁诱导透明太赫兹超材料[J].激光与光电子学进展,2019,56(4):202-208. 被引量：10

引证文献2

1姚仲敏,赵昕,朱磊,董亮,李泰成,吴天昊,付壮壮.基于全介质超材料的光频段电磁感应透明效应[J].应用激光,2018,38(4):672-677. 被引量：1
2张敏,延凤平,杜雪梅,仉晓琦.太赫兹多波段的电磁诱导透明设计与分析[J].中国激光,2021,48(3):164-172. 被引量：9

二级引证文献10

1董亮,李泰成,朱磊,秦月,吴群.基于全介质超材料的电磁感应透明开关实验研究[J].电子元件与材料,2020,39(9):45-49. 被引量：2
2王子煜,邵健,胡亚新,朱佳璐,张晓蕊,白磊,董正高.基于全介质超材料的高Q电磁诱导透明现象研究[J].光学学报,2021,41(11):132-138. 被引量：6
3谷建强,王可蒙,许祎,欧阳春梅,田震,韩家广,张伟力.基于超材料的太赫兹光电导天线[J].中国激光,2021,48(19):168-188. 被引量：9
4吴经纬,牛力,王庆伟,张学迁,栗岩锋,韩家广.太赫兹平行平板波导中等离子诱导透明效应的调控[J].中国激光,2021,48(19):189-198. 被引量：2
5刘姗姗,李泉,杨子榆,路光达,王爽.基于石墨烯-金属复合超材料结构的电磁诱导透明非线性调制[J].中国激光,2021,48(19):297-305. 被引量：5
6于新颖,闫俊伢,杨森,张婷.T形结构太赫兹超材料吸收器的设计与仿真[J].激光与光电子学进展,2021,58(21):257-264. 被引量：2
7于新颖,杨森,樊东燕.可调谐极化不敏感太赫兹吸收器的设计[J].激光与光电子学进展,2022,59(3):218-224. 被引量：1
8杨成福,徐兴贵,陈俊歌,陈娟.基于面积映射方法的多波束透镜天线设计[J].激光与光电子学进展,2022,59(3):271-278.
9Huang Yue,Xu Hang,Xu Jinqiang,Feng Liwen,Wang Tianyi,Wang Lina,Liu Zhongqi,Huang Senlin,Liu Kexin.A Compact and Robust Regenerative Amplifier Pump Source for High Repetition Rate Terahertz Parametric Amplifier[J].激光与光电子学进展,2022,59(21):262-266.
10周凤麒,王嘉伟,刘志敏,张箫,刘婷,孙丽文.石墨烯超材料等离诱导透明特性和光电开关设计[J].光学学报,2023,43(2):150-157.

1王潇潇,孙家翔,孙远航,李爱军,陈怡,张晓军,康智慧,王磊,王海华,高锦岳.Image information transfer via electromagnetically induced transparency-based slow light[J].Chinese Physics B,2015,24(7):252-255.
2Metamaterial用于生物传感器[J].现代化工,2010,30(12):93-93.
3Adham Abulnour.The Avenue of Sphinxes： Restoration of a Legend[J].Journal of Civil Engineering and Architecture,2014,8(8):952-962.
4蔡小华,谢兵.NaBH_4/I_2体系羧酸的还原[J].上饶师范学院学报,2006,26(3):47-48. 被引量：4
5孙景昌,梁红伟,赵涧泽,边继明,冯秋菊,王经纬,赵子文,杜国同.Realization of Ultraviolet Electroluminescence from ZnO Homo junction Fabricated on Silicon Substrate with p-Type ZnO：N Layer Formed by Radical N2O Doping[J].Chinese Physics Letters,2008,25(12):4345-4347. 被引量：2
6窦秀明,孙宝权,熊永华,黄社松,倪海桥,牛智川.Temperature Dependence of Photoluminescence from Single and Ensemble InAs/GaAs Quantum Dots[J].Chinese Physics Letters,2008,25(9):3440-3443.
7李春来,郭洁,张澎,余铨强,马伟涛,缪锡根,赵治亚,栾琳.Planar Magnetic Metamaterial Slabs for Magnetic Resonance Imaging Applications[J].Chinese Physics Letters,2014,31(7):184-187.
8刘丹,吴胜伟,马明旺,张增艳,朱智勇.水和二氧六环水溶液的THz波段介电性质[J].核技术,2010,33(9):688-692. 被引量：4
9Dong-Ze He,Jing-Fei Zhang,Xin Zhang.Redshift drift constraints on holographic dark energy[J].Science China(Physics,Mechanics & Astronomy),2017,60(3):80-86.
10红色草原举办首届中国用户研讨会[J].物流技术与应用,2013(1):112-112.

Journal of Electronic Science and Technology

2015年第2期

浏览历史

内容加载中请稍等...

Terahertz Metamaterial Sensor Based on Electromagnetically Induced Transparency Effect 被引量：2

参考文献29

同被引文献10

引证文献2

二级引证文献10

相关作者

相关机构

相关主题

浏览历史