基于类电磁诱导透明的双频段太赫兹超材料的传感和慢光特性

孙占硕; 王鑫; 王俊林; 樊勃; 张宇; 冯瑶

doi:10.7498/aps.71.20212163

摘要

提出并研究了一种由三组明模组成的类电磁诱导透明太赫兹超材料结构. 两组具有相似共振频率的明模为两个弱杂化态, 能量在两个共振点之间来回振荡, 产生相消干涉, 在两个共振点之间产生透射窗口. 该超材料的三组明模两两耦合干涉产生双频段的类电磁诱导透明效应. 根据仿真曲线和电场分布, 分析了超材料的类电磁诱导透明形成机理. 此外, 通过仿真和计算研究了超材料的传感特性, 在待测物的最佳厚度下, 两个类电磁诱导透明窗口的折射率灵敏度可高达451.92和545.31 GHz/RIU. 通过对6种石油产品的传感仿真, 验证了双频段超材料比单频段超材料在介电常数匹配方面更具有优势. 还研究了所设计的超材料在慢光效应下的特性. 这两个窗口的最大群时延分别可达9.98和6.23 ps, 此超材料在高灵敏度传感器和慢光器件领域具有重要的应用价值.

关键词:

Abstract

Electromagnetically induced transparency (EIT) is a quantum interference phenomenon in a three-level atomic system. The generation of quantum interference effect significantly reduces the light absorptivity of the specific frequency that is strongly absorbed, and produces a sharp “transmission window” in the resonance absorption region. The EIT is usually accompanied by strong dispersion, which significantly reduces the group velocity of light and enhances the nonlinear interaction. The EIT phenomenon of atomic system usually needs to be observed at very low temperature or high intensity laser, which is a very serious challenge for the application of EIT technology. The simulation of electromagnetically induced transparency using metamaterials can effectively break through these limitations.In this work, an electromagnetically induced transparency-like terahertz metamaterial structure with three bright modes is proposed and investigated. Two weakly hybrid states are composed of two bright modes with similar resonant frequencies. The energy oscillates back and forth between the two modes, and a transparent window is generated between the two resonance points. The designed metamaterial is composed of three groups of bright modes with adjacent resonant frequencies, and the three groups of bright modes are coupled to produce two transparent windows. The electromagnetically induced transparency-like formation mechanism is analyzed based on the simulation curve and electric field distribution. In addition, the sensing properties of metamaterial are determined by simulation and calculation, and the refractive index sensitivities of the two windows can be as high as 451.92 GHz/RIU and 545.31 GHz/RIU under the optimal thickness of the measured substances. Through the sensing simulation of six petroleum products, it is verified that the dual-band has more excellent advantages in dielectric constant matching than the single frequency band. The characteristics of the designed metamaterial in the slow light effect are also studied. The maximum group delay times of the two windows can reach 9.98 ps and 6.23 ps. Therefore, the structure is considered to have an important application value in the field of high sensitivity sensors and slow light devices.

Keywords:

electromagnetically induced transparency-like /
terahertz metamaterials /
sensing characteristics /
slow light characteristics

作者及机构信息

内蒙古大学电子信息工程学院, 呼和浩特　010021

通信作者: 王鑫, wangxin219@imu.edu.cn ; 王俊林, wangjunlin@imu.edu.cn ;

基金项目: 国家自然科学基金(批准号: 51965047)、内蒙古自然科学基金(批准号: 2021MS06012)和内蒙古自治区科技计划项目(批准号: 2020GG0185)资助的课题.

Authors and contacts

College of Electronic Information Engineering, Inner Mongolia University, Hohhot 010021, China

Corresponding author: Wang Xin, wangxin219@imu.edu.cn ; Wang Jun-Lin, wangjunlin@imu.edu.cn ;

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 51965047), the Natural Science Foundation of Inner Mongolia Autonomous Region, China (Grant No. 2021MS06012), and the Science and Technology Planning Project of Inner Mongolia Autonomous Region, China (Grant No. 2020GG0185).

文章全文 : translate this paragraph

参考文献

[1]	Harris S E, Field J E, Imamoğlu A 1990 Phys. Rev. Lett. 64 1107 Google Scholar
[2]	Xiao M, Li Y Q, Jin S Z, Gea-Banacloche J 1995 Phys. Rev. Lett. 74 666 Google Scholar
[3]	Hau L V, Harris S E, Dutton Z, Behroozi C H 1999 Nature 397 594 Google Scholar
[4]	Boller K J, Imamoğlu A, Harris S E 1991 Phys. Rev. Lett. 66 2593 Google Scholar
[5]	Lin X Q, Chen Z, Yu J W, Liu P Q, Li P F, Chen Z Z 2016 IEEE Sens. J. 16 293 Google Scholar
[6]	Lin X Q, Peng J, Chen Z, Yu J W, Yang X F 2018 IEEE Sens. J. 18 9251 Google Scholar
[7]	Li H M, Liu S B, Liu S Y, Zhang H F 2014 Appl. Phys. Lett. 105 133514 Google Scholar
[8]	Zhang F L, He X, Zhou X, Zhou Y L, An S, Yu G Y, Pang L N 2013 Appl. Phys. Lett. 103 221904 Google Scholar
[9]	Longdell J J, Fraval E, Sellars M J, Manson N B 2005 Phys. Rev. Lett. 95 063601 Google Scholar
[10]	Ma J Y, Qin J Y, Campbell G T, Lecamwasam R, Sripathy K, Hope J, Buchler B, Lam P K 2020 Sci. Adv. 6 eaax8256 Google Scholar
[11]	Liu N, Weiss T, Mesch M, Langguth L, Eigenthaler U, Hirscher M, Sonnichsen C, Giessen H 2010 Nano Lett. 10 1103 Google Scholar
[12]	Waks E, Vuckovic J 2006 Phys. Rev. Lett. 96 153601 Google Scholar
[13]	Tassin P, Zhang L, Koschny T, Economou E N, Soukoulis C M 2009 Opt. Express 17 5595 Google Scholar
[14]	Sun Y R, Chen H, Li X J, Hong Z 2017 Opt. Commun. 392 142 Google Scholar
[15]	Xiao S Y, Wang T, Liu T T, Yan X C, Li Z, Xu C 2018 Carbon 126 271 Google Scholar
[16]	Zhang S, Genov D A, Wang Y, Liu M, Zhang X 2008 Phys. Rev. Lett. 101 047401 Google Scholar
[17]	Hokmabadi M P, Kim J H, Rivera E, Kung P, Kim S M 2015 Sci. Rep. 5 14373 Google Scholar
[18]	Zheng S Q, Zhao Q X, Peng L, Jiang X 2021 Results Phys. 23 104040 Google Scholar
[19]	Zhang J J, Xiao S S, Jeppesen C, Kristensen A, Mortensen N A 2010 Opt. Express 18 17187 Google Scholar
[20]	Hu S, Yang H L, Han S, Huang X J, Xiao B X 2015 J. Appl. Phys. 117 043107 Google Scholar
[21]	Tang B, Jia Z P, Huang L, Su J B, Jiang C 2021 IEEE J. Sel. Top. Quantum Electron. 27 4700406 Google Scholar
[22]	Gu J Q, Singh R, Liu X J, Zhang X Q, Ma Y F, Zhang S, Maier S A, Tian Z, Azad A K, Chen H T, Taylor A J, Han J G, Zhang W L 2012 Nat. Commun. 3 1151 Google Scholar
[23]	Sarkar R, Devi K M, Ghindani D, Prabhu S S, Chowdhury D R, Kumar G 2020 J. Opt. 22 035105 Google Scholar
[24]	Li H M, Liu S B, Liu S Y, Wang S Y, Zhang H F, Bian B R, Kong X K 2015 Appl. Phys. Lett. 106 114101 Google Scholar
[25]	Li H M, Liu S B, Liu S Y, Wang S Y, Ding G W, Yang H, Yu Z Y, Zhang H F 2015 Appl. Phys. Lett. 106 083511 Google Scholar
[26]	Zhang K, Wang C, Qin L, Peng R W, Xu D H, Xiong X, Wang M 2014 Opt. Lett. 39 3539 Google Scholar
[27]	Liu T T, Wang H X, Liu Y, Xiao L S, Zhou C B, Liu Y B, Xu C, Xiao S Y 2018 J. Phys. D:Appl. Phys. 51 415105 Google Scholar
[28]	Devi K M, Chowdhury D R, Kumar G, Sarma A K 2018 J. Appl. Phys. 124 063106 Google Scholar
[29]	Zhu L, Meng F Y, Fu J H, Wu Q, Hua J 2012 Opt. Express 20 4494 Google Scholar
[30]	Hu J, Lang T T, Hong Z, Shen C Y, Shi G H 2018 J. Lightwave Technol. 36 2083 Google Scholar
[31]	Kang M, Li Y N, Chen J, Chen J, Bai Q, Wang H T, Wu P H 2010 Appl. Phys. B 100 699 Google Scholar
[32]	Wu X J, Quan B G, Pan X C, Xu X L, Lu X C, Gu C Z, Wang L 2013 Biosens. Bioelectron. 42 626 Google Scholar
[33]	Zhang C, Liang L, Ding L, Jin B, Hou Y, Li C, Jiang L, Liu W, Hu W, Lu Y, Kang L, Xu W, Chen J, Wu P 2016 Appl. Phys. Lett. 108 241105 Google Scholar
[34]	Xie Q, Dong G X, Wang B X, Huang W Q 2018 Nanoscale Res. Lett. 13 2947 Google Scholar
[35]	Saadeldin A S, Hameed M F O, Elkaramany E M A, Obayya S S A 2019 IEEE Sens. J. 19 7993 Google Scholar
[36]	Chen T, Zhang D P, Huang F Y, Li Z, Hu F R 2020 Mater. Res. Express 7 095802 Google Scholar
[37]	Zhang X, Wang Y, Cui Z, Zhang X, Chen S, Zhang K, Wang X 2021 Opt. Mater. Express 11 1470 Google Scholar
[38]	Liu T T, Zhou C B, Cheng L, Jiang X Y, Wang G Z, Xu C, Xiao S Y 2019 J. Opt. 21 035101 Google Scholar
[39]	Zhang Z, Yang J, Han Y, He X, Zhang J, Huang J, Chen D, Xu S, Xie W 2020 Appl. Phys. A 126 199 Google Scholar
[40]	Jiang J, Cui J, Fang R, Wu F, Yang Y 2020 Integr. Ferroelectr. 212 1 Google Scholar
[41]	Zeng F, Zhong M 2021 Opt. Mater. 111 110596 Google Scholar

施引文献

图 1 提出的超材料的几何结构和单元结构图

Fig. 1. Geometry of the proposed metamaterial structure and the unit structure diagram.

下载: 全尺寸图片幻灯片

图 2 (a) 单波段超材料、DR和DT的透射幅值曲线; (b) 双波段超材料、DR、DT和FL的透射幅值曲线

Fig. 2. (a) Transmission amplitude curves of the single-band metamaterial, DR and DT; (b) transmission amplitude curves of the dual-band metamaterial, DR, DT and FL.

下载: 全尺寸图片幻灯片

图 3 EIT-like的等效原子能级示意图

Fig. 3. Schematic diagram of EIT-like equivalent atomic energy level.

下载: 全尺寸图片幻灯片

图 4 (a) 三个波谷频率的电场分布; (b) 两个透射峰值频率的电场分布

Fig. 4. (a) Electric field distribution of the three trough frequencies; (b) electric field distribution of two transmission peak frequencies.

下载: 全尺寸图片幻灯片

图 5 超材料覆盖厚度为4 µm且折射率不同的被测物的仿真曲线

Fig. 5. Simulation curves of the metamaterial covered with the measured substances with thickness 4 µm and different refractive indices.

下载: 全尺寸图片幻灯片

图 6 (a) 超材料表面覆盖不同被测物厚度对应的第一个EIT-like窗口的拟合灵敏度; (b) 超材料表面覆盖不同被测物厚度对应的第二个EIT-like窗口的拟合灵敏度; (c) 被测物质的厚度对灵敏度的影响

Fig. 6. (a) Fitting sensitivity of the first EIT-like window corresponding to different measured substances thickness covered on the surface of metamaterial; (b) fitting sensitivity of the second EIT-like window corresponding to different measured substances thickness covered on the surface of metamaterial; (c) influence of thickness of the measured substances on sensitivity.

下载: 全尺寸图片幻灯片

图 7 (a) 超材料的传输曲线和相移曲线; (b) 计算的超材料的群时延和群折射率

Fig. 7. (a) Simulated transmission curve and phase shift curve of the metamaterial; (b) calculated group delay and group index of the metamaterial.

下载: 全尺寸图片幻灯片

表 1 超材料覆盖待测物的仿真和计算结果

Table 1. Simulation and calculation results of metamaterial covering the measured substances.

The measured substance	ε	Frequency shift /GHz		Calculated ε		Calculated average ε
The measured substance	ε	First	Second	First	Second	Calculated average ε
JP-4	1.7	133.85	171.83	1.68	1.73	1.705
Petroleum ether	1.8	152.73	188.22	1.79	1.81	1.8
90#	2.01	188.82	227.67	2.01	2.01	2.01
93#	2.11	201.44	248.53	2.09	2.12	2.105
Transmission oil	2.2	218.42	265.2	2.2	2.21	2.205
97#	2.25	222.98	270.68	2.23	2.24	2.235

下载: 导出CSV

表 2 各种超材料在传感和慢光方面性能的比较

Table 2. Comparison of sensing and slow light properties of various metamaterials.

Performance index	Ref.[34]	Ref.[35]	Ref.[36]	Ref.[37]	Ref.[38]	Ref.[39]	Ref.[40]	Ref.[41]	This paper
Performance index	2018	2019	2020	2021	2019	2020	2020	2021	—
Q	58	22.05	30.5	—	—	—	11.88	—	26.63	19.46
S/(GHz·RIU^–1)	105	300	280	229.7	—	—	—	—	452	545
FOM	7.5	2.94	8.54	—	—	—	—	—	4.75	6.21
$ {\tau }_{\mathrm{g}} $/ps	—	—	—	—	6.74	7	7.28	5.5	9.98	6.23

下载: 导出CSV

map

[1]	Harris S E, Field J E, Imamoğlu A 1990 Phys. Rev. Lett. 64 1107 Google Scholar
[2]	Xiao M, Li Y Q, Jin S Z, Gea-Banacloche J 1995 Phys. Rev. Lett. 74 666 Google Scholar
[3]	Hau L V, Harris S E, Dutton Z, Behroozi C H 1999 Nature 397 594 Google Scholar
[4]	Boller K J, Imamoğlu A, Harris S E 1991 Phys. Rev. Lett. 66 2593 Google Scholar
[5]	Lin X Q, Chen Z, Yu J W, Liu P Q, Li P F, Chen Z Z 2016 IEEE Sens. J. 16 293 Google Scholar
[6]	Lin X Q, Peng J, Chen Z, Yu J W, Yang X F 2018 IEEE Sens. J. 18 9251 Google Scholar
[7]	Li H M, Liu S B, Liu S Y, Zhang H F 2014 Appl. Phys. Lett. 105 133514 Google Scholar
[8]	Zhang F L, He X, Zhou X, Zhou Y L, An S, Yu G Y, Pang L N 2013 Appl. Phys. Lett. 103 221904 Google Scholar
[9]	Longdell J J, Fraval E, Sellars M J, Manson N B 2005 Phys. Rev. Lett. 95 063601 Google Scholar
[10]	Ma J Y, Qin J Y, Campbell G T, Lecamwasam R, Sripathy K, Hope J, Buchler B, Lam P K 2020 Sci. Adv. 6 eaax8256 Google Scholar
[11]	Liu N, Weiss T, Mesch M, Langguth L, Eigenthaler U, Hirscher M, Sonnichsen C, Giessen H 2010 Nano Lett. 10 1103 Google Scholar
[12]	Waks E, Vuckovic J 2006 Phys. Rev. Lett. 96 153601 Google Scholar
[13]	Tassin P, Zhang L, Koschny T, Economou E N, Soukoulis C M 2009 Opt. Express 17 5595 Google Scholar
[14]	Sun Y R, Chen H, Li X J, Hong Z 2017 Opt. Commun. 392 142 Google Scholar
[15]	Xiao S Y, Wang T, Liu T T, Yan X C, Li Z, Xu C 2018 Carbon 126 271 Google Scholar
[16]	Zhang S, Genov D A, Wang Y, Liu M, Zhang X 2008 Phys. Rev. Lett. 101 047401 Google Scholar
[17]	Hokmabadi M P, Kim J H, Rivera E, Kung P, Kim S M 2015 Sci. Rep. 5 14373 Google Scholar
[18]	Zheng S Q, Zhao Q X, Peng L, Jiang X 2021 Results Phys. 23 104040 Google Scholar
[19]	Zhang J J, Xiao S S, Jeppesen C, Kristensen A, Mortensen N A 2010 Opt. Express 18 17187 Google Scholar
[20]	Hu S, Yang H L, Han S, Huang X J, Xiao B X 2015 J. Appl. Phys. 117 043107 Google Scholar
[21]	Tang B, Jia Z P, Huang L, Su J B, Jiang C 2021 IEEE J. Sel. Top. Quantum Electron. 27 4700406 Google Scholar
[22]	Gu J Q, Singh R, Liu X J, Zhang X Q, Ma Y F, Zhang S, Maier S A, Tian Z, Azad A K, Chen H T, Taylor A J, Han J G, Zhang W L 2012 Nat. Commun. 3 1151 Google Scholar
[23]	Sarkar R, Devi K M, Ghindani D, Prabhu S S, Chowdhury D R, Kumar G 2020 J. Opt. 22 035105 Google Scholar
[24]	Li H M, Liu S B, Liu S Y, Wang S Y, Zhang H F, Bian B R, Kong X K 2015 Appl. Phys. Lett. 106 114101 Google Scholar
[25]	Li H M, Liu S B, Liu S Y, Wang S Y, Ding G W, Yang H, Yu Z Y, Zhang H F 2015 Appl. Phys. Lett. 106 083511 Google Scholar
[26]	Zhang K, Wang C, Qin L, Peng R W, Xu D H, Xiong X, Wang M 2014 Opt. Lett. 39 3539 Google Scholar
[27]	Liu T T, Wang H X, Liu Y, Xiao L S, Zhou C B, Liu Y B, Xu C, Xiao S Y 2018 J. Phys. D:Appl. Phys. 51 415105 Google Scholar
[28]	Devi K M, Chowdhury D R, Kumar G, Sarma A K 2018 J. Appl. Phys. 124 063106 Google Scholar
[29]	Zhu L, Meng F Y, Fu J H, Wu Q, Hua J 2012 Opt. Express 20 4494 Google Scholar
[30]	Hu J, Lang T T, Hong Z, Shen C Y, Shi G H 2018 J. Lightwave Technol. 36 2083 Google Scholar
[31]	Kang M, Li Y N, Chen J, Chen J, Bai Q, Wang H T, Wu P H 2010 Appl. Phys. B 100 699 Google Scholar
[32]	Wu X J, Quan B G, Pan X C, Xu X L, Lu X C, Gu C Z, Wang L 2013 Biosens. Bioelectron. 42 626 Google Scholar
[33]	Zhang C, Liang L, Ding L, Jin B, Hou Y, Li C, Jiang L, Liu W, Hu W, Lu Y, Kang L, Xu W, Chen J, Wu P 2016 Appl. Phys. Lett. 108 241105 Google Scholar
[34]	Xie Q, Dong G X, Wang B X, Huang W Q 2018 Nanoscale Res. Lett. 13 2947 Google Scholar
[35]	Saadeldin A S, Hameed M F O, Elkaramany E M A, Obayya S S A 2019 IEEE Sens. J. 19 7993 Google Scholar
[36]	Chen T, Zhang D P, Huang F Y, Li Z, Hu F R 2020 Mater. Res. Express 7 095802 Google Scholar
[37]	Zhang X, Wang Y, Cui Z, Zhang X, Chen S, Zhang K, Wang X 2021 Opt. Mater. Express 11 1470 Google Scholar
[38]	Liu T T, Zhou C B, Cheng L, Jiang X Y, Wang G Z, Xu C, Xiao S Y 2019 J. Opt. 21 035101 Google Scholar
[39]	Zhang Z, Yang J, Han Y, He X, Zhang J, Huang J, Chen D, Xu S, Xie W 2020 Appl. Phys. A 126 199 Google Scholar
[40]	Jiang J, Cui J, Fang R, Wu F, Yang Y 2020 Integr. Ferroelectr. 212 1 Google Scholar
[41]	Zeng F, Zhong M 2021 Opt. Mater. 111 110596 Google Scholar

[1]	成昱轩, 许辉, 于鸿飞, 黄林琴, 谷志超, 陈玉峰, 贺龙辉, 陈智全, 侯海良. 基于石墨烯人工微结构的三频段太赫兹传感与慢光. , 2025, 74(6): . doi: 10.7498/aps.74.20241576
[2]	杨肖杰, 许辉, 徐海烨, 李铭, 于鸿飞, 成昱轩, 侯海良, 陈智全. 基于石墨烯等离激元太赫兹结构的传感及慢光应用. , 2024, 73(15): 157802. doi: 10.7498/aps.73.20240668
[3]	张向, 王玥, 张婉莹, 张晓菊, 罗帆, 宋博晨, 张狂, 施卫. 单壁碳纳米管太赫兹超表面窄带吸收及其传感特性. , 2024, 73(2): 026102. doi: 10.7498/aps.73.20231357
[4]	金嘉升, 马成举, 张垚, 张跃斌, 鲍士仟, 李咪, 李东明, 刘洺, 刘芊震, 张贻歆. 基于相变材料的慢光和吸收可切换多功能太赫兹超材料. , 2023, 72(8): 084202. doi: 10.7498/aps.72.20222336
[5]	向星诚, 马海贝, 王磊, 田达, 张伟, 张彩虹, 吴敬波, 范克彬, 金飚兵, 陈健, 吴培亨. 利用样品阱实现太赫兹超材料的超微量传感. , 2023, 72(12): 128701. doi: 10.7498/aps.72.20230080
[6]	葛宏义, 李丽, 蒋玉英, 李广明, 王飞, 吕明, 张元, 李智. 基于双开口金属环的太赫兹超材料吸波体传感器. , 2022, 71(10): 108701. doi: 10.7498/aps.71.20212303
[7]	杨泽浩, 刘紫威, 杨博, 张成龙, 蔡宸, 祁志美. 基于多孔金膜的太赫兹导模共振生化传感特性仿真. , 2022, 71(21): 218701. doi: 10.7498/aps.71.20220722
[8]	陈永强, 许光远, 王军, 方宇, 吴幸智, 丁亚琼, 孙勇. 基于非对称微波光子晶体的电磁二极管. , 2022, 71(3): 034701. doi: 10.7498/aps.71.20211291
[9]	宁仁霞, 黄旺, 王菲, 孙剑, 焦铮. 双明模耦合的双波段类电磁诱导透明研究. , 2022, 71(1): 014201. doi: 10.7498/aps.71.20211312
[10]	张跃斌, 马成举, 张垚, 金嘉升, 鲍士仟, 李咪, 李东明. 基于非对称结构全介质超材料的类电磁诱导透明效应研究. , 2021, 70(19): 194201. doi: 10.7498/aps.70.20210070
[11]	庞慧中, 王鑫, 王俊林, 王宗利, 刘苏雅拉图, 田虎强. 双频带太赫兹超材料吸波体传感器传感特性. , 2021, 70(16): 168101. doi: 10.7498/aps.70.20210062
[12]	王鑫, 王俊林. 太赫兹波段电磁超材料吸波器折射率传感特性. , 2021, 70(3): 038102. doi: 10.7498/aps.70.20201054
[13]	陈永强, 许光远, 王军, 方宇, 吴幸智, 丁亚琼, 孙勇. 基于非对称微波光子晶体的电磁二极管. , 2021, (): . doi: 10.7498/aps.70.20211291
[14]	宁仁霞, 黄旺, 王菲, 孙剑, 焦铮. 双明模耦合的双波段类电磁诱导透明研究. , 2021, (): . doi: 10.7498/aps.70.20211312
[15]	王越, 冷雁冰, 王丽, 董连和, 刘顺瑞, 王君, 孙艳军. 基于石墨烯振幅可调的宽带类电磁诱导透明超材料设计. , 2018, 67(9): 097801. doi: 10.7498/aps.67.20180114
[16]	贾玥, 陈肖含, 张好, 张临杰, 肖连团, 贾锁堂. Rydberg原子的电磁诱导透明光谱的噪声转移特性. , 2018, 67(21): 213201. doi: 10.7498/aps.67.20181168
[17]	张玉萍, 李彤彤, 吕欢欢, 黄晓燕, 张会云. 工字形太赫兹超材料吸波体的传感特性研究. , 2015, 64(11): 117801. doi: 10.7498/aps.64.117801
[18]	司黎明, 侯吉旋, 刘埇, 吕昕. 基于负微分电阻碳纳米管的太赫兹波有源超材料特性参数提取. , 2013, 62(3): 037806. doi: 10.7498/aps.62.037806
[19]	刘志强, 常胜江, 王晓雷, 范飞, 李伟. 基于VO2薄膜相变原理的温控太赫兹超材料调制器. , 2013, 62(13): 130702. doi: 10.7498/aps.62.130702
[20]	姚鸣, 朱卡的, 袁晓忠, 蒋逸文, 吴卓杰. 声子辅助的电磁感应透明和超慢光效应的研究. , 2006, 55(4): 1769-1773. doi: 10.7498/aps.55.1769

计量

文章访问数: 5639
PDF下载量: 167
被引次数: 0

姓名
邮箱
手机号码
标题
留言内容
验证码

搜索

留言板