Refractive index sensor and filter of metal-insulator-metal waveguide based on ring resonator embedded by cross structure

Qi Yun-Ping; Zhang Xue-Wei; Zhou Pei-Yang; Hu Bing-Bing; Wang Xiang-Xian

doi:10.7498/aps.67.20180758

Abstract

Continuous improvement in nanofabrication and nano-characterization capabilities have changed projections about the role that metals could play in developing the new optical devices. Surface plasmon polaritons are evanescent waves that propagate along a metal-dielectric interface. They can be laterally confined below the diffraction limit by using subwavelength metal structures, rendering them attractive to the development of miniaturized optical devices. A surface plasmon polariton refractive index sensor and filter which consist of two metal-insulator-metal (MIM) waveguides coupled to each other by a ring resonator embedded by cross structure are proposed. And the transmission characteristics of surface plasmon polaritons are studied in our proposed structure. The transmission properties of such a structure are simulated by the finite element method, and the eigenvalue wavelengths of the ring resonator are calculated theoretically. The sensing characteristics of such a structure are systematically analyzed by investigating the transmission spectrum. The results show that there are three resonance peaks in the transmission spectrum, that is, three resonance modes corresponding to the eigenvalue solutions of the first, second and third-order Bessel eigen-function equations, and each of which has a linear relationship with the refractive index of the material under sensing. Through the optimization of structural parameters, we achieve a theoretical value of the refractive index sensitivity (S) as high as 1500 nm/RIU, and the corresponding sensing resolution is 1.3310-4 RIU. More importantly, it is sensitive to none of the parameters of our proposed structure, which means that the sensitivity of the sensor is immune to the fabrication deviation. In addition, by the resonant theory of ring resonator, we find a linear relationship between the resonance wavelength and the radius of ring resonator. So the resonance wavelength can be easily manipulated by adjusting the radius and refractive index. In addition, the positions of transmission peaks can be easily modulated by changing the radius of the ring, which can be used to design band-pass filter for a large wavelength range. Moreover, the transmission intensity and the transmission bandwidth decrease as spacing distance between the MIM waveguide and ring cavity increases. These results would be helpful in designing the refractive index sensor of high-sensitivity and band-pass filters, and have guiding significance for biological sensor applications.

Keywords:

Authors and contacts

1.
Engineering Research Center of Gansu Province for Intelligent Information Technology and Application, College of Physics and Electronic Engineering, Northwest Normal University, Lanzhou 730070, China;
2.
School of Science, Lanzhou University of Technology, Lanzhou 730050, China

Corresponding author: Qi Yun-Ping, yunpq@126.com

Funds: Project supported by the National Natural Science Foundation of China (Grant No. 61367005), the Natural Science Foundation of Gansu Province, China (Grant No. 17JR5RA078), Northwest Normal University Young Teachers' Scientific Research Capability Upgrading Program (Grant No. NWNU-LKQN-17-6), and the Northwest Normal University Graduate Student Innovation Ability Enhancement Program Foundation, China (Grant No. CX2018Y167).

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Cited By

[1]	Hunsperger R G 2009 Integrated Optics:Theory and Application (Berlin:Springer) p85
[2]	Barnes W L, Dereux A, Ebbesen T W 2003 Nature 424 824
[3]	Pang Z, Tong H, Wu X, Zhu J, Wang X, Yang H, Qi Y 2018 Opt. Quant. Electron. 50 335
[4]	Wang L, Cai W, Tan X H, Xiang Y X, Zhang X Z, Xu J J 2011 Acta Phys. Sin. 60 067305 (in Chinese) [王垒, 蔡卫, 谭信辉, 向吟啸, 张心正, 许京军 2011 60 067305]
[5]	Hua L, Wang G X, Liu X M 2013 Chin. Sci. Bull. 58 3607
[6]	Amini A, Aghili S, Golmohammadi S, Gasemi P 2017 Opt. Commun. 403 226
[7]	Wang G, Lu H, Liu X, Mao D, Duan L 2011 Opt. Express 19 3513
[8]	Gao H, Shi H, Wang C, Du C, Luo X, Deng Q, L Y, Lin X, Yao H 2005 Opt. Express 13 10795
[9]	Veronis G, Fan S 2005 Appl. Phys. Lett. 87 131102
[10]	Han Z, Liu L, Forsberg E 2006 Opt. Commun. 259 690
[11]	Zhang Z D, Zhao Y N, Lu D, Xiong Z H, Zhang Z Y 2012 Acta Phys. Sin. 61 187301 (in Chinese) [张志东, 赵亚男, 卢东, 熊祖洪, 张中月 2012 61 187301]
[12]	Tang Y, Zhang Z D, Wang R B, Hai Z Y, Xue C Y, Zhang W D, Yan S B 2017 Sensors 17 784
[13]	Liu Z Q, Liu G Q, Liu X S, Shao H B, Chen J, Huang S, Liu M L, Fu G L 2015 Plasmonics 10 821
[14]	Wei W, Zhang X, Ren X 2015 Nanoscale Res. Lett. 10 211
[15]	Ren M X, Pan C P, Li Q Q, Cai W, Zhang X Z, Wu Q, Fan S S, Xu J J 2013 Opt. Lett. 38 3133
[16]	Gallinet B, Martin O J 2013 ACS Nano 7 6978
[17]	Shen Y, Zhou J H, Liu T R, Tao Y T, Jiang R B, Liu M X, Xiao G H, Zhu J H, Zhou Z K, Wang X H, Jin C J, Wang J F 2013 Nature Commun. 4 2381
[18]	Lodewijks K, Ryken J, Roy W V, Borghs G, Lagae L, Dorpe P V 2013 Plasmonics 8 1379
[19]	Qiu G, Ng S P, Wu C M 2016 Sens. Actuators B:Chem. 234 247
[20]	Zhang X N, Liu G Q, Liu Z Q, Hu Y, Cai Z J, Liu X S, Fu G L, Liu M L 2014 Opt. Eng. 53 107108
[21]	Huang D W, Ma Y F, Sung M J, Huang C P 2010 Opt. Eng. 49 054403
[22]	Zhang Y N, Xie W G, Wang J, Wang P 2018 Opt. Mater. 75 666
[23]	Wu D K, Kuhlmey B T, Eggleton B J 2009 Opt. Lett. 34 322
[24]	Lin X S, Huang X G 2008 Opt. Lett. 33 2874
[25]	Liu H, Gao Y, Zhu B, Ren G, Jian S 2015 Opt. Commun. 334 164
[26]	Wu T S, Liu Y M, Yu Z Y, Peng Y W, Shu C G, Ye H 2014 Opt. Express 22 7669
[27]	Wang T B, Wen X W, Yin C P, Wang H Z 2009 Opt. Express 17 24096
[28]	Liu D D, Wang J C, Zhang F, Pan Y W, Lu J, Ni X W 2017 Sensors 17 585
[29]	Johnson P B, Christy R W 1972 Phys. Rev. B 6 4370
[30]	Palik E D 1985 Handbook of Optical Constants of Solids (New York:Academic Press) pp350-356

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Vol. 67, Issue 19 - 2018-10-05

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