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A metal-dielectric-metal (MDM) waveguide coupling two square cavities with double baffles is designed in this paper based on the transmission characteristics of surface plasmon polaritons in subwavelength structure. The independent tuning of the dual Fano resonance is implemented by the interference between the wide-spectrum mode generated by the F-P (Fabry Perot) cavity and the two narrow-spectrum modes generated by the two square cavities. Moreover, the independent tuning of the dual Fano resonance can be achieved by changing the sizes of the two square cavities and filling medium. The coupled-mode theory (CMT) is adopted to analyze the transmission characteristics of the dual Fano resonance. The structure is simulated by the finite element method to quantitatively analyze the influence of structural parameters on the independent tuning of the dual Fano resonance and the refractive index sensing characteristics. The proposed sensor yields respectively sensitivity higher than 1020 nm/RIU and 1120 nm/RIU and a figure of merit of 3.29 × 105 and 1.17 × 106 by optimizing the geometry parameters. This structure provides an effective theoretical reference in the optical integration of ultra-fast optical switches, multi-function high-sensitivity sensors and slow-light devices.
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Keywords:
- surface plasmon polaritons /
- Fano resonance /
- square cavity /
- double baffle
[1] Yankovich A B, Verre R, Olsén E, Persson A E O, Trinh V, Dovner G, Käll M, Olsson E 2017 ACS Nano 11 4265Google Scholar
[2] Zeng C, Cui Y D 2013 Opt. Commun. 290 188Google Scholar
[3] Huang L L, Chen X Z, Bai B F, Tan Q F, Jin G F, Zentgraf Z, Zhang S 2013 Light-Sci. Appl. 2 e70Google Scholar
[4] Jankovic N, Cselyuszka N 2018 Sensors 18 1Google Scholar
[5] Yan Z D, Wen X M, Gu P, Zhong H, Zhan P, Chen Z, Wang Z L 2017 Nanotechnol. 28 475203Google Scholar
[6] Khatir M, Granpayeh N 2013 J. Lightwave Technol. 31 1045Google Scholar
[7] 陈颖, 罗佩, 田亚宁, 刘晓飞, 赵志勇, 朱奇光 2017 光学学报 37 0924002
Chen Y, Luo P, Tian Y N, Liu X F, Zhao Z Y, Zhu Q G 2017 Acta Opt. Sin. 37 0924002
[8] Fu H X, Li S L, Wang Y L, Song G, Zhang P F, Wang L L, Yu L 2018 IEEE Photonics J. 10 1
[9] Chen Z, Yu L 2014 IEEE Photonics J. 6 1
[10] Li C, Li S L, Wang Y L, Jiao R Z, Wang L L, Yu L 2017 IEEE Photonics J. 99 1
[11] Wang D Q, Yu X L, Yu Q M 2013 Appl. Phys. Lett. 103 824
[12] Artar A, Yanik A A 2011 Nano Lett. 11 3694Google Scholar
[13] Wu C H, Khanikaev A, Shvets G 2011 Phys. Rev. Lett. 106 107403Google Scholar
[14] Zhang Z D, Wang H Y, Zhang Z Y 2013 Plasmonics 8 797Google Scholar
[15] Rakhshani M R, Mansouri-Birjandi M A 2016 IEEE Sens. J. 16 3041Google Scholar
[16] Kim J, Soref R, Buchwald W R 2010 Opt. Express 18 17997Google Scholar
[17] Zheng S, Ruan Z S, Gao S Q, Long Y, Li S M, He M G, Zhou N, Du J, Shen L, Cai X L, Wang J 2017 Opt. Express 25 25655Google Scholar
[18] Guo Z C, Wen K H, Hu Q Y, Lai W H, Lin J Y, Fang Y H 2018 Sensors 18 1348Google Scholar
[19] Lu H, Liu X, Mao D 2012 Phys. Rev. A 85 53803Google Scholar
[20] Piao X J, Yu S, Koo S, Lee K 2011 Opt. Express 19 10907Google Scholar
[21] Wu C, Ding H F, Huang T Y, Wu X, Chen B W, Ren K X, Fu S N 2017 Plasmonics 13 251
[22] Wen K H, Hu Y H, Chen L, Zhou J Y, Liang L, Meng Z M 2016 Plasmonics 11 315Google Scholar
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图 2 Hz场分布 (a) FR1波峰处的Hz场分布;(b) FR1波谷处的Hz场分布;(c) FR2波峰处的Hz场分布;(d) FR2波谷处的Hz场分布
Figure 2. The Hz field distribution: (a) The Hz field distribution at the peak of FR1; (b) the Hz field distribution at the dip of FR1; (c) the Hz field distribution at the peak of FR2; (d) the Hz field distribution at the dip of FR2.
图 3 参数l1和l2对传感特性的影响 (a)参数l1对FR1的影响;(b)参数l2对FR2的影响;(c)参数l1 = l2或l1/l2对Fano共振线型的影响
Figure 3. Influence of parameters l1 and l2 on sensing characteristics: (a) Influence of parameters l1 on the FR1; (b) influence of parameters l2 on the FR2; (c) influence of parameters l1 = l2 or l1/l2 on the Fano resonance.
图 4 参数L1对传感特性的影响 (a)参数L1对FR1的影响;(b)参数L1对FR1的FOM值的影响;(c)参数L1对FR2的影响;(b)参数L1对FR2的FOM值的影响
Figure 4. Influence of parameters L1 on sensing characteristics: (a) Influence of parameters L1 on the FR1; (b) influence of parameters L1 on the FOM value of FR1; (c) influence of parameters L1 on the FR2; (d) influence of parameters L1 on the FOM value of FR2.
图 5 参数g1, g2和折射率n1, n2对传感特性的影响 (a)参数g1对FR1的影响;(b)参数g2对FR2的影响;(c)折射率n1对FR1的影响;(d)折射率n2对FR2的影响
Figure 5. Influence of parameters g1, g2 and refractive index n1,n2 on sensing characteristics: (a) Influence of parameters g1 on the FR1; (b) influence of parameters g2 on the FR2; (c) influence of refractive index n1 on the FR1; (d) influence of refractive index n2 on the FR2.
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[1] Yankovich A B, Verre R, Olsén E, Persson A E O, Trinh V, Dovner G, Käll M, Olsson E 2017 ACS Nano 11 4265Google Scholar
[2] Zeng C, Cui Y D 2013 Opt. Commun. 290 188Google Scholar
[3] Huang L L, Chen X Z, Bai B F, Tan Q F, Jin G F, Zentgraf Z, Zhang S 2013 Light-Sci. Appl. 2 e70Google Scholar
[4] Jankovic N, Cselyuszka N 2018 Sensors 18 1Google Scholar
[5] Yan Z D, Wen X M, Gu P, Zhong H, Zhan P, Chen Z, Wang Z L 2017 Nanotechnol. 28 475203Google Scholar
[6] Khatir M, Granpayeh N 2013 J. Lightwave Technol. 31 1045Google Scholar
[7] 陈颖, 罗佩, 田亚宁, 刘晓飞, 赵志勇, 朱奇光 2017 光学学报 37 0924002
Chen Y, Luo P, Tian Y N, Liu X F, Zhao Z Y, Zhu Q G 2017 Acta Opt. Sin. 37 0924002
[8] Fu H X, Li S L, Wang Y L, Song G, Zhang P F, Wang L L, Yu L 2018 IEEE Photonics J. 10 1
[9] Chen Z, Yu L 2014 IEEE Photonics J. 6 1
[10] Li C, Li S L, Wang Y L, Jiao R Z, Wang L L, Yu L 2017 IEEE Photonics J. 99 1
[11] Wang D Q, Yu X L, Yu Q M 2013 Appl. Phys. Lett. 103 824
[12] Artar A, Yanik A A 2011 Nano Lett. 11 3694Google Scholar
[13] Wu C H, Khanikaev A, Shvets G 2011 Phys. Rev. Lett. 106 107403Google Scholar
[14] Zhang Z D, Wang H Y, Zhang Z Y 2013 Plasmonics 8 797Google Scholar
[15] Rakhshani M R, Mansouri-Birjandi M A 2016 IEEE Sens. J. 16 3041Google Scholar
[16] Kim J, Soref R, Buchwald W R 2010 Opt. Express 18 17997Google Scholar
[17] Zheng S, Ruan Z S, Gao S Q, Long Y, Li S M, He M G, Zhou N, Du J, Shen L, Cai X L, Wang J 2017 Opt. Express 25 25655Google Scholar
[18] Guo Z C, Wen K H, Hu Q Y, Lai W H, Lin J Y, Fang Y H 2018 Sensors 18 1348Google Scholar
[19] Lu H, Liu X, Mao D 2012 Phys. Rev. A 85 53803Google Scholar
[20] Piao X J, Yu S, Koo S, Lee K 2011 Opt. Express 19 10907Google Scholar
[21] Wu C, Ding H F, Huang T Y, Wu X, Chen B W, Ren K X, Fu S N 2017 Plasmonics 13 251
[22] Wen K H, Hu Y H, Chen L, Zhou J Y, Liang L, Meng Z M 2016 Plasmonics 11 315Google Scholar
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