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在基于太赫兹技术的生物化学传感应用中, 折射率传感逐步引起了广泛的研究兴趣. 为了提升太赫兹传感器的性能, 本文提出了基于向日葵型的圆形光子晶体折射率传感器. 所设计的传感器包括两个在光子晶体谐振腔中心对称分布的样品池. 研究了传感器性能与结构参数之间的依赖关系, 并讨论了这些参数的选择从而优化了传感器的性能. 最后, 所设计的折射率传感器在不同参数下获得的最大灵敏度为10.4 μm/RIU, 最大的Q因子为62.21, 最大的品质因数为1.46. 该项工作将圆形光子晶体传感器扩展到太赫兹波段, 实现了高性能太赫兹波折射率传感器.Refractive index sensing is attracting extensive attention in biochemical sensing using terahertz technology. Various structures with strong confinements have been used to design sensors for improving the interaction between the terahertz wave field and the analytes, such as photonic crystals, nanowires, plasmonic structures, and metamaterials. Terahertz wave sensors based on two-dimensional photonic crystal have been used in various areas ranging from disease diagnostics to environmental pollution detection. For improving the performance of terahertz sensor, a sensing scheme based on high-density polyethylene sunflower-typecircular photonic crystal structure is proposed. The designed sensor contains two symmetrical sample cells surrounding a cavity in a circular photonic crystal. The transmission properties of the terahertz wave sensor are analyzed based on COMSOL Multiphysics when the central sample cells are filled with analyte with different refractive indices. The sensor characteristics depending on the structure parameters are analyzed. The choice of these parameters is discussed. Finally, a sensitivity of 10.4 μm/RIU, Q-factor of 62.21, and figure-of-merit of 1.46 are realized. The results in this work are expected to be able to extend the circular photonic crystal-based sensor to terahertz wave region.
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图 1 圆形光子晶体太赫兹波传感器 (a)二维结构; (b)三维结构
Fig. 1. (a) 2D structure of the terahertz wave sensor based on the circular photonic crystal; (b) 3D structure of the sensor.
图 2 计算得到的无缺陷圆形光子晶体的透射光谱(蓝色虚线)和基于圆形光子晶体设计的太赫兹传感器的透射光谱(红色实线)
Fig. 2. Calculated transmission spectra of a circular photonic crystal without defects (dashed blue curve) and the designed sensor (solid red curve).
图 3 不同样品折射率时圆形光子晶体传感器在0.5— 2.0 THz范围内的透射谱
Fig. 3. Transmission spectra of the circular photonic crystal sensor ranging from 0.5 to 2.0 THz with different refractive indices of the samples.
图 4 圆形光子晶体传感器共振频率1.233 THz附近的透射光谱
Fig. 4. Transmission spectra of the circular photonic crystal sensor around the selected resonant frequency of 1.233 THz with different refractive indices of the samples.
图 5 当g = 0 μm参数t对灵敏度S, Q因子和FOM的影响
Fig. 5. Influence of t on sensitivity S, Q-factor and FOM when g = 0 μm.
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[1] Wu F, Wu J J, Guo Z W, Jiang H T, Sun Y, Ren J, Chen H 2019 Phys. Rev. Appl. 12 014028
Google Scholar
[2] Wang X P, Sang M H, Yuan W, Nie Y Y, Luo H M 2016 IEEE Photonics Technol. Lett. 28 264
Google Scholar
[3] Zhang Y B, Liu W W, Li Z C, Zhi L, Cheng H, Chen S Q, Tian J G 2018 Opt. Lett. 43 1842
Google Scholar
[4] Liang L, Hu X, Wen L, Zhu Y H, Yang X G, Zhou J, Zhang Y X, Carranza I E, Grant J, Jiang C P, Cumming D R S, Li B J, Chen Q 2018 Laser Photonics Rev. 12 1800078
Google Scholar
[5] Xu S, Fan F, Ji Y Y, Cheng J R, Chang S J 2019 Opt. Lett. 44 2450
Google Scholar
[6] 李绍和, 李九生, 孙建忠 2019 物理学报 68 104203
Google Scholar
Li S H, Li J S, Sun J Z 2019 Acta Phys. Sin. 68 104203
Google Scholar
[7] Chen J, Nie H, Tang C J, Cui Y H, Yan B, Zhang Z Y, Kong Y R, Xu Z J, Cai P G 2019 Appl. Phys. Express 12 052015
Google Scholar
[8] 田伟, 文岐业, 陈智, 杨青慧, 荆玉兰, 张怀武 2015 物理学报 64 028401
Google Scholar
Tian W, Wen Q Y, Chen Z, Yang Q H, Jing Y L, Zhang H W 2015 Acta Phys. Sin. 64 028401
Google Scholar
[9] Cheng W, Han Z H, Du Y, Qin J Y 2019 Opt. Express 27 16071
Google Scholar
[10] Xiang Y J, Zhu J Q, Wu L M, You Q, Ruan B X, Dai X Y 2018 IEEE Photonics J. 10 6800507
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Google Scholar
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Google Scholar
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Google Scholar
[14] Wang S H, Sun X H, Wang C, Peng G D, Qi Y L, Wang X S 2017 J. Phys. D: Appl. Phys. 50 365102
Google Scholar
[15] Yan D X, Li J S, Jin L F 2019 Laser Phys. 29 025401
Google Scholar
[16] Tavousi A, Rakhshani M R, Mansouri-Birjandi M A 2018 Opt. Commun. 429 166
Google Scholar
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Google Scholar
Wang C H, Zhao G H, Chang S J 2012 Acta Phys. Sin. 61 157805
Google Scholar
[18] Fink Y, Winn J N, Fan S H, Chen C P, Michel J, Joannopoulos J D, Thomas E L 1998 Science 282 1679
Google Scholar
[19] Wu F, Lu G, Guo Z W, Jiang H T, Xue C H, Zheng M J, Chen C X, Du G Q, Chen H 2018 Phys. Rev. Appl. 10 064022
Google Scholar
[20] Wang X, Jiang X, You Q, Guo J, Dai X Y, Xiang Y J 2017 Photonics Res. 5 536
Google Scholar
[21] Kraeh C, Martinez-Hurtado J L, Popescu A, Hedler H, Finley J J 2018 Opt. Mater. 76 106
Google Scholar
[22] Caër C, Serna-Otálvaro S F, Zhang W W, Roux X L, Cassan E 2014 Opt. Lett. 39 5792
Google Scholar
[23] Li L Q, Li T L, Ji F T, Song W P, Zhang G Y, Li Y 2017 Microsyst. Technol. 23 3271
Google Scholar
[24] Ghanaatshoar M, Zamani M 2015 J. Supercond. Novel Magn. 28 1365
Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
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Google Scholar
[29] Lee P T, Lu T W, Fan J H, Tsai F M 2007 Appl. Phys. Lett. 90 151125
Google Scholar
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