干形腔耦合MIM波导的传感特性研究
Research on Sensing Characteristics of Chinese Word Gan Shaped Cavity Coupled MIM Waveguides

DOI: 10.12677/NAT.2022.122009, PP. 62-70

Keywords: 光学微腔，MIM波导，传感特性
Optical Microcavity, MIM Waveguide, Sensing Characteristics

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Abstract:

光学微腔的共振耦合在微纳米器件领域非常重要。本文设计的是干形谐振腔和总线波导组成的微纳米结构，其运用时域有限差分法(FDTD)进行模拟计算，分析改变谐振腔与总线波导的耦合间距、谐振腔各支节的长度、腔内介质的折射率时的共振特性以及传感特性，同时还利用耦合模理论和驻波理论验证干形谐振腔和总线波导耦合现象的正确性。优化结构参数，得到结构的最大灵敏度为1444.5 nm/RIU，品质因素最大为68.78，在谐振腔内添加温敏材料，该结构可用于温度传感。最后，在总线波导同侧再添加一个干形结构形成干形腔的级联，出现类电磁感应透明现象，在慢光方面具有重要的应用。本文设计的干形谐振腔可为以后传感器提高灵敏度提供一定的价值参考。
Resonant coupling of optical microcavities is very important in the field of micro-nano devices. In this paper, a micro-nano structure composed of a Chinese word gan shaped cavity and a bus waveguide is designed, and the finite difference time domain (FDTD) method is used to simulation calculations to analyze the coupling spacing between the resonator and the bus waveguide, the length of each branch of the resonator, the resonance characteristics and sensing characteristics of the refractive index of the medium in the cavity, at the same time, the coupling mode theory and standing wave theory are used to verify the correctness of the coupling phenomenon of dry resonators and bus waveguides. By optimizing the structural parameters, the maximum sensitivity of the obtained structure is 1444.5 nm/RIU, and the maximum quality factor is 68.78, by adding temperature-sensitive material in the resonant cavity, the structure can be temperature-sensing. Finally, a Chinese word gan shaped cavity is added on the same side of the bus waveguide to form a cascade of Chinese word gan shaped cavity, and the phenomenon of electromagnetic induction-like transparency appears, which has important applications in slow light. The Chinese word gan shaped cavity designed in this paper provides a certain value reference for improving the sensitivity of the sensor in the future.

References

[1]	陈颖, 许扬眉, 高新贝, 曹景刚, 谢进朝, 朱奇光. 含矩形腔的MIM波导耦合T型腔结构Fano共振传感特性研究[J]. 中国激光, 2019, 46(1): 332-338.
[2]	杨凤英, 陈跃刚. X形谐振腔的共振及其差动传感特性研究[J]. 量子光学学报, 2021, 27(2): 137-147.
[3]	赵颂, 周华, 王淑英, 韩非, 蒋斯涵, 沈向前. 基于金属纳米球等离增强的高效钙钛矿/硅电池设计[J]. 物理学报, 2022, 71(3): 330-336.
[4]	王娅欣, 张克非, 邵龙, 蒋涛. 六信道光子晶体环形腔波分解复用器的设计[J]. 激光杂志, 2019, 40(6): 45-49.
[5]	丁冬艳, 梁忠诚, 顾敏芬, 陈家璧, 庄松林. 波导多层光存储器的数据记录方式[J]. 金陵科技学院学报, 2008(2): 14-17.
[6]	陈颖, 曹景刚, 谢进朝, 高新贝, 许扬眉, 李少华. 含双挡板金属-电介质-金属波导耦合方形腔的独立调谐双重Fano共振特性[J]. 物理学报, 2019, 68(10): 248-256.
[7]	张莹, 陈梅雄, 李莹颖, 袁杰. 光学微腔的应用和发展前景[J]. 激光与光电子学进展, 2015, 52(4): 17-27.
[8]	祁云平, 张婷, 郭嘉, 张宝和, 王向贤. 基于乙醇密封共振腔金属-介质-金属波导的高性能温度和折射率两用传感器[J]. 物理学报, 2020, 69(16): 233-242.
[9]	谷红明, 黄永清, 王欢欢, 武刚, 段晓峰, 刘凯, 任晓敏. 一种新型光学微腔的理论分析[J]. 物理学报, 2018, 67(14): 145-151.
[10]	陈颖, 罗佩, 田亚宁, 刘晓飞, 赵志勇, 朱奇光. 含金属双缝的金属-电介质-金属波导耦合环形腔Fano共振慢光特性研究[J]. 光学学报, 2017, 37(9): 288-293.
[11]	卓青霞, 卓鸿俊. 圆盘阵列结构表面等离激元传感器的研究[J]. 现代信息科技, 2021, 5(7): 33-37.
[12]	魏国强, 田晋平, 杨荣草, 裴为华. 带有同心双圆环谐振腔的MIM波导的Fano谐振特性研究[J]. 量子光学学报, 2019, 25(3): 325-335.
[13]	张利伟, 黄星, 孟威威, 乔文涛. MIM波导结构中的等离激元诱导透明和慢光效应[J]. 半导体光电, 2020, 41(6): 808-814+821.

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