回音壁模式光学微腔及其应用研究进展

黄嘉祺; 邹辉

doi:10.13756/j.gtxyj.2024.230039

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回音壁模式光学微腔及其应用研究进展

光电器件研究与应用 | 更新时间：2024-05-30

- 回音壁模式光学微腔及其应用研究进展
- Research Progress of Whispering Gallery Mode Optical Microcavity and Its Application
- 光通信研究 2024年第3期页码：23003901-23003909
- 作者机构：
  
  1.南京邮电大学　电子与光学工程学院，南京　210023
  2.中国工程物理研究院　应用电子学研究所，四川　绵阳　621054
- 作者简介：
  
  黄嘉祺（1999-），男，江苏无锡人。硕士，主要研究方向为回音壁模式光学微腔。
  邹辉，副教授。E-mail：zouhui1010@163.com
- 基金信息：
- DOI：10.13756/j.gtxyj.2024.230039
  中图分类号： TN256
- 纸质出版日期：2024-06-10，
  
  收稿日期：2023-03-15，
  
  修回日期：2023-03-20，
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黄嘉祺，邹辉.回音壁模式光学微腔及其应用研究进展[J].光通信研究，2024（3）：230039.

Huang J Q, Zou H. Research Progress of Whispering Gallery Mode Optical Microcavity and Its Application[J]. Study on Optical Communications, 2024（3）：230039.
黄嘉祺，邹辉.回音壁模式光学微腔及其应用研究进展[J].光通信研究，2024（3）：230039. DOI： 10.13756/j.gtxyj.2024.230039.

Huang J Q, Zou H. Research Progress of Whispering Gallery Mode Optical Microcavity and Its Application[J]. Study on Optical Communications, 2024（3）：230039. DOI： 10.13756/j.gtxyj.2024.230039.

摘要

近年来，高品质因子的回音壁模式（WGM）光学微腔发展迅速，成为光学和物理领域的热点研究。光学微腔是一种微型光学元件，由于其微小的尺寸和高品质因子，可以加强光与物质的相互作用并使光在其中长时间存留。WGM光学微腔是光学微腔的典型代表之一，具有体积小、灵敏度高和寿命长等优点，目前，基于WGM光学微腔的应用主要集中在各类传感、激光器和滤波器等领域。然而，当前对WGM光学微腔的研究还未实现大规模生产，仅处于实验室研究阶段，工业化生产还存在成本高、制作工艺困难等缺点。文章重点介绍了WGM光学微腔的研究进展，阐述了回音壁材料对

值的影响，近几年WGM光学微腔在传感、激光器和滤波器领域的应用，并提出了在可能实现全光网络的未来WGM光学微腔存在的挑战及进一步研究方向。对于后续研究，文章认为首先需降低成本、缩短时间，提高制备工艺的精度和效率；其次，需要解决微腔与光学器件耦合的问题，提高耦合效率并提高抗干扰能力；最后，需要解决腔体对环境的敏感性问题，以确保微腔在制备滤波器等器件时具有良好的稳定性。

Abstract

In recent years

high quality factor echo wall mode optical microcavities have developed rapidly and become a hot research topic in the fields of optics and physics. Optical microcavity is a kind of micro optical element. Due to its small size and high-quality factor

it can enhance the interaction between light and matter

enabling long-time light stays. Echo wall mode resonators are one of the typical representatives of optical microcavities

with advantages of small size

high sensitivity

and long life. Currently

applications based on echo wall mode resonators are mainly concentrated in various fields such as sensors

lasers

filters

and so on. However

current research on echo wall mode resonators has not yet achieved large-scale production

and is only in the laboratory research stage. Industrial production still has shortcomings such as high cost and manufacturing process difficulties. This article focuses on the research progress of echo wall mode resonators

expounds the impact of echo wall materials on

values

and discusses the applications of echo wall mode resonators in the fields of sensors

lasers

and filters in recent years. It also proposes the challenges and further research directions of echo wall mode resonators in the future

which may realize all-optical networks. For further researc

h directions

we believe that it is necessary to reduce costs

shorten time

and improve the accuracy and efficiency of the preparation process. It is also necessary to solve the coupling problem between the microcavity and the optical device

improving the coupling efficiency and the anti-interference ability. It should also address the sensitivity of the cavity to the environment to ensure that the microcavity has good stability when preparing devices such as filters.

关键词

回音壁模式高品质因子光学微腔传感

Keywords

WGMhigh quality factoroptical microcavitysensor

references

Grudinin I S, Matsko A B, Maleki L. Brillouin Lasing with a CaF2 Whispering Gallery Mode Resonator[J]. Physical Review Letters, 2009, 102(4): 043902.

Ilchenko V S, Savchenkov A A, Matsko A B, et al. Nonlinear Optics and Crystalline Whispering Gallery-Mode Cavities[J]. Physical Review Letters, 2004, 92(4): 043903.

Vollmer F, Arnold S. Whispering-gallery-mode Biosensing: Label-free Detection down to Single Molecules[J]. Nature Methods, 2008, 5(7): 591-596.

Feron P, Arnaud C, Boustimi M, et al. Optical Feedback on Whispering Gallery Mode Laser: Wavelength Shifts in Erbium-doped Microspherical Laser[C]//Integrated Optics and Photonic Integrated Circuits. Strasbourg, France: SPIE, 2004, 5451: 199-209.

Haroche S, Kleppner D. Cavity Quantum Electrodynamics[J]. Physics Today, 1989, 42(1): 24-30.

Rayleigh L. CXII. The Problem of the Whispering Gallery[J]. The London, Edinburgh, and Dublin Philosophical Magazineand Journal of Science, 1910, 20(120): 1001-1004.

赵宏春. 回音壁模式光学微腔传感原理及性能研究[D]. 北京: 中国科学院大学, 2020.

Zhao H C. Study on the Principle and Performance of Echo Wall Mode Optical Microcavity Sensing[D]. Beijing: University of Chinese Academy of Sciences, 2020.

Oraevsky A N. Whispering-gallery Waves[J]. Quantum Electronics, 2002, 32(5): 377.

Chremmos I, Schwelb O, Uzunoglu N. Photonic Microresonator Research and Applications[M]. New York: Springer, 2010: 1155-1175.

邹长铃, 董春华, 崔金明. 回音壁模式光学微腔: 基础与应用[J]. 中国科学: 物理学力学天文学, 2012, 42(11): 1155-1175.

Zou C L, Dong C H, Cui J M. Whispering-gallery Mode Optical Microcavities: Fundamentals and Applications[J]. Science China Physics, Mechanics & Astronomy, 2012, 42(11): 1155-1175.

何塞林. 微纳光子集成[M]. 北京: 科学出版社, 2010.

Jose Capmany. Micro and Nano Photonics Integration[M]. Beijing: Science Press, 2010.

周权. 高Q值回音壁模式微腔传感器研究[D]. 南京: 南京邮电大学, 2021.

Zhou Q. Research on High Q Echo Wall Mode Microcavity Sensor[D]. Nanjing: Nanjing University of Posts and Telecommunications, 2021.

潘毓. 超高品质回音壁模式谐振器研究[D]. 杭州: 浙江大学, 2017.

Pan Y. Research on Ultra-high Q Whispering-gallery-mode Resonators[D]. Hangzhou: Zhejiang University, 2017.

Collot L, Lefevre-Seguin V, Brune M, et al. Very high-Q Whispering-gallery Mode Resonances Observed on Fused Silica Microspheres[J]. Europhysics Letters, 1993, 23(5): 327.

Shu F, Zou C, Sun F. Perpendicular Coupler for Whispering-gallery Resonators[J]. Optics Letters, 2012, 37(15): 3123-3125.

Laine J P, Little B E, Lim D R, et al. Microsphere Resonator Mode Characterization by Pedestal Anti-resonant Reflecting Waveguide Coupler[J]. IEEE Photonics Technology Letters, 2000, 12(8): 1004-1006.

Shi L, Zhu T, Huang D, et al. In-fiber Whispering-gallery-mode Resonator Fabricated by Femtosecond Laser Micromachining[J]. Optics Letters, 2015, 40(16): 3770-3773.

Wan H, Chen J, Wan C, et al. Optofluidic Microcapillary Biosensor for Label-free, Low Glucose Concentra-tion Detection[J]. Biomedical Optics Express, 2019, 10(8): 3929-3937.

Bo F, Wang J, Cui J, et al. Lithium-niobate–silica Hybrid Whispering-gallery-mode Resonators[J]. Advanced Materials, 2015, 27(48): 8075-8081.

Braginskii V B, Chenko V S. Properties of Optical Dielectric Microresonators[J]. Soviet Physics Doklady, 1987, 32: 306.

McCall S L, Levi A F J, Slusher R E, et al. Whispering-gallery Mode Microdisk Lasers[J]. Applied Phys-ics Letters, 1992, 60(3): 289-291.

Reitzenstein S, Heindel T, Kistner C, et al. Low Threshold Electrically Pumped Quantum Dot-micropillar Lasers[J]. Applied Physics Letters, 2008, 93(6): 061104.

Shitikov A E, Bilenko I A, Kondratiev N M, et al. Billion Q-factor in Silicon WGM Resonators[J]. Optica, 2018, 5(12): 1525-1528.

Pöllinger M, O’Shea D, Warken F, et al. Ultrahigh-Q Tunable Whispering-gallery-mode Microresonator[J]. Physical Review Letters, 2009, 103(5): 053901.

Fang Z, Chormaic S N, Wang S, et al. Bismuth-doped Glass Microsphere Lasers[J]. Photonics Research, 2017, 5(6): 740-744.

Grossmann T, Schleede S, Hauser M, et al. Direct Laser Writing for Active and Passive High-Q Polymer Microdiskson Silicon[J]. Optics Express, 2011, 19(12): 11451-11456.

Tu X, Chen S L, Song C, et al. Ultrahigh Q Polymer Microring Resonators for Biosensing Applications[J]. IEEE Photonics Journal, 2019, 11(2): 1-10.

王亚平, 王秀翃, 王璞. 回音壁模式光学微腔识别细胞类型[J]. 中国激光, 2020, 47(2): 0207028.

Wang Y P, Wang X H, Wang P. Identification of Cell Types Using Whispering Gallery Mode Optical Microcavities[J]. Chinese Journal of Lasers, 2020, 47(2): 0207028.

Garrett C G B, Kaiser W, Bond W L. Stimulated Emission into Optical Whispering Modes of Spheres[J]. Physical Review, 1961, 124(6): 1807.

Lin J, Yu S, Ma Y, et al. On-chip Three-dimensional High-Q Microcavities Fabricated by Femtosecond Laser Direct Writing[J]. Optics Express, 2012, 20(9): 10212-10217.

Liang W, Savchenkov A A, Matsko A B, et al. Generation of Near-infrared Frequency Combs from a MgF2 Whispering Gallery Mode Resonator[J]. Optics Letters, 2011, 36(12): 2290-2292.

Li Y H, Jiang X F, Zhao G M, et al. Whispering Gallery Mode Microresonator for Nonlinear Optics[J]. arXiv, 2018, 1809: 04878.

Kim E, Baaske M D, Vollmer F. Towards Next-generation Label-free Biosensors: Recent Advances in Whispering Gallery Mode Sensors[J]. Lab on a Chip, 2017, 17(7): 1190-1205.

Vollmer F, Braun D, Libchaber A, et al. Protein Detection by Optical Shift of a Resonant Microcavity[J]. Applied Physics Letters, 2002, 80(21): 4057-4059.

Zhi Y, Yu X C, Gong Q, et al. Single Nanoparticle Detection using Optical Microcavities[J]. Advanced Materials, 2017, 29(12): 1604920.

Vollmer F. Single Virus Detection from the Reactive Shift of a Whispering-gallery Mode[J]. Proceedings of the National Academy of Sciences, 2008, 105(52): 20701-20704.

Shao L, Jiang X F, Yu X C, et al. Detection of Single Nanoparticles and Lentiviruses using Microcavity Resonance Broadening[J]. Advanced Materials, 2013, 25(39): 5616-5620.

Dantham V R, Holler S, Barbre C, et al. Label-free Detection of Single Protein using a Nanoplasmonic-photonic Hybrid Microcavity[J]. Nano Letters, 2013, 13(7): 3347-3351.

Wang Y P, Wang X H, Wang P. Identifying Single Cell Types via Whispering Gallery Mode Optical Microcavities[J]. Chinese Journal of Lasers, 2020, 47(2): 0207028.

Wang Z, Liu Y, Gong C, et al. Liquid Crystal-amplified Optofluidic Biosensor for Ultra-highly Sensitive and Stable Protein Assay[J]. PhotoniX, 2021, 2(1): 1-16.

Nawrocka M S, Liu T, Wang X, et al. Tunable Silicon Microring Resonator with Wide Free Spectral Range[J]. Applied Physics Letters, 2006, 89(7): 071110.

Wu Y, Rao Y J, Chen Y, et al. Miniature Fiber-optic Temperature Sensors based on Silica/polymer Microfiber Knot Resonators[J]. Optics Express, 2009, 17(20): 18142-18147.

Muñoz-Hernandez T, Reyes-Vera E, Torres P. Temperature Sensor based on Whispering Gallery Modes of Metal-filled Side-hole Photonic Crystal Fiber Resonators[J]. IEEE Sensors Journal, 2020, 20(16): 9170-9178.

Liang L, Li M, Liu N, et al. A High-sensitivity Optical Fiber Relative Humidity Sensor based on Microsphere WGM Resonator[J]. Optical Fiber Technology, 2018, 45: 415-418.

Liu W, Li W, Wang R, et al. Magnetic Sensor based on WGM Hollow Microbubble Resonator Filled with Magnetic Fluid[J]. Optics Communications, 2021, 497: 127148.

Yacoby E, London Y, Meshorer Y, et al. Whispering Gallery Modes Silica Resonators: A Platform for Optical Sensing[J]. Optics & Laser Technology, 2022, 151(108019): 181-188.

Johari M A M, Jali M H B, Yusof H H B M, et al. Polyvinyl Alcohol Coating Microbottle Resonator on Whispering Gallery Modes for Ethanol Liquid Sensor[J]. Optics & Laser Technology, 2021, 143: 107379.

周权, 陈瑶, 韩丰恺, 等. 高Q值薄壁液芯毛细管微腔电场传感器[J]. 光子学报, 2020, 49(2): 0223002.

Zhou Q, Chen Y, Han F K, et al. High-Q Thin-walled Liquid-core Capillary Microcavity Electric Field Sensor[J]. Acta Photonica Sinica, 2020, 49(2): 0223002.

Li G H, Zhou B L, Hou Z, et al. Transfer Printing of Perovskite Whispering Gallery Mode Laser Cavities by Thermal Release Tape[J]. Nanoscale Research Letters, 2022, 17(1): 1-7.

Savchenkov A A, Ilchenko V S, Matsko A B, et al. Tunable Filter based on Whispering Gallery Modes[J]. Electronics Letters, 2003, 39(4): 389-391.

Pandit N, Jaiswal R K, Pathak N P. Microwave Multi-Bandnotch Filter using Spoof Surface Whispering Gallery Mode (SS-WGM) Resonator[C]//2021 IEEE MTT-S International Microwave and RF Conference (IMARC). KANPUR, India: IEEE, 2021: 1-3.

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