金属等离子激元调控Fabry-Perot微腔谐振模式研究 -

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金属等离子激元调控Fabry-Perot微腔谐振模式研究

doi:10.3788/CO.20191203.0649

长春理工大学高功率半导体国家重点实验室, 吉林长春 130022

基金项目:

国家自然基金青年基金项目21707010

吉林省优秀青年基金20180520194JH

长春理工大学创新基金项目XJJLG-2016-07

详细信息

作者简介:
马光辉(1992-), 男, 陕西渭南人, 硕士研究生, 2016年于长春理工大学光电信息学院获得学士学位, 主要从事光电子技术及应用方面的研究。E-mail:553761365@qq.com
徐英添(1986-), 男, 吉林长春人, 硕士生导师, 副研究员, 2008年于长春理工大学获得学士学位, 2014年于吉林大学获得博士学位, 主要从事光电子技术及应用方面的研究。E-mail:xyt@cust.edu.cn

中图分类号:O437
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出版历程
- 收稿日期:2018-05-11
- 修回日期:2018-07-05
- 刊出日期:2019-06-01

Resonant mode of Fabry-Perot microcavity regulated by metal surface plasmons

State Key Laboratory on High Power Semiconductor Lasers, Changchun University of Science and Technology, Changchun 130022, China

Funds:

National Natural Foundation-Youth Foundation Project21707010

the Excellent Youth Foundation of Jilin Province20180520194JH

Changchun University of Science and Technology Innovation Foundation ProjectXJJLG-2016-07

More Information

Corresponding author:XU Ying-tian, E-mail:xyt@cust.edu.cn

摘要

摘要:目前，利用氧化锌（ZnO）微纳米线结构形成具有自然谐振腔的紫外器件引起国内外广泛关注。针对ZnO本征缺陷导致器件发光及稳定性不足等问题，开展金属局域等离子激元局域场发光增强方面的研究，对ZnO基紫外器件的应用具有十分重要的意义。本文通过理论仿真构建氧化锌微米线结构模型，对微腔光学损耗及Fabry-Perot（F-P）谐振腔模式演化进行了理论分析。得到ZnO微腔直径变化与F-P谐振模式演化、光学损耗和光强分布的关系。在此基础上通过金属Ag纳米颗粒对ZnO微米线6个表面进行修饰，发现金属局域表面等离子激元共振耦合效应对微腔周围的损耗光有明显的抑制作用，并且在金属与微腔的交叉区通过共振耦合效应实现局域场增强。模拟结果表明，在损耗较大的微腔表面修饰Ag纳米颗粒以后，光场限域能力提高6.72%，而在金属颗粒之间沿 X轴方向产生二次耦合现象，其电场强度更有2倍的增强效果。
- F-P谐振腔/
- 金属局域表面等离子激元/
- 光学损耗/
- 局域场增强
Abstract:At present, the use of zinc oxide(ZnO) micro-nanowire structures in ultraviolet laser devices with natural resonant cavities has attracted wide attention at home and abroad. Aiming at the problems of the luminescence and stability caused by ZnO intrinsic defects, research on the local field luminescence enhancement of plasmons is very important for the application of ZnO-based UV laser devices. In this paper, ZnO micro-wire structure model is constructed by theoretical simulation and the micro-cavity optical loss and Fabry-Perot(F-P) resonant cavity mode evolution are theoretically analyzed. The relationship between the diameter change of ZnO microcavity and the evolution of the F-P resonance mode, optical loss and light intensity distribution is obtained. On this basis, the six surfaces of ZnO microwires are modified by metal Ag nanoparticles. It is found that the resonance coupling effect of metal local surface plasmons significantly inhibited the loss of light around the microcavity and the local field enhancement is realized by the resonance coupling effect at the intersection of the metal and the microcavity. The simulation results show that after the surface of the microcavity is modified with Ag nanoparticles, the confinement ability of the optical field increased by 6.72%, while the secondary coupling occurs along the X axis between the metal particles, and the electric field intensity is enhanced by 2 times.
- F-P resonator/
- metal local surface plasmons/
- optical loss/
- local field enhancement

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图 1(a) 类F-P 腔结构示意图；(b) 在ZnO微腔中传播的示意图

Figure 1.(a)Structure diagram of an F-P laser cavity; (b)schematic diagram of laser propagation in ZnO microcavity

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图 2(a) 局域表面等离子激元振荡图；(b)传播表面等离子激元图

Figure 2.(a)Localized surface plasmon oscillations; (b)spread surface plasmon

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图 3不同直径时的(x,y)，(x,z)面电场分布图

Figure 3.The electric field distributions of (x,y), (x,z) planes of the ZnO micro-wires with different diameters

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图 4(a) 不同腔径对应的光强曲线；(b)随腔径变化的光限制效率图

Figure 4.(a)Light intensity curves corresponding to different cavity diameters; (b)light-confinement efficiency varies with cavity diameter

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图 5不同直径时的ZnO F-P 腔共振谱图

Figure 5.ZnO F-P laser resonant spectra with different diameters

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图 6Ag纳米颗粒修饰的LSPR微腔的模拟示意图和对应电场分布

Figure 6.Simulation diagram of LSPR microcavity modified by Ag nanoparticles and corresponding electric field distributions

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图 7Ag纳米颗粒修饰微腔的电场强度分布图

Figure 7.Distribution of the electric field intensity of the Ag nanoparticle modified microcavity

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图 8Ag纳米颗粒装饰ZnO微米线的局部电场图

Figure 8.Local electric field diagrams of Ag nanoparticle modified ZnO microwire

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图 9(a) 随装饰面数目变化的光强曲线；(b)随装饰面数目变化的光限制效率图

Figure 9.(a)Light intensity curve as a function of the number of decorative surface; (b)light confinement efficiency map as a function of the number of decorative surfaces

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图 10D=2时无Ag颗粒装饰和有Ag颗粒装饰时ZnO微腔的谐振谱图

Figure 10.Resonance spectra of ZnO microcavity without and with Ag particle decoration whenD=2

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