Integrated plasmonic double bowtie / ring grating structure for enhanced electric field confinement

Nanospectroscopy Pub Date : 2015-08-28 DOI:10.1515/nansp-2015-0005

N. Rahbany, W. Geng, S. Blaize, R. Salas-Montiel, R. Bachelot, C. Couteau

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引用次数: 6

Abstract

Abstract Metallic nanoparticles and nanoantennas have been extensively studied due to their capability to increase electromagnetic field confinement which is essential in numerous applications ranging from optoelectronics to telecommunication and sensing devices. We show that a double bowtie nanoantenna has a higher electric field confinement in its gap compared to a single bowtie nanoantenna, which is expected to give better fluorescence enhancement of a single emitter placed in the gap. We show that the electric field intensity can be further increased by placing the double bowtie inside a ring grating structure where the excitation of surface plasmon-polaritons (SPPs) is achieved. We perform FDTD simulations to characterise the double bowtie nanoantenna and study the effect of its dimensions on the electric field enhancement in the gap. Our proposed integrated structure with gratings is shown to increase the electric field by a factor of 77 due to a double cavity effect. Next steps would be to study the fluorescence enhancement of emitters placed inside our double bowtie / ring grating nanocavity to see if the strong coupling regime can be attained.

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用于增强电场约束的集成等离子体双领结/环形光栅结构

金属纳米粒子和纳米天线由于其增强电磁场约束的能力而被广泛研究，这在从光电子到电信和传感设备的许多应用中都是必不可少的。我们表明，双领结纳米天线在其间隙中具有比单领结纳米天线更高的电场约束，这有望为放置在间隙中的单个发射器提供更好的荧光增强。我们表明，通过将双领结放置在环形光栅结构中，可以进一步增加电场强度，从而实现表面等离子激元(SPPs)的激发。我们进行时域有限差分模拟来表征双领结纳米天线，并研究其尺寸对间隙电场增强的影响。由于双腔效应，我们提出的带有光栅的集成结构将电场增加了77倍。下一步将是研究放置在双领结/环形光栅纳米腔内的发射器的荧光增强，看看是否可以达到强耦合状态。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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Nanospectroscopy

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