Yatao Yang, Yongxian Yan, Yifan Wang, Wei-Wei Cheng, Qiancheng Zhao, Yi Li
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引用次数: 0
摘要
我们提出了一种用于增强单分子荧光的全介电(磷化镓,GaP)纳米天线设计。开槽的 GaP 纳米盘具有很强的散射和有限的光学损耗,从而在共振位置实现了 30 倍以上的激发增强增长。我们提出的方案还能精确操纵光学态的局部密度,使单个染料的量子产率提高了近一个数量级(原始量子产率为 0.01),发射增强了 12 倍。我们对四种商用染料颜色(原始量子产率为 0.3)的整体荧光增强效果进行了基准测试,并在模拟中实现了比商用零模波导(ZMW)高一个数量级的增强。我们基于 GaP 的设计不仅为下一代 DNA 和蛋白质测序芯片提供了解决方案,还有助于单实体相互作用、便携式荧光检测以及量子光源集成器件。
We propose a design for all-dielectric (gallium phosphide, GaP) nanoantenna to enhance single molecule fluorescence. The slotted GaP nanodisk exhibits strong scattering and limited optical loss, resulting in more than 30× excitation enhancement growth at the resonance position. Our proposed scheme also enables precise manipulation of the local density of optical states, leading to a nearly one order of magnitude increments in quantum yield for individual dye (original quantum yield is 0.01) and 12× emission enhancement. We benchmark the overall fluorescent enhancement for the four commercial dye colors (original quantum yield is 0.3) and achieved one-order of enhancement higher than commercialized zero-mode waveguide (ZMW) in the simulation. Our GaP-based design not only provides a solution for next-generation chips for DNA and protein sequencing, but also contributes to single-entity interactions, portable fluorescence detection, and integrated devices with quantum light sources.
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