基于纳米空腔阵列结构的可调谐等离子镊子,用于多点纳米级粒子捕获

Xiaoya Yan, Hongyan Shi, Pengxue Jia, Xiudong Sun
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引用次数: 0

摘要

基于金属纳米结构的等离子体光镊能够在低激光功率下稳定捕获和动态操控纳米级物体,已被广泛应用于纳米技术和生命科学领域。特别是其等离子纳米腔结构可以通过将电磁场限制在亚波长体积内来提高局部场强和捕获深度。本文利用 Ag@Polydimethylsiloxane 纳米空腔阵列结构成功捕获了 10-6 M 的 R6G 染料分子,并在质子光学力和热泳的共同作用下形成了 R6G 微环。随后的理论研究表明,通过改变锥形纳米空腔单元的结构参数,可以灵活调节其捕获性能,当空腔深度为 140 nm 时,它能为 RNP = 14 nm 的聚苯乙烯粒子提供一个稳定的势阱。此外,通过研究六角锥形纳米腔阵列结构的捕获特性,还发现在激光照射区域内可以同时激活多个捕获位点。这种多点稳定捕获平台使同时分析多个目标粒子成为可能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Tunable plasmonic tweezers based on nanocavity array structure for multi-site nanoscale particles trapping
The ability of plasmonic optical tweezers based on metal nanostructure to stably trap and dynamically manipulate nanoscale objects at low laser power has been widely used in the fields of nanotechnology and life sciences. In particular, their plasmonic nanocavity structure can improve the local field intensity and trap depth by confining electromagnetic fields to subwavelength volumes. In this paper, the R6G dye molecules with 10−6 M were successfully trapped by using the Ag@Polydimethylsiloxane nanocavity array structure, and a R6G micro-ring was formed under the combined action of plasmonic optical force and thermophoresis. Subsequently, the theoretical investigation revealed that the trapping performance can be flexibly adjusted by changing the structural parameters of the conical nanocavity unit, and it can provide a stable potential well for polystyrene particles of RNP = 14 nm when the cavity depth is 140 nm. In addition, it is found that multiple trapping sites can be activated simultaneously in the laser irradiation area by investigating the trapping properties of the hexagonal conical nanocavity array structure. This multi-site stable trapping platform makes it possible to analyze multiple target particles contemporaneously.
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