用于共振纳米光子离子生产的定制硅纳米柱阵列

Bennett N. Walker, Jessica A. Stolee, Deanna L. Pickel, S. Retterer, A. Vertes
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引用次数: 75

摘要

尺寸与电磁辐射波长相称的纳米结构表现出近场效应,并且作为光学天线,可以将激光辐射耦合到局部环境。激光诱导的硅微柱阵列表现为纳米光子离子源,可以通过旋转光偏振面来调制。然而,这些基质的表面形态范围有限,使得研究控制离子产生的潜在机制变得困难。在这里,我们证明纳米柱阵列(NAPAs)可以被定制以显示共振离子的产生。具有亚波长直径的柱的离子产率在高长宽比下显示出尖锐的共振。离子强度的共振增强可以通过调整周期来调节。除了强分子离子形成外,还观察到高能碎片通道的存在。在p偏振和s偏振激光束中,NAPAs的离子产额表现出显著的差异,表明能量…
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Tailored Silicon Nanopost Arrays for Resonant Nanophotonic Ion Production
Nanostructures that have dimensions commensurate with the wavelength of the electromagnetic radiation exhibit near-field effects and, as optical antennas, can couple laser radiation to the local environment. Laser-induced silicon microcolumn arrays behave as nanophotonic ion sources that can be modulated by rotating the plane of light polarization. However, the limited range of surface morphologies available for these substrates makes it difficult to study the underlying mechanism that governs ion production. Here we demonstrate that nanopost arrays (NAPAs) can be tailored to exhibit resonant ion production. Ion yields from posts with subwavelength diameter show sharp resonances at high aspect ratios. The resonant enhancement in ion intensities can be modulated by adjusting the periodicity. In addition to strong molecular ion formation, the presence of high-energy fragmentation channels is observed. Ion yields from NAPAs exhibit dramatic differences for p- and s-polarized laser beams, indicating that ener...
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