Saemisch Lisa, van Hulst Niek F, Liebel Matz
ICFO-Institut de Ciencies Fotoniques, The Barcelona Institute of Science and Technology, 08860 Castelldefels, Barcelona, Spain.
ICREA-Institució Catalana de Recerca i Estudis Avançats, 08010 Barcelona, Spain.
Nano Lett. 2021 May 12;21(9):4021-4028. doi: 10.1021/acs.nanolett.1c00866. Epub 2021 Apr 26.
Nanoscale phase control is one of the most powerful approaches to specifically tailor electrical fields in modern nanophotonics. Especially the precise subwavelength assembly of many individual nanobuilding blocks has given rise to exciting new materials as diverse as metamaterials, for miniaturizing optics, or 3D assembled plasmonic structures for biosensing applications. Despite its fundamental importance, the phase response of individual nanostructures is experimentally extremely challenging to visualize. Here, we address this shortcoming and measure the quantitative scattering phase of different nanomaterials such as gold nanorods and spheres as well as dielectric nanoparticles. Beyond reporting spectrally resolved responses, with phase changes close to π when passing the particles' plasmon resonance, we devise a simple method for distinguishing different plasmonic and dielectric particles purely based on their phase behavior. Finally, we integrate this novel approach in a single-shot two-color scheme, capable of directly identifying different types of nanoparticles on one sample, from a single widefield image.
纳米尺度的相位控制是现代纳米光子学中专门定制电场的最有效方法之一。特别是许多单个纳米构建块的精确亚波长组装已经产生了令人兴奋的新材料,如用于光学小型化的超材料,或用于生物传感应用的三维组装等离子体结构。尽管其具有根本重要性,但单个纳米结构的相位响应在实验上极难可视化。在此,我们解决了这一缺点,并测量了不同纳米材料(如金纳米棒、金纳米球以及介电纳米颗粒)的定量散射相位。除了报告光谱分辨响应,当通过粒子的等离子体共振时相位变化接近π,我们设计了一种简单方法,仅基于它们的相位行为来区分不同的等离子体和介电粒子。最后,我们将这种新方法集成到单次双色方案中,能够从单个宽视场图像直接识别一个样品上不同类型的纳米颗粒。
