Plasmon spectroscopy: Theoretical and numerical calculations, and optimization techniques

Nanospectroscopy Pub Date : 2016-02-02 DOI:10.1515/nansp-2015-0006

R. Rodríguez-Oliveros, R. Paniagua‐Domínguez, J. Sánchez-gil, D. Macías

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引用次数: 9

Abstract

Abstract We present an overview of recent advances in plasmonics, mainly concerning theoretical and numerical tools required for the rigorous determination of the spectral properties of complex-shape nanoparticles exhibiting strong localized surface plasmon resonances (LSPRs). Both quasistatic approaches and full electrodynamic methods are described, providing a thorough comparison of their numerical implementations. Special attention is paid to surface integral equation formulations, giving examples of their performance in complicated nanoparticle shapes of interest for their LSPR spectra. In this regard, complex (single) nanoparticle configurations (nanocrosses and nanorods) yield a hierarchy of multiple-order LSPR s with evidence of a rich symmetric or asymmetric (Fano-like) LSPR line shapes. In addition, means to address the design of complex geometries to retrieve LSPR spectra are commented on, with special interest in biologically inspired algorithms. Thewealth of LSPRbased applications are discussed in two choice examples, single-nanoparticle surface-enhanced Raman scattering (SERS) and optical heating, and multifrequency nanoantennas for fluorescence and nonlinear optics.

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等离子体光谱学:理论和数值计算，以及优化技术

摘要:本文综述了等离子体动力学的最新进展，主要涉及理论和数值工具，以严格确定具有强局域表面等离子体共振(LSPRs)的复杂形状纳米颗粒的光谱特性。描述了准静态方法和全电动力学方法，并对它们的数值实现进行了全面的比较。特别注意了表面积分方程公式，给出了它们在复杂纳米颗粒形状中的性能示例，以获得它们的LSPR光谱。在这方面，复杂的(单)纳米粒子结构(纳米交叉和纳米棒)产生多级LSPR的层次结构，并具有丰富的对称或不对称(法诺样)LSPR线形的证据。此外，还讨论了用于检索LSPR光谱的复杂几何形状的设计方法，并对生物启发算法特别感兴趣。本文以单纳米粒子表面增强拉曼散射(SERS)和光学加热以及荧光和非线性光学的多频纳米天线为例，讨论了基于lsprr的丰富应用。

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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