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Auteurs principaux: Huang, Cheng-ping, Yin, Xiao-gang
Format: Preprint
Publié: 2022
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Accès en ligne:https://arxiv.org/abs/2205.00912
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author Huang, Cheng-ping
Yin, Xiao-gang
author_facet Huang, Cheng-ping
Yin, Xiao-gang
contents It is well known that the optical properties of spherical metal particles can be described with the Rayleigh approximation or rigorous Mie theory. But for the single metallic nanorods, a theory well capturing the fundamental resonance and scattering features is still absent. In this study, an analytical model is developed for the metallic nanorod, considering the longitudinally non-uniform conduction current and surface charges. With the circuit parameters deduced from the kinetic and electromagnetic energy of the nanorod, a formula which agrees well with the simulations has been suggested for the resonance wavelength of the fundamental longitudinal mode. Moreover, by introducing the radiative resistance to the circuit theory, the dipole moment, extinction spectrum, and near-field enhancement of the nanorod have been derived analytically and confirmed numerically. The results are important for understanding the optical properties of the metallic nanorods and provide a guideline for designing the light scattering and absorption.
format Preprint
id arxiv_https___arxiv_org_abs_2205_00912
institution arXiv
publishDate 2022
record_format arxiv
spellingShingle Optical properties of single metal nanorods: An analytical model
Huang, Cheng-ping
Yin, Xiao-gang
Optics
It is well known that the optical properties of spherical metal particles can be described with the Rayleigh approximation or rigorous Mie theory. But for the single metallic nanorods, a theory well capturing the fundamental resonance and scattering features is still absent. In this study, an analytical model is developed for the metallic nanorod, considering the longitudinally non-uniform conduction current and surface charges. With the circuit parameters deduced from the kinetic and electromagnetic energy of the nanorod, a formula which agrees well with the simulations has been suggested for the resonance wavelength of the fundamental longitudinal mode. Moreover, by introducing the radiative resistance to the circuit theory, the dipole moment, extinction spectrum, and near-field enhancement of the nanorod have been derived analytically and confirmed numerically. The results are important for understanding the optical properties of the metallic nanorods and provide a guideline for designing the light scattering and absorption.
title Optical properties of single metal nanorods: An analytical model
topic Optics
url https://arxiv.org/abs/2205.00912