Title : ( Application of circuit model for gap-plasmon nanodisk resonators )
Authors: morteza dareini , Shaban Reza Ghorbani , Hadi Arabi , Daqiqeh Rezaei Soroosh ,Abstract
The design of plasmonic metasurfaces is often based on solving the Maxwell electromagnetic equations, which can be a time-consuming and expensive process considering many geometrical parameters that can limit design flexibility. To speed up the design flow, a model based on the classical transmission line theory is presented. The proposed equivalent circuit model can predict the plasmon resonance wavelength based on various geometrical parameters including dielectric thickness and disk diameter. In addition, unlike other reported circuit models, the developed model considers the nanostructure array pitch size, which is crucial in metasurface design. Comparison between the results obtained from circuit model and full wavelength simulation showed that the circuit parameters accurately determine the response of the structure. Finally, as a metasurface design demonstration, we utilized our model to simulate aluminum-based gap-plasmon nanodisk arrays for optimizing their optical response to maximize structural color saturation.
Keywords
Nanostructure; Plasmonic metasurfaces; Resonant frequency; Circuit model@article{paperid:1099149,
author = {Dareini, Morteza and Ghorbani, Shaban Reza and Arabi, Hadi and سروش دقیقه رضایی},
title = {Application of circuit model for gap-plasmon nanodisk resonators},
journal = {Photonics and Nanostructures-Fundamentals and Applications},
year = {2024},
volume = {60},
month = {July},
issn = {1569-4410},
pages = {101264--1},
numpages = {-101263},
keywords = {Nanostructure; Plasmonic metasurfaces; Resonant frequency; Circuit model},
}
%0 Journal Article
%T Application of circuit model for gap-plasmon nanodisk resonators
%A Dareini, Morteza
%A Ghorbani, Shaban Reza
%A Arabi, Hadi
%A سروش دقیقه رضایی
%J Photonics and Nanostructures-Fundamentals and Applications
%@ 1569-4410
%D 2024