A computationally efficient method for simulating metal-nanowire dipole antennas at infrared and longer visible wavelengths

Mario Fernández Pantoja; Matthew G. Bray; Douglas H. Werner; Pingjuan L. Werner; Amelia Rubio Bretones

doi:10.1109/TNANO.2011.2117438

A computationally efficient method for simulating metal-nanowire dipole antennas at infrared and longer visible wavelengths

Mario Fernández Pantoja
, Matthew G. Bray
, Douglas H. Werner
, Pingjuan L. Werner
, Amelia Rubio Bretones

Research output: Contribution to journal › Article › peer-review

7 Scopus citations

Abstract

This paper presents a numerically efficient approach for simulating nanowires at infrared and long optical wavelengths. A computationally efficient circuit-equivalent modeling approach based on the electric-field integral-equation (EFIE) formulation is employed to simulate the highly dispersive behavior of nanowires at short wavelengths. The proposed approach can be used both for frequency-domain and for time-domain EFIE formulations. In comparison with widely used full-wave solutions achieved through the finite-difference time-domain method, the circuit-based EFIE formulation results in a sharp reduction of the computational resources while retaining high accuracy.

Original language	English (US)
Article number	5716676
Pages (from-to)	239-246
Number of pages	8
Journal	IEEE Transactions on Nanotechnology
Volume	11
Issue number	2
DOIs	https://doi.org/10.1109/TNANO.2011.2117438
State	Published - Mar 2012

All Science Journal Classification (ASJC) codes

Computer Science Applications
Electrical and Electronic Engineering

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10.1109/TNANO.2011.2117438

Cite this

@article{aed1808f9e3143b8b27c4e372c6620a0,

title = "A computationally efficient method for simulating metal-nanowire dipole antennas at infrared and longer visible wavelengths",

abstract = "This paper presents a numerically efficient approach for simulating nanowires at infrared and long optical wavelengths. A computationally efficient circuit-equivalent modeling approach based on the electric-field integral-equation (EFIE) formulation is employed to simulate the highly dispersive behavior of nanowires at short wavelengths. The proposed approach can be used both for frequency-domain and for time-domain EFIE formulations. In comparison with widely used full-wave solutions achieved through the finite-difference time-domain method, the circuit-based EFIE formulation results in a sharp reduction of the computational resources while retaining high accuracy.",

author = "Pantoja, \{Mario Fern{\'a}ndez\} and Bray, \{Matthew G.\} and Werner, \{Douglas H.\} and Werner, \{Pingjuan L.\} and Bretones, \{Amelia Rubio\}",

note = "Funding Information: Manuscript received April 5, 2010; revised December 13, 2010; accepted February 8, 2011. Date of publication February 22, 2011; date of current version March 9, 2012. This work was supported in part by the Spanish Ministry of Education under Project PR2009-0443, in part by the Penn State MRSEC under NSF Grant 0213623, in part by the EU FP7/2007-2013 under Grant GA 205294 (HIRF SE project), in part by the Spanish National Projects TEC2010-20841-C04-04, CSD200800068, and DEX-5300002008105, and in part by the Junta de Andalucia Project P09-TIC5327. The review of this paper was arranged by Associate Editor C. Zhou.",

year = "2012",

month = mar,

doi = "10.1109/TNANO.2011.2117438",

language = "English (US)",

volume = "11",

pages = "239--246",

journal = "IEEE Transactions on Nanotechnology",

issn = "1536-125X",

publisher = "Institute of Electrical and Electronics Engineers Inc.",

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AU - Pantoja, Mario Fernández

AU - Bray, Matthew G.

AU - Werner, Douglas H.

AU - Werner, Pingjuan L.

AU - Bretones, Amelia Rubio

N1 - Funding Information: Manuscript received April 5, 2010; revised December 13, 2010; accepted February 8, 2011. Date of publication February 22, 2011; date of current version March 9, 2012. This work was supported in part by the Spanish Ministry of Education under Project PR2009-0443, in part by the Penn State MRSEC under NSF Grant 0213623, in part by the EU FP7/2007-2013 under Grant GA 205294 (HIRF SE project), in part by the Spanish National Projects TEC2010-20841-C04-04, CSD200800068, and DEX-5300002008105, and in part by the Junta de Andalucia Project P09-TIC5327. The review of this paper was arranged by Associate Editor C. Zhou.

PY - 2012/3

Y1 - 2012/3

N2 - This paper presents a numerically efficient approach for simulating nanowires at infrared and long optical wavelengths. A computationally efficient circuit-equivalent modeling approach based on the electric-field integral-equation (EFIE) formulation is employed to simulate the highly dispersive behavior of nanowires at short wavelengths. The proposed approach can be used both for frequency-domain and for time-domain EFIE formulations. In comparison with widely used full-wave solutions achieved through the finite-difference time-domain method, the circuit-based EFIE formulation results in a sharp reduction of the computational resources while retaining high accuracy.

AB - This paper presents a numerically efficient approach for simulating nanowires at infrared and long optical wavelengths. A computationally efficient circuit-equivalent modeling approach based on the electric-field integral-equation (EFIE) formulation is employed to simulate the highly dispersive behavior of nanowires at short wavelengths. The proposed approach can be used both for frequency-domain and for time-domain EFIE formulations. In comparison with widely used full-wave solutions achieved through the finite-difference time-domain method, the circuit-based EFIE formulation results in a sharp reduction of the computational resources while retaining high accuracy.

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JF - IEEE Transactions on Nanotechnology

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ER -

A computationally efficient method for simulating metal-nanowire dipole antennas at infrared and longer visible wavelengths

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