Semianalytical approach to study the loss characteristics of a symmetrical multilayered plasmonic waveguide

Bapita Roy; Rajib Chakraborty

doi:10.1364/AO.55.001765

Applied Optics
Vol. 55,
Issue 7,
pp. 1765-1771
(2016)
•https://doi.org/10.1364/AO.55.001765

Semianalytical approach to study the loss characteristics of a symmetrical multilayered plasmonic waveguide

Bapita Roy and Rajib Chakraborty

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Bapita Roy and Rajib Chakraborty, "Semianalytical approach to study the loss characteristics of a symmetrical multilayered plasmonic waveguide," Appl. Opt. 55, 1765-1771 (2016)

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Abstract

A metal waveguide of finite width and thickness surrounded by a dielectric provides increased propagation length of the surface plasmon polariton and is therefore called long-range surface plasmon polaritons (LR-SPP). In this work, a new structure is proposed by modifying the refractive index of the dielectric surrounding the metal waveguide, leading to further improvement of the propagation length. It is shown that, when the single dielectric surrounding is replaced by a multilayered surrounding where each layer has different thicknesses and refractive index, the propagation loss gets reduced, leading to increased propagation length of the LR-SPP. The propagation loss is calculated semianalytically from the FWHM of the Lorentzian peak obtained in the plot of excitation efficiency of such waveguide for different values of the propagation constant. Before doing this calculation, the 2D variation of refractive index is first converted into a 1D effective refractive index. All the steps of analysis are discussed in detail, and, wherever necessary, the calculated results are matched with similar results of other researchers.

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Thickness ( $t$ ) of the Metal Stripe (nm)	Mode Effective Refractive Index ( $N_{eff}$ )
10	$1.4809 + 1.4834 i$
40	$1.4883 + 1.4957 i$
80	$1.5006 + 1.5016 i$
100	$1.5056 + 1.5031 i$
200	$1.5056 + 1.5060 i$

Thickness ( $t$ ) of the Gold WG (nm)	Width ( $w$ ) of the Gold Stripe (nm)	Thickness ( $d$ ) of the Polymer (nm)	Complex Propagation Constant of the Waveguide
Thickness ( $t$ ) of the Gold WG (nm)	Width ( $w$ ) of the Gold Stripe (nm)	Thickness ( $d$ ) of the Polymer (nm)	$β_{real}$	$β_{imag}$ (FWHM)
10	10	60	1.557045	0.011081
	20		1.564409	0.011755
	30		1.571263	0.028737
40	10		1.560996	0.016639
	20		1.568106	0.00328
	30		1.572854	0.021538
80	10		1.571954	0.021493
	20		1.578085	0.0030323
	30		1.581532	0.031263

	Propagation Loss (in dB) of the Metal Waveguide with a Overlay of
	Graph I	Graph II	Graph III	Graph IV
Gold WG Thickness (nm)	Single Layer of BCB Cladding	Successive layers of a Dielectric of r.i. 1.488 and BCB	Successive Layers of Dielectric of r.i. 1.4, 1.488 and BCB	Successive Layers of Dielectric of r.i. 1.34, 1.4, 1.488 and BCB
10	6.944	1.95	1.302	0.9
20	13.02	11.28	3.906	1.953
30	52.08	21.06	10.85	8.68
40	75.95	22.7	15.87	9.75

Thickness ( $t$ ) of the Metal Stripe (nm)	Mode Effective Refractive Index ( $N_{eff}$ )
10	$1.4809 + 1.4834 i$
40	$1.4883 + 1.4957 i$
80	$1.5006 + 1.5016 i$
100	$1.5056 + 1.5031 i$
200	$1.5056 + 1.5060 i$

Thickness ( $t$ ) of the Gold WG (nm)	Width ( $w$ ) of the Gold Stripe (nm)	Thickness ( $d$ ) of the Polymer (nm)	Complex Propagation Constant of the Waveguide
Thickness ( $t$ ) of the Gold WG (nm)	Width ( $w$ ) of the Gold Stripe (nm)	Thickness ( $d$ ) of the Polymer (nm)	$β_{real}$	$β_{imag}$ (FWHM)
10	10	60	1.557045	0.011081
	20		1.564409	0.011755
	30		1.571263	0.028737
40	10		1.560996	0.016639
	20		1.568106	0.00328
	30		1.572854	0.021538
80	10		1.571954	0.021493
	20		1.578085	0.0030323
	30		1.581532	0.031263

Abstract

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Figures (7)

Tables (3)

Equations (6)

Applied Optics