Improved particle swarm optimization algorithm for high performance SPR
sensor design

Lei Han; Chaoyu Xu; Tianye Huang; Xueyan Dang

doi:10.1364/AO.417015

Applied Optics
Vol. 60,
Issue 6,
pp. 1753-1760
(2021)
•https://doi.org/10.1364/AO.417015

Improved particle swarm optimization algorithm for high performance SPR sensor design

Lei Han, Chaoyu Xu, Tianye Huang, and Xueyan Dang

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Lei Han, Chaoyu Xu, Tianye Huang, and Xueyan Dang, "Improved particle swarm optimization algorithm for high performance SPR sensor design," Appl. Opt. 60, 1753-1760 (2021)

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Abstract

The surface plasmon resonance (SPR) sensor offers high sensitivity, good stability, simple structure, and is label-free. However, optimizing a multi-layered structure is quite time-consuming within the SPR sensor design process. Moreover, it is easy to overlook optimal design when using the conventional parameter sweeping method. In this paper, the improved particle swarm optimization (IPSO) algorithm with high global optimal solution convergence speed is applied for this purpose. Based on the IPSO algorithm, the SPR sensor with transition metal dichalcogenides (TMDCs) and graphene composite is proposed and optimized. The results show that the best Ag-ITO-${\rm WS}_2$-graphene hybrid structure can be found by the IPSO algorithm, and the maximum sensitivity is 137.4°/RIU, and the figure of merit (FOM) is $5.25\;{{\rm RIU}^{- 1}}$. Compared with the standard particle swarm optimization algorithm, the number of iterations can be reduced. The development of the SPR sensor provides an optimization platform, which enormously improves the development efficiency of the multi-layer SPR sensor.

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Type of TMDCs	Monolayer (nm)	RI
${M o S e}_{2}$	0.70	$4.6226 + 1.0063 i$
${M o S}_{2}$	0.65	$5.0805 + 1.1723 i$
${W S}_{2}$	0.80	$4.8937 + 0.3124 i$
${W S e}_{2}$	0.70	$4.5501 + 0.4332 i$
Graphene	0.34	$3.0000 + 1.1491 i$

Hybrid Structure	Ag (nm)	ITO (nm)	TMDC (N)	Graphene (L)	$S$ (°/RIU)	FOM ( ${R I U}^{- 1}$ )	Iterations (times)
Ag-ITO- ${W S}_{2}$ -graphene	64	1	10	3	137.4	5.21	7
Ag-ITO- ${M o S}_{2}$ -graphene	79	1	8	9	137.4	4.52	6
Ag-ITO- ${M o S e}_{2}$ -graphene	54	1	10	10	115.4	3.61	24
Ag-ITO- ${W S e}_{2}$ -graphene	70	2	10	10	119.8	4.27	11

Hybrid Structure	Ag (nm)	ITO (nm)	TMDC (N)	Graphene (L)	$S$ (°/RIU)	FOM ( ${R I U}^{- 1}$ )	Iterations (times)
Ag-ITO- ${W S}_{2}$ -graphene	66	1	10	3	137.4	5.25	5
Ag-ITO- ${M o S}_{2}$ -graphene	79	1	8	9	137.4	4.52	4
Ag-ITO- ${M o S e}_{2}$ -graphene	80	1	9	8	132.8	4.43	5
Ag-ITO- ${W S e}_{2}$ -graphene	70	2	10	10	119.8	4.27	6

Type of TMDCs	Monolayer (nm)	RI
${M o S e}_{2}$	0.70	$4.6226 + 1.0063 i$
${M o S}_{2}$	0.65	$5.0805 + 1.1723 i$
${W S}_{2}$	0.80	$4.8937 + 0.3124 i$
${W S e}_{2}$	0.70	$4.5501 + 0.4332 i$
Graphene	0.34	$3.0000 + 1.1491 i$

Hybrid Structure	Ag (nm)	ITO (nm)	TMDC (N)	Graphene (L)	$S$ (°/RIU)	FOM ( ${R I U}^{- 1}$ )	Iterations (times)
Ag-ITO- ${W S}_{2}$ -graphene	64	1	10	3	137.4	5.21	7
Ag-ITO- ${M o S}_{2}$ -graphene	79	1	8	9	137.4	4.52	6
Ag-ITO- ${M o S e}_{2}$ -graphene	54	1	10	10	115.4	3.61	24
Ag-ITO- ${W S e}_{2}$ -graphene	70	2	10	10	119.8	4.27	11

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Applied Optics