Guided-mode resonance sensors: different schemes for different applications

Morteza Maleki; Mahdiyeh Mehran

doi:10.1364/JOSAB.449373

Journal of the Optical Society of America B
Vol. 39,
Issue 6,
pp. 1634-1643
(2022)
•https://doi.org/10.1364/JOSAB.449373

Guided-mode resonance sensors: different schemes for different applications

Morteza Maleki and Mahdiyeh Mehran

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Morteza Maleki and Mahdiyeh Mehran, "Guided-mode resonance sensors: different schemes for different applications," J. Opt. Soc. Am. B 39, 1634-1643 (2022)

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Abstract

This work performs a quantitative comparison of different dielectric-based guided-mode resonance (D-GMR) sensors. To this end, diverse D-GMR structures are classified into three different classes, and their sensitivity (S) is compared to each other. For one of these classes in various schemes, the sensitivity is investigated for the TE and TM modes. Moreover, grating height effects are studied for different cases in this category, and analytical sensitivity equations are used as benchmarks. Then, the three classes are compared and, based on the numerical results and analytical equations, various applications are proposed for different structures in the refractive index (RI) of interest. Comparing our results to other recent works, we prove that the proposed classification leads to great sensing performances and the predictions are reliable. A comparison has been performed for methane as a gas sample (with RI of 1.0003) and a hemoglobin solution and toluene as two different analytes (with RIs of 1.33 and 1.4778, respectively). The results show a sensitivity of ${\rm S} = {1427.3}\;{\rm nm/refractive}$ index unit (nm/RIU) for methane with a detection precision of one to a few volume percentages in the air, which can also be calibrated to illuminate the fabrication variation errors. For hemoglobin, a sensitivity of 1073.4 nm/RIU is obtained, with a limit of detection of 116.15 mg/lit for 65-87 g/lit of hemoglobin in water; for the toluene sensor, ${\rm S} = {1019.7}\;{\rm nm/RIU}$ is calculated. As a general result, a high figure of merit/sensitivity can be achieved over a wide range of applications, from gases to high RI analytes, using our proposed classifications.

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Data underlying the results presented in this paper are not publicly available at this time but may be obtained from the authors upon reasonable request.

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	Detected	Working
	RI Range	Wavelength	S	FoM
Refs.	(RIU)	(µm)	(nm/RIU)	( $R I U^{- 1}$ )
[25]	1.33–1.334	1.55–1.57	350	437.5
[27]	1.3–1.5	1.2–1.4	497.83	551
[29]	1.33–1.65	0.68–0.75	233.35	4200
[30]	1.4–1.41	0.77–0.85	301	12000
[24]	1.345–1.38	1.4–1.55	657	9112
[31]	1.33–1.41	0.7–0.82	82.24 (TE)	270000
			135.32 (TM)	1080000
[26]	1–1.05	1.1563	748	374
[28]	1–1.7	1.3–10	1450–10000	$\sim 1250$

$n_{c}$ (RIU)	Case Number	TE	TM
1	#1	21.05	10.28
	#5	13.32	6.62
	#6	—	7.47
	#7	59.57	91.62
1.35	#1	29.59	32.87
	#5	32.21	23.87
	#6	—	24.20
	#7	65.80	87.20
1.5	#1	37.18	49.12
	#5	46.66	59.62
	#6	—	63.13
	#7	69.73	86.11

MUR	$λ_{0, o b j e c t i v e}$ (nm)	Type	$n_{s}$	$n_{f}$	$h_{w g}$ (nm)	$h_{g}$ (nm)	$λ_{0, sim}$ (nm)	S (nm/RIU)	FoM ( ${R I U}^{- 1}$ )	LoD
Methane ( $n_{c} = 1 R I U$ )	1653.7	D	1.16	3.4	130	10	1660.2	150.52	1132.7	24	vol%
		E	1.16	3.4	130	$h_{wg}$	1634.3	33.47	11.34	37	vol%
		S	$n_{c}$	3.4	125	10	1652.8	1427.3	16457	1	vol%
Hemoglobin ( $n_{c} = 1.33 R I U$ )	1550	D	1.16	3.4	130	10	1558.4	867.11	10900	144	mg/lit
		E	1.16	3.4	130	$h_{wg}$	1516.6	1073.4	285.51	116.15	mg/lit
		S	$n_{c}$	2.05	250	10	1554.5	835.28	34021	149.65	mg/lit
Toluene ( $n_{c} = 1.4778 R I U$ )	1550	D	1.16	3.4	130	10	1556.8	860.95	24415	—
		E	1.16	3.4	130	$h_{wg}$	1528.3	1019.7	629.72	—
		S	$n_{c}$	2.05	280	10	1553.4	677.85	50365	—

	Detected	Working
	RI Range	Wavelength	S	FoM
Refs.	(RIU)	(µm)	(nm/RIU)	( $R I U^{- 1}$ )
[25]	1.33–1.334	1.55–1.57	350	437.5
[27]	1.3–1.5	1.2–1.4	497.83	551
[29]	1.33–1.65	0.68–0.75	233.35	4200
[30]	1.4–1.41	0.77–0.85	301	12000
[24]	1.345–1.38	1.4–1.55	657	9112
[31]	1.33–1.41	0.7–0.82	82.24 (TE)	270000
			135.32 (TM)	1080000
[26]	1–1.05	1.1563	748	374
[28]	1–1.7	1.3–10	1450–10000	$\sim 1250$

$n_{c}$ (RIU)	Case Number	TE	TM
1	#1	21.05	10.28
	#5	13.32	6.62
	#6	—	7.47
	#7	59.57	91.62
1.35	#1	29.59	32.87
	#5	32.21	23.87
	#6	—	24.20
	#7	65.80	87.20
1.5	#1	37.18	49.12
	#5	46.66	59.62
	#6	—	63.13
	#7	69.73	86.11

Abstract

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Journal of the Optical Society of America B