Surface modification of optical materials with hydrogen plasma for fabrication of Bragg gratings

Uliana O. Salgaeva; Anatoliy B. Volyncev; Sergio B. Mendes

doi:10.1364/AO.55.000485

Applied Optics
Vol. 55,
Issue 3,
pp. 485-490
(2016)
•https://doi.org/10.1364/AO.55.000485

Surface modification of optical materials with hydrogen plasma for fabrication of Bragg gratings

Uliana O. Salgaeva, Anatoliy B. Volyncev, and Sergio B. Mendes

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Uliana O. Salgaeva, Anatoliy B. Volyncev, and Sergio B. Mendes, "Surface modification of optical materials with hydrogen plasma for fabrication of Bragg gratings," Appl. Opt. 55, 485-490 (2016)

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Abstract

We investigate the hydrogen plasma process as a route for creating Bragg gratings (BGs) on optoelectronic materials such as undoped lithium niobate ( ${LiNbO}_{3}$ ), proton-exchanged ${LiNbO}_{3}$ , and soda-lime glass. Photopatterns (periodic modulations, $Λ = 323 - 2000 nm$ ) were created on those substrates and the hydrogen plasma process was investigated for its ability to transfer the microstructures and the underlying mechanisms involved in this process. The diffraction efficiency and surface topology of the BG were characterized, as well as the optical properties of corresponding bulk materials undergoing the same plasma treatment. It is shown that the hydrogen plasma treatment changes the complex refractive index and modifies the surface topology with a volume expansion in the near-surface region, and both features are connected to the appearance of structural defects in the materials. The hydrogen plasma offers unique flexibility and advantages that can be explored for the fabrication of integrated photonic components.

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No.	Material	Mask	$Λ$ , nm	$t$ , min	$P$ , $W$	$T$ , °C	Diffraction efficiency, %	Surface modulation, nm	$Δ T$ at 633 nm, %
1	Glass	S1805	323	30	50	-	$10^{- 5} (S)$	1-2	0.7
2	Glass	S1805	1000	60	50	$75 \pm 5$	$5 \times 10^{- 5} (P)$	5	1.0
3	Glass	Al	2000	120	45	$300 \pm 5$	$1.5 (S)$	90	1.9
4	${LiNbO}_{3}$	S1805	350	30	50	-	$5 \times 10^{- 5} (P)$	1-2	1.5
5	${LiNbO}_{3}$	Al	1000	60	75	$150 \pm 5$	$6.4 \times 10^{- 4} (P)$	80	2.6
6	${LiNbO}_{3}$	Al	1000	150	50	$200 \pm 5$	$0.13 (S)$	30	4.0
7	$PE : {LiNbO}_{3}$	S1805	350	30	50	-	$10^{- 5} (S)$	n/a	n/a
8	$PE : {LiNbO}_{3}$	S1805	2000	60	50	$80 \pm 5$	$10^{- 4} (S)$	4-5	15.72
9	$PE : {LiNbO}_{3}$	Al	1000	60	50	$250 \pm 5$	$0.04 (S)$	2-3	66

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