Mechanical, structural, and optical properties of PEALD metallic oxides for optical applications

Svetlana Shestaeva; Astrid Bingel; Peter Munzert; Lilit Ghazaryan; Christian Patzig; Andreas Tünnermann; Adriana Szeghalmi

doi:10.1364/AO.56.000C47

Applied Optics
Vol. 56,
Issue 4,
pp. C47-C59
(2017)
•https://doi.org/10.1364/AO.56.000C47

Mechanical, structural, and optical properties of PEALD metallic oxides for optical applications

Svetlana Shestaeva, Astrid Bingel, Peter Munzert, Lilit Ghazaryan, Christian Patzig, Andreas Tünnermann, and Adriana Szeghalmi

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Svetlana Shestaeva, Astrid Bingel, Peter Munzert, Lilit Ghazaryan, Christian Patzig, Andreas Tünnermann, and Adriana Szeghalmi, "Mechanical, structural, and optical properties of PEALD metallic oxides for optical applications," Appl. Opt. 56, C47-C59 (2017)

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Abstract

Structural, optical, and mechanical properties of ${Al}_{2} O_{3}$ , ${SiO}_{2}$ , and ${HfO}_{2}$ materials prepared by plasma-enhanced atomic layer deposition (PEALD) were investigated. Residual stress poses significant challenges for optical coatings since it may lead to mechanical failure, but in-depth understanding of these properties is still missing for PEALD coatings. The tensile stress of PEALD alumina films decreases with increasing deposition temperature and is approximately 100 MPa lower than the stress in thermally grown films. It was associated with incorporation of -OH groups in the film as measured by infrared spectroscopy. The tensile stress of hafnia PEALD layers increases with deposition temperature and was related to crystallization of the film. ${HfO}_{2}$ nanocrystallites were observed even at 100°C deposition temperature with transmission electron microscopy. Stress in hafnia films can be reduced from approximately 650 MPA to approximately 450 MPa by incorporating ultrathin ${Al}_{2} O_{3}$ layers. PEALD silica layers have shown moderate stress values and stress relaxation with the storage time, which was correlated to water adsorption. A complex interference coating system for a dichroic mirror (DCM) at 355 nm wavelength was realized with a total coating thickness of approximately 2 μm. Severe cracking of the DCM coating was observed, and it propagates even into the substrate material, showing a good adhesion of the ALD films. The reflectance peak is above 99.6% despite the mechanical failure, and further optimization on the material properties should be carried out for demanding optical applications.

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Material	Precursor	Reactant	ALD cycle [ ^b ](in s)
${Al}_{2} O_{3}$	TMA	$H_{2} O$	[0.02/-/6/-/-/0.03/-/12] (18.32)
${Al}_{2} O_{3}$	TMA	$O_{2}$ —plasma	[0.04/-/3.5/-/2/5/3.5] (14.04)
${SiO}_{2}$	3DMAS	$O_{2}$ —plasma	[0.4/4/5/-/-/3/-/4] (16.4)
	BDEAS	$O_{2}$ —plasma	[0.125/2/5/-/-/5/-/2] (14.125)
	AP-LTO 330	$O_{3}$	[0.1/5/10/-/-/2/10/8] (35.1)
${HfO}_{2}$	TDMAH	$O_{2}$ —plasma	[0.4/-/8/2/3/10/-/10] (33.4)

Material	$T$ , (°C)	$d$ nm	$ρ$ ( $g / {cm}^{3}$ ) $\pm 10 %$	$σ_{XRR}$ (nm) $\pm 0.2$	$σ_{AFM}$ (nm) $\pm 10 %$	$σ$ (MPa) $\pm 10 %$ , “zero day”
${Al}_{2} O_{3}$	120	300	3.00	1.1	-	420
	200	300	3.08	1.3	-	300
	300	300	3.10	0.9	-	92
${SiO}_{2}$	100	50	2.10	-	0.10	-
		100	2.10	-	0.11	-
		300	2.10	-	0.07	4
	200	300	2.10	-	0.10	−32
	300	300	2.10	-	0.10	−83
${HfO}_{2}$	100	50	-	-	0.27	-
		100	-	-	0.46	-
		200	7.90	0.8	-	611
	200	200	8.90	1.5	-	629
	300	200	9.30	2.3	-	917

Process	Plasma Conditions	Stress (MPa)	Refractive Index at 550 nm
Standard Plasma	50 sccm $O_{2}$ , 300 W	650	2.03
High energy plasma	10 sccm $O_{2}$ , 300 W	820	2.05
Low energy plasma	90 sccm $O_{2}$ , 100 W	640	2.03

Parameter	Specification
Center wavelength	HR 355 nm/AR 532 nm/AR 1064 nm
Angle of incidence (AOI)	45°
Spectral reflectance	HR 355 nm 0.997/AR 532 nm and 1064 nm $< 0.01$
Substrate material	UV grade fused silica (Suprasil 1)

DCM1		DCM2
Process temperature	100°C	Process temperature	200°C
Oxygen plasma pre-treatment	120 s	Oxygen plasma pre-treatment	300 s
Pre-coating layer	No	Pre-coating layer	5 nm ${SiO}_{2}$
Total number of layers	33	Total number of layers	30
$Σ {HfO}_{2}$	861 nm	$Σ {HfO}_{2} / {Al}_{2} O_{3}$ nanolaminates	743 nm
$Σ {SiO}_{2}$	1271 nm	$Σ {SiO}_{2}$	1161 nm
Total thickness	2132 nm	Total thickness	1904 nm

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Applied Optics