Multilayer deformation planarization by substrate pit suturing

Yingjie Chai; Meiping Zhu; Huanbin Xing; Hu Wang; Yun Cui; Jianda Shao

doi:10.1364/OL.41.003403

Optics Letters
Vol. 41,
Issue 15,
pp. 3403-3406
(2016)
•https://doi.org/10.1364/OL.41.003403

Multilayer deformation planarization by substrate pit suturing

Yingjie Chai, Meiping Zhu, Huanbin Xing, Hu Wang, Yun Cui, and Jianda Shao

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Yingjie Chai, Meiping Zhu, Huanbin Xing, Hu Wang, Yun Cui, and Jianda Shao, "Multilayer deformation planarization by substrate pit suturing," Opt. Lett. 41, 3403-3406 (2016)

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Abstract

In the pursuit of 1064 nm high-power laser resistance dielectric coatings in the nanosecond region, a group of ${HfO}_{2} / {SiO}_{2}$ high reflectors with and without suture layers were prepared on prearranged fused silica substrates with femtosecond laser pits. Surface morphology, global coating stress, and high-resolution cross sections were characterized to determine the effects of substrate pit suturing. Laser-induced damage resistance was investigated for samples with and without suture layers. Our results indicate considerable stability in terms of the nanosecond 1064 nm laser-induced damage threshold for samples having a suture layer, due to decreased electronic field (e-field) deformation with simultaneous elimination of internal cracks. In addition, a suture layer formed by plasma ion-assisted deposition could effectively improve global mechanical stress of the coatings. By effectively reducing the multilayer deformation using a suture layer, electron-beam high-reflective coatings, whose laser-induced damage resistance was not influenced by the substrate pit, can be prepared.

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Sample	Stack Formula ^a	Substrate
A-1	$4 L {(HL)}^{12} H 4 L$	With pit
A-2	$S 4 L {(HL)}^{12} H 4 L$	With pit
B-1	$S 4 L {(HL)}^{12} H 4 L$	Without pit
B-2	$4 L {(HL)}^{12} H 4 L$	Without pit
B-3	S	Without pit

Sample	B-1	B-2	B-3
$σ_{coatings} (MPa)$	−51.9	62.7	−200.4
$f_{total} (\times 10^{- 5} N / m)$	−52.5	34.1	−93.8

Sample	Stack Formula ^a	Substrate
A-1	$4 L {(HL)}^{12} H 4 L$	With pit
A-2	$S 4 L {(HL)}^{12} H 4 L$	With pit
B-1	$S 4 L {(HL)}^{12} H 4 L$	Without pit
B-2	$4 L {(HL)}^{12} H 4 L$	Without pit
B-3	S	Without pit

Sample	B-1	B-2	B-3
$σ_{coatings} (MPa)$	−51.9	62.7	−200.4
$f_{total} (\times 10^{- 5} N / m)$	−52.5	34.1	−93.8

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Optics Letters