Study of the Surface of Al/MgF2 Mirrors after Exposure to High-Intensity VUV Radiation

The degradation of the surface of the Al/MgF 2 mirror coating under the influence of ultraviolet radiation from a high-intensity broadband plasma erosion source was investigated. The discharge was carried out in different gases (neon, argon, and air) to control the spectral composition of the radiat...

Full description

Saved in:
Bibliographic Details
Published in:Physics of atomic nuclei 2023-12, Vol.86 (9), p.2085-2090
Main Authors: Pasynkova, D. S., Novikov, P. A., Novikov, D. O., Telekh, V. D., Chesnokov, D. A., Zhupanov, V. G., Skriabin, A. S.
Format: Article
Language:English
Subjects:
Argon
Broadband
Cracks
Degradation
Exposure
Interaction of Plasma
Magnesium fluorides
Neon
Particle and Nuclear Physics
Particle Beams
Physics
Physics and Astronomy
Plasma erosion
Radiation
Radiation sources
Radiation with Matter
Roughness
Substrates
Ultraviolet radiation
Citations: Items that this one cites
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:The degradation of the surface of the Al/MgF 2 mirror coating under the influence of ultraviolet radiation from a high-intensity broadband plasma erosion source was investigated. The discharge was carried out in different gases (neon, argon, and air) to control the spectral composition of the radiation. The surface of the samples was examined using a micro-nanoprofilometer, measuring the roughness and the depth of cracks that occurred after irradiation. It was found that, when the sample was exposed to quanta with energy not exceeding 6 eV, the sample experienced minimal roughness losses, and no cracks were observed. When the sample was exposed to quanta with energy ≈6–15 eV, the MgF 2 layer near the radiation source began to evaporate, and the depth of cracks reached 55 nm. When the sample was exposed to quanta with energy up to 21 eV, in addition to complete evaporation of the coating, severe degradation of the substrate was observed, with cracks reaching a depth of 200 nm.
ISSN:1063-7788
1562-692X
DOI:10.1134/S1063778823090168