Silver nanopillar coatings grown by glancing angle magnetron sputtering for reducing multipactor effect in spacecrafts

Silver nanopillar coatings grown by glancing angle magnetron sputtering for reducing multipactor effect in spacecrafts

[Display omitted] •High aspect ratio nanometric surface roughness lessens secondary electron emission.•SEE main reduction occurs at low electron energies, most influencing in multipactor.•Glancing angle deposition of Ag nanopillars is suitable method for SEE reduction.•Ag nanopillars coatings can av...

Full description

Saved in:
Bibliographic Details
Published in:Applied surface science Vol. 526; p. 146699
Main Authors: Troncoso, G., García-Martín, J.M., González, M.U., Morales, C., Fernández-Castro, M., Soler-Morala, J., Galán, L., Soriano, L.
Format: Journal Article
Language:English
Published: Elsevier B.V 01-10-2020
Subjects:
Ag nanopillars
Anti-multipactor coatings
Glancing angle deposition
Magnetron sputtering
Secondary electron emission
Ag nanopillars
Anti-multipactor coatings
Magnetron sputtering
Secondary electron emission
Glancing angle deposition
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:[Display omitted] •High aspect ratio nanometric surface roughness lessens secondary electron emission.•SEE main reduction occurs at low electron energies, most influencing in multipactor.•Glancing angle deposition of Ag nanopillars is suitable method for SEE reduction.•Ag nanopillars coatings can avoid multipactor with no increase of insertion losses. We have studied nanometric high aspect ratio Ag nanopillar coatings exhibiting reduced secondary electron emission for the mitigation of multipactor effect in radio-frequency space devices of high frequency and high power. The Ag nanopillars have been grown by glancing angle deposition with DC magnetron sputtering. Some samples have been covered by a gold capping layer to reduce oxidation and aging effects. The secondary emission yield of the surfaces of these samples has been measured and compared to those of flat Ag and Au reference samples. The results show that high aspect ratio surface roughness at the nanometer scale significantly reduce the secondary emission yield of the surface. This reduction is more important for low electron energies, which is the most influencing energy range of electrons for multipactor. The multipactor region for the nanopillar coating presenting the best secondary emission yield properties has been simulated, finding practical suppression of multipactor effect. The high-frequency surface resistance of these samples has also been estimated from published computations for similar surface roughness patterns. It was found that such nanopillar coatings are compatible with the best accomplishments of present space industry.
ISSN:0169-4332
1873-5584
DOI:10.1016/j.apsusc.2020.146699