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Published July 2021 | Published
Journal Article Open

Zirconia-titania-doped tantala optical coatings for low mechanical loss Bragg mirrors

Lalande, Émile
Lussier, Alexandre W.
Lévesque, Carl
Ward, Marianne
Baloukas, Bill
Martinu, Ludvik
Vajente, Gabriele ORCID icon
Billingsley, Garilynn ORCID icon
Ananyeva, Alena
Bassiri, Riccardo
Fejer, Martin M. ORCID icon
Schiettekatte, François

Abstract

The noise caused by internal mechanical dissipation in high refractive index amorphous thin films in dielectric mirrors is an important limitation for gravitational wave detection. The objective of this study is to decrease this noise spectral density, which is linearly dependent on such dissipation and characterized by the loss angle of Young's modulus, by adding zirconia to titania-doped tantala, from which the current mirrors for gravitational wave detection are made. The purpose of adding zirconia is to raise the crystallization temperature, which allows the material to be more relaxed by raising the practical annealing temperature. The Ta, Ti, and Zr oxides are deposited by reactive magnetron sputtering in an Ar:O₂ atmosphere using radio frequency and high power impulse plasma excitation. We show that, thanks to zirconia, the crystallization temperature rises by more than 150°C, which allows one to obtain a loss angle of 2.5×10⁻⁴, that is, a decrease by a factor of 1.5 compared to the current mirror high-index layers. However, due to a difference in the coefficient of thermal expansion between the thin film and the silica substrate, cracks appear at high annealing temperature. In response, a silica capping layer is applied to increase the temperature of crack formation by 100°C.

Additional Information

© 2021 The Author(s). Published under an exclusive license by the AVS. Submitted: 7 April 2021 · Accepted: 25 May 2021 · Published Online: 10 June 2021. This paper is a part of the Special Topic Collection on Functional Coatings. The work performed at U. Montréal and Polytechnique Montréal was supported by the Natural Sciences and Engineering Research Council of Canada (NSERC), the Canadian Foundation for Innovation (CFI), and the Fonds de recherche Québec, Nature et technologies (FQRNT) through the Regroupement Québécois sur les matériaux de pointe (RQMP). The authors thank S. Roorda, M. Chicoine, R. Shink, and L. Godbout from U. Montréal and F. Turcot from Polytechnique Montréal for fruitful discussions and technical support. They also thank their colleagues within the LIGO Scientific Collaboration for advice and support. LIGO was constructed by the California Institute of Technology and Massachusetts Institute of Technology with funding from the National Science Foundation and operates under Cooperative Agreement No. PHY-0757058. Advanced LIGO was built under Award No. PHY-0823459. M. Fejer and R. Bassiri acknowledge the support of the LSC Center for Coatings Research, jointly funded by the National Science Foundation (NSF) and the Gordon and Betty Moore Foundation (GBMF), in particular through NSF Grant No. PHY-1708175 and GBMF Grant No. 6793. This paper has LIGO Document No. LIGO-P2000523. DATA AVAILABILITY. The data that support the findings of this study are available from the corresponding author upon reasonable request.

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