Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors

A. Amato; M. Bazzan; G. Cagnoli; M. Canepa; M. Coulon; J. Degallaix; N. Demos; A. Di Michele; M. Evans; F. Fabrizi; G. Favaro; D. Forest; S. Gras; D. Hofman; A. Lemaître; G. Maggioni; M. Magnozzi; V. Martinez; L. Mereni; C. Michel; V. Milotti; M. Montani; A. Paolone; A. Pereira; F. Piergiovanni; V. Pierro; L. Pinard; I. M. Pinto; E. Placidi; S. Samandari; B. Sassolas; N. Shcheblanov; J. Teillon; I. Vickridge; M. Granata

doi:10.1103/PhysRevD.111.042003

Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors

A. Amato, M. Bazzan, G. Cagnoli, M. Canepa, M. Coulon, J. Degallaix, N. Demos, A. Di Michele, M. Evans, F. Fabrizi, G. Favaro, D. Forest, S. Gras, D. Hofman, A. Lemaître, G. Maggioni, M. Magnozzi, V. Martinez, L. Mereni, C. MichelV. Milotti, M. Montani, A. Paolone, A. Pereira, F. Piergiovanni, V. Pierro, L. Pinard, I. M. Pinto, E. Placidi, S. Samandari, B. Sassolas, N. Shcheblanov, J. Teillon, I. Vickridge, M. Granata^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

Brownian thermal noise of thin-film coatings is a fundamental limit for high-precision experiments based on optical resonators such as gravitational-wave interferometers. Here we present the results of a research activity aiming to develop lower-noise ion-beam sputtered silicon nitride thin films compliant with the very stringent requirements on optical loss of gravitational-wave interferometers. In order to test the hypothesis of a correlation between the synthesis conditions of the films and their elemental composition and optical and mechanical properties, we varied the voltage, current intensity, and composition of the sputtering ion beam, and we performed a broad campaign of characterizations. While the refractive index was found to monotonically depend on the beam voltage and linearly vary with the N/Si ratio, the optical absorption appeared to be strongly sensitive to other factors, as yet unidentified. However, by systematically varying the deposition parameters, an optimal working point was found. Thus we show that the loss angle and extinction coefficient of our thin films can be as low as (1.0±0.1)×10-4 rad at ~2.8 kHz and (6.4±0.2)×10-6 at 1064 nm, respectively, after thermal treatment at 900 °C. To the best of our knowledge, such loss angle value is the lowest ever measured on this class of thin films. We then used our silicon nitride thin films to design and produce a multimaterial mirror coating showing a thermal noise amplitude of (10.3±0.2)×10-18 m Hz-1/2 at 100 Hz, which is 25% lower than in current mirror coatings of the Advanced LIGO and Advanced Virgo interferometers, and an optical absorption as low as (1.6±0.5) parts per million at 1064 nm.

Original language	English
Article number	042003
Journal	Physical Review D
Volume	111
Issue number	4
DOIs	https://doi.org/10.1103/PhysRevD.111.042003
Publication status	Published - 15 Feb 2025

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Amato, A., Bazzan, M., Cagnoli, G., Canepa, M., Coulon, M., Degallaix, J., Demos, N., Di Michele, A., Evans, M., Fabrizi, F., Favaro, G., Forest, D., Gras, S., Hofman, D., Lemaître, A., Maggioni, G., Magnozzi, M., Martinez, V., Mereni, L., ... Granata, M. (2025). Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors. Physical Review D, 111(4), Article 042003. https://doi.org/10.1103/PhysRevD.111.042003

@article{7f04d2412b4b4c5bbe41bbf53a4d4c4d,

title = "Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors",

abstract = "Brownian thermal noise of thin-film coatings is a fundamental limit for high-precision experiments based on optical resonators such as gravitational-wave interferometers. Here we present the results of a research activity aiming to develop lower-noise ion-beam sputtered silicon nitride thin films compliant with the very stringent requirements on optical loss of gravitational-wave interferometers. In order to test the hypothesis of a correlation between the synthesis conditions of the films and their elemental composition and optical and mechanical properties, we varied the voltage, current intensity, and composition of the sputtering ion beam, and we performed a broad campaign of characterizations. While the refractive index was found to monotonically depend on the beam voltage and linearly vary with the N/Si ratio, the optical absorption appeared to be strongly sensitive to other factors, as yet unidentified. However, by systematically varying the deposition parameters, an optimal working point was found. Thus we show that the loss angle and extinction coefficient of our thin films can be as low as (1.0±0.1)×10-4 rad at ~2.8 kHz and (6.4±0.2)×10-6 at 1064 nm, respectively, after thermal treatment at 900 °C. To the best of our knowledge, such loss angle value is the lowest ever measured on this class of thin films. We then used our silicon nitride thin films to design and produce a multimaterial mirror coating showing a thermal noise amplitude of (10.3±0.2)×10-18 m Hz-1/2 at 100 Hz, which is 25% lower than in current mirror coatings of the Advanced LIGO and Advanced Virgo interferometers, and an optical absorption as low as (1.6±0.5) parts per million at 1064 nm.",

author = "A. Amato and M. Bazzan and G. Cagnoli and M. Canepa and M. Coulon and J. Degallaix and N. Demos and {Di Michele}, A. and M. Evans and F. Fabrizi and G. Favaro and D. Forest and S. Gras and D. Hofman and A. Lema{\^i}tre and G. Maggioni and M. Magnozzi and V. Martinez and L. Mereni and C. Michel and V. Milotti and M. Montani and A. Paolone and A. Pereira and F. Piergiovanni and V. Pierro and L. Pinard and Pinto, {I. M.} and E. Placidi and S. Samandari and B. Sassolas and N. Shcheblanov and J. Teillon and I. Vickridge and M. Granata",

note = "Funding Information: This work has been promoted by the LMA and partially supported by the Master Projet Couches Minces Optiques of CNRS Nucl\u00E9aire & Particules and by the European Gravitational Observatory in the framework of the Advanced project. The CTN experiment is supported by the LIGO Laboratory. 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-1764464. CTN data analysis and figure generation were carried out using matlab software provided by The MathWorks, Inc. M. Magnozzi gratefully acknowledges the RADIATE Transnational Access Grant No. 824096 (proposal 21002507-ST) funded by the Horizon 2020 research and innovation programme of the European Union, for access to the SAFIR ion beam facility at the Institut des NanoSciences de Paris. The integrated XPS measurements were carried out at the SmartLab facility of the Department of Physics at Sapienza Universit\u00E0 di Roma. We thank I. Roch and G. Cochez of the Institut d\u2019Electronique, de Micro\u00E9lectronique et de Nanotechnologie for providing an LP-CVD sample, in the framework of the French RENATECH network. In the document repositories of the LIGO and Virgo Collaborations, this work has numbers LIGO-P2400299 and VIR-0630C-24, respectively. Publisher Copyright: {\textcopyright} 2025 American Physical Society.",

year = "2025",

month = feb,

day = "15",

doi = "10.1103/PhysRevD.111.042003",

language = "English",

volume = "111",

journal = "Physical Review D",

issn = "1550-7998",

publisher = "American Physical Society",

number = "4",

}

Amato, A, Bazzan, M, Cagnoli, G, Canepa, M, Coulon, M, Degallaix, J, Demos, N, Di Michele, A, Evans, M, Fabrizi, F, Favaro, G, Forest, D, Gras, S, Hofman, D, Lemaître, A, Maggioni, G, Magnozzi, M, Martinez, V, Mereni, L, Michel, C, Milotti, V, Montani, M, Paolone, A, Pereira, A, Piergiovanni, F, Pierro, V, Pinard, L, Pinto, IM, Placidi, E, Samandari, S, Sassolas, B, Shcheblanov, N, Teillon, J, Vickridge, I & Granata, M 2025, 'Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors', Physical Review D, vol. 111, no. 4, 042003. https://doi.org/10.1103/PhysRevD.111.042003

TY - JOUR

T1 - Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors

AU - Amato, A.

AU - Bazzan, M.

AU - Cagnoli, G.

AU - Canepa, M.

AU - Coulon, M.

AU - Degallaix, J.

AU - Demos, N.

AU - Di Michele, A.

AU - Evans, M.

AU - Fabrizi, F.

AU - Favaro, G.

AU - Forest, D.

AU - Gras, S.

AU - Hofman, D.

AU - Lemaître, A.

AU - Maggioni, G.

AU - Magnozzi, M.

AU - Martinez, V.

AU - Mereni, L.

AU - Michel, C.

AU - Milotti, V.

AU - Montani, M.

AU - Paolone, A.

AU - Pereira, A.

AU - Piergiovanni, F.

AU - Pierro, V.

AU - Pinard, L.

AU - Pinto, I. M.

AU - Placidi, E.

AU - Samandari, S.

AU - Sassolas, B.

AU - Shcheblanov, N.

AU - Teillon, J.

AU - Vickridge, I.

AU - Granata, M.

N1 - Funding Information: This work has been promoted by the LMA and partially supported by the Master Projet Couches Minces Optiques of CNRS Nucl\u00E9aire & Particules and by the European Gravitational Observatory in the framework of the Advanced project. The CTN experiment is supported by the LIGO Laboratory. 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-1764464. CTN data analysis and figure generation were carried out using matlab software provided by The MathWorks, Inc. M. Magnozzi gratefully acknowledges the RADIATE Transnational Access Grant No. 824096 (proposal 21002507-ST) funded by the Horizon 2020 research and innovation programme of the European Union, for access to the SAFIR ion beam facility at the Institut des NanoSciences de Paris. The integrated XPS measurements were carried out at the SmartLab facility of the Department of Physics at Sapienza Universit\u00E0 di Roma. We thank I. Roch and G. Cochez of the Institut d\u2019Electronique, de Micro\u00E9lectronique et de Nanotechnologie for providing an LP-CVD sample, in the framework of the French RENATECH network. In the document repositories of the LIGO and Virgo Collaborations, this work has numbers LIGO-P2400299 and VIR-0630C-24, respectively. Publisher Copyright: © 2025 American Physical Society.

PY - 2025/2/15

Y1 - 2025/2/15

N2 - Brownian thermal noise of thin-film coatings is a fundamental limit for high-precision experiments based on optical resonators such as gravitational-wave interferometers. Here we present the results of a research activity aiming to develop lower-noise ion-beam sputtered silicon nitride thin films compliant with the very stringent requirements on optical loss of gravitational-wave interferometers. In order to test the hypothesis of a correlation between the synthesis conditions of the films and their elemental composition and optical and mechanical properties, we varied the voltage, current intensity, and composition of the sputtering ion beam, and we performed a broad campaign of characterizations. While the refractive index was found to monotonically depend on the beam voltage and linearly vary with the N/Si ratio, the optical absorption appeared to be strongly sensitive to other factors, as yet unidentified. However, by systematically varying the deposition parameters, an optimal working point was found. Thus we show that the loss angle and extinction coefficient of our thin films can be as low as (1.0±0.1)×10-4 rad at ~2.8 kHz and (6.4±0.2)×10-6 at 1064 nm, respectively, after thermal treatment at 900 °C. To the best of our knowledge, such loss angle value is the lowest ever measured on this class of thin films. We then used our silicon nitride thin films to design and produce a multimaterial mirror coating showing a thermal noise amplitude of (10.3±0.2)×10-18 m Hz-1/2 at 100 Hz, which is 25% lower than in current mirror coatings of the Advanced LIGO and Advanced Virgo interferometers, and an optical absorption as low as (1.6±0.5) parts per million at 1064 nm.

AB - Brownian thermal noise of thin-film coatings is a fundamental limit for high-precision experiments based on optical resonators such as gravitational-wave interferometers. Here we present the results of a research activity aiming to develop lower-noise ion-beam sputtered silicon nitride thin films compliant with the very stringent requirements on optical loss of gravitational-wave interferometers. In order to test the hypothesis of a correlation between the synthesis conditions of the films and their elemental composition and optical and mechanical properties, we varied the voltage, current intensity, and composition of the sputtering ion beam, and we performed a broad campaign of characterizations. While the refractive index was found to monotonically depend on the beam voltage and linearly vary with the N/Si ratio, the optical absorption appeared to be strongly sensitive to other factors, as yet unidentified. However, by systematically varying the deposition parameters, an optimal working point was found. Thus we show that the loss angle and extinction coefficient of our thin films can be as low as (1.0±0.1)×10-4 rad at ~2.8 kHz and (6.4±0.2)×10-6 at 1064 nm, respectively, after thermal treatment at 900 °C. To the best of our knowledge, such loss angle value is the lowest ever measured on this class of thin films. We then used our silicon nitride thin films to design and produce a multimaterial mirror coating showing a thermal noise amplitude of (10.3±0.2)×10-18 m Hz-1/2 at 100 Hz, which is 25% lower than in current mirror coatings of the Advanced LIGO and Advanced Virgo interferometers, and an optical absorption as low as (1.6±0.5) parts per million at 1064 nm.

U2 - 10.1103/PhysRevD.111.042003

DO - 10.1103/PhysRevD.111.042003

M3 - Article

SN - 1550-7998

VL - 111

JO - Physical Review D

JF - Physical Review D

IS - 4

M1 - 042003

ER -

Development of ion-beam sputtered silicon nitride thin films for low-noise mirror coatings of gravitational-wave detectors

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