Optical properties of germania and titania at 1064 nm and at 1550 nm

D. Diksha; A. Amato; V Spagnuolo; G. McGhee; M. Chicoine; C. Clark; S. Hill; J. Hough; R. Johnston; R. Keil; N. Mavridi; S. Reid; S. Rowan; T. Schapals; F. Schiettekatte; S. C. Tait; I. W. Martin; J. Steinlechner

doi:10.1088/1361-6382/ad3c8c

Optical properties of germania and titania at 1064 nm and at 1550 nm

D. Diksha^*, A. Amato, V Spagnuolo, G. McGhee, M. Chicoine, C. Clark, S. Hill, J. Hough, R. Johnston, R. Keil, N. Mavridi, S. Reid, S. Rowan, T. Schapals, F. Schiettekatte, S. C. Tait, I. W. Martin, J. Steinlechner^*

^*Corresponding author for this work

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

Abstract

One of the main noise sources in current gravitational-wave detectors is the thermal noise of the high-reflectivity coatings on the main interferometer optics. Coating thermal noise is dominated by the mechanical loss of the high-refractive index material within the coating stacks, Ta 2 O 5 mixed with TiO 2 . For upgrades to room-temperature detectors, a mixture of GeO 2 and TiO 2 is an interesting alternative candidate coating material. While the rather low refractive index of GeO2 increases with increasing TiO 2 content, a higher TiO 2 content results in a lower threshold temperature before heat treatment leads to crystallisation, and potentially to a degradation of optical properties. For future cryogenic detectors, on the other hand, a higher TiO 2 content is beneficial as the TiO2 suppresses the low-temperature mechanical loss peak of GeO2. In this paper, we present the optical properties of coatings-produced by plasma-assisted ion-beam evaporation-with high TiO2 content at 1550 nm, a laser wavelength considered for cryogenic gravitational-wave detectors, as a function of heat-treatment temperature. For comparison, the absorption of pure GeO2 was also measured. Furthermore, results at the currently-used wavelength of 1064 nm are presented.

Original language	English
Article number	125006
Number of pages	12
Journal	Classical and Quantum Gravity
Volume	41
Issue number	12
DOIs	https://doi.org/10.1088/1361-6382/ad3c8c
Publication status	Published - 20 Jun 2024

Keywords

gravitational-wave detectors
coating thermal noise
titania
low temperature
absorption
THERMAL NOISE
FILMS

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Diksha, D., Amato, A., Spagnuolo, V., McGhee, G., Chicoine, M., Clark, C., Hill, S., Hough, J., Johnston, R., Keil, R., Mavridi, N., Reid, S., Rowan, S., Schapals, T., Schiettekatte, F., Tait, S. C., Martin, I. W., & Steinlechner, J. (2024). Optical properties of germania and titania at 1064 nm and at 1550 nm. Classical and Quantum Gravity, 41(12), Article 125006. https://doi.org/10.1088/1361-6382/ad3c8c

@article{2a7df9281189428bb94ec7352b24fffc,

title = "Optical properties of germania and titania at 1064 nm and at 1550 nm",

abstract = "One of the main noise sources in current gravitational-wave detectors is the thermal noise of the high-reflectivity coatings on the main interferometer optics. Coating thermal noise is dominated by the mechanical loss of the high-refractive index material within the coating stacks, Ta 2 O 5 mixed with TiO 2 . For upgrades to room-temperature detectors, a mixture of GeO 2 and TiO 2 is an interesting alternative candidate coating material. While the rather low refractive index of GeO2 increases with increasing TiO 2 content, a higher TiO 2 content results in a lower threshold temperature before heat treatment leads to crystallisation, and potentially to a degradation of optical properties. For future cryogenic detectors, on the other hand, a higher TiO 2 content is beneficial as the TiO2 suppresses the low-temperature mechanical loss peak of GeO2. In this paper, we present the optical properties of coatings-produced by plasma-assisted ion-beam evaporation-with high TiO2 content at 1550 nm, a laser wavelength considered for cryogenic gravitational-wave detectors, as a function of heat-treatment temperature. For comparison, the absorption of pure GeO2 was also measured. Furthermore, results at the currently-used wavelength of 1064 nm are presented.",

keywords = "gravitational-wave detectors, coating thermal noise, titania, low temperature, absorption, THERMAL NOISE, FILMS",

author = "D. Diksha and A. Amato and V Spagnuolo and G. McGhee and M. Chicoine and C. Clark and S. Hill and J. Hough and R. Johnston and R. Keil and N. Mavridi and S. Reid and S. Rowan and T. Schapals and F. Schiettekatte and Tait, {S. C.} and Martin, {I. W.} and J. Steinlechner",

year = "2024",

month = jun,

day = "20",

doi = "10.1088/1361-6382/ad3c8c",

language = "English",

volume = "41",

journal = "Classical and Quantum Gravity",

issn = "0264-9381",

publisher = "IOP Publishing Ltd.",

number = "12",

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Diksha, D , Amato, A, Spagnuolo, V, McGhee, G, Chicoine, M, Clark, C, Hill, S, Hough, J, Johnston, R, Keil, R, Mavridi, N, Reid, S, Rowan, S, Schapals, T, Schiettekatte, F, Tait, SC, Martin, IW & Steinlechner, J 2024, 'Optical properties of germania and titania at 1064 nm and at 1550 nm', Classical and Quantum Gravity, vol. 41, no. 12, 125006. https://doi.org/10.1088/1361-6382/ad3c8c

TY - JOUR

T1 - Optical properties of germania and titania at 1064 nm and at 1550 nm

AU - Diksha, D.

AU - Amato, A.

AU - Spagnuolo, V

AU - McGhee, G.

AU - Chicoine, M.

AU - Clark, C.

AU - Hill, S.

AU - Hough, J.

AU - Johnston, R.

AU - Keil, R.

AU - Mavridi, N.

AU - Reid, S.

AU - Rowan, S.

AU - Schapals, T.

AU - Schiettekatte, F.

AU - Tait, S. C.

AU - Martin, I. W.

AU - Steinlechner, J.

PY - 2024/6/20

Y1 - 2024/6/20

N2 - One of the main noise sources in current gravitational-wave detectors is the thermal noise of the high-reflectivity coatings on the main interferometer optics. Coating thermal noise is dominated by the mechanical loss of the high-refractive index material within the coating stacks, Ta 2 O 5 mixed with TiO 2 . For upgrades to room-temperature detectors, a mixture of GeO 2 and TiO 2 is an interesting alternative candidate coating material. While the rather low refractive index of GeO2 increases with increasing TiO 2 content, a higher TiO 2 content results in a lower threshold temperature before heat treatment leads to crystallisation, and potentially to a degradation of optical properties. For future cryogenic detectors, on the other hand, a higher TiO 2 content is beneficial as the TiO2 suppresses the low-temperature mechanical loss peak of GeO2. In this paper, we present the optical properties of coatings-produced by plasma-assisted ion-beam evaporation-with high TiO2 content at 1550 nm, a laser wavelength considered for cryogenic gravitational-wave detectors, as a function of heat-treatment temperature. For comparison, the absorption of pure GeO2 was also measured. Furthermore, results at the currently-used wavelength of 1064 nm are presented.

AB - One of the main noise sources in current gravitational-wave detectors is the thermal noise of the high-reflectivity coatings on the main interferometer optics. Coating thermal noise is dominated by the mechanical loss of the high-refractive index material within the coating stacks, Ta 2 O 5 mixed with TiO 2 . For upgrades to room-temperature detectors, a mixture of GeO 2 and TiO 2 is an interesting alternative candidate coating material. While the rather low refractive index of GeO2 increases with increasing TiO 2 content, a higher TiO 2 content results in a lower threshold temperature before heat treatment leads to crystallisation, and potentially to a degradation of optical properties. For future cryogenic detectors, on the other hand, a higher TiO 2 content is beneficial as the TiO2 suppresses the low-temperature mechanical loss peak of GeO2. In this paper, we present the optical properties of coatings-produced by plasma-assisted ion-beam evaporation-with high TiO2 content at 1550 nm, a laser wavelength considered for cryogenic gravitational-wave detectors, as a function of heat-treatment temperature. For comparison, the absorption of pure GeO2 was also measured. Furthermore, results at the currently-used wavelength of 1064 nm are presented.

KW - gravitational-wave detectors

KW - coating thermal noise

KW - titania

KW - low temperature

KW - absorption

KW - THERMAL NOISE

KW - FILMS

U2 - 10.1088/1361-6382/ad3c8c

DO - 10.1088/1361-6382/ad3c8c

M3 - Article

SN - 0264-9381

VL - 41

JO - Classical and Quantum Gravity

JF - Classical and Quantum Gravity

IS - 12

M1 - 125006

ER -

Optical properties of germania and titania at 1064 nm and at 1550 nm

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