par Amorosi, Anthony 
;Amez-Droz, Loïc ;Collette, Christophe
Référence Gravitational Wave Advanced Detector Workshop (23/05/ 2022 - 27/05/2022)
Publication Publié, 2022-05-24
;Amez-Droz, Loïc ;Collette, Christophe Référence Gravitational Wave Advanced Detector Workshop (23/05/ 2022 - 27/05/2022)
Publication Publié, 2022-05-24
Poster de conférence
| Résumé : | Large-scale, high-end, scientific instruments see their performances significantly impaired by residual ground motion at low frequencies. Namely, recent development of gravitational wave detectors aims to detect gravitational waves whose strain is as low as 10-20 Hz-1/2 in the sub-Hz frequency range, while seismic noise can be 10 times larger in this frequency range. High performance active isolation strategy and seismic sensors are required to address this issue. The Precision Mechatronics Laboratory, based in ULiège and ULB, Belgium, has a large experience in developing high-resolution optical inertial sensors intended to be used in active control. The latest inertial sensors, HINS and VINS, are based on an Long-range, Michelson-type, optical readout with a sensitivity of 2∙10-13 m/√Hz at 1 Hz. They have a resolution of 2∙10-12 m/√Hz at 1 Hz, 1∙10-13 m/√Hz at 10 Hz and 3∙10-14 m/√Hz at 100 Hz. A new, compact, design of the sensors is being developed. The sensor is designed to fit a 10 x 10 x 10 cm box, reducing the original design of VINS by a factor of 8. The mechanics also features fused-silica joints for and reduced low-frequency thermal noise. Ringdown tests demonstrate a Q-factor of 2800 in open-air. |
