The payload of the Lunar Gravitational-wave Antenna

peer reviewed The toolbox to study the Universe grew on 14 September 2015 when the LIGO-Virgo collaboration heard a signal from two colliding black holes between 30 and 250 Hz. Since then, many more gravitational waves have been detected as detectors continue to increase sensitivity. However, the cu...

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Bibliographic Details
Published in:Journal of Applied Physics
Main Authors: van Heijningen, Joris, ter Brake, H.J.M., Gerberding, Oliver, Chalathadka Subrahmanya, Shreevathsa, Harms, Jan, Bian, Xing, Gatti, Alberto, Zeoli, Morgane, Bertolini, Alessandro, Collette, Christophe, Perali, Andrea, Pinto, Nicola, Sharma, Meenakshi, Tavernier, Filip, Rezvani, Javad
Other Authors: A&M - Aérospatiale et Mécanique - ULiège BE, Centre for Cosmology, Particle Physics and Phenomenology (CP3), UCLouvain, Faculty of Science and Technology, University of Twente, Institut für Experimentalphysik, Universität Hamburg, Gran Sasso Science Institute (GSSI), Institute of Mechanics, Chinese Academy of Sciences, Beijing, ESAT-MICAS, Katholieke Universiteit Leuven, National Institute of Subatomic Physics Nikhef, School of Pharmacy, Physics Unit, University of Camerino, INAF, I-62032 Camerino, School of Science and Technology, Physics Division, University of Camerino
Format: Article in Journal/Newspaper
Language:English
Published: American Institute of Physics Inc. 2023
Subjects:
Black holes
Gravitational wave antennas
Gravitational-waves
Inertial sensor
Interferometric detectors
Interferometrics
Laser interferometer space antenna
Seismic station
Space missions
Physics and Astronomy (all)
General Relativity and Quantum Cosmology
astro-ph.IM
General Physics and Astronomy
Engineering
computing & technology
Aerospace & aeronautics engineering
Ingénierie
informatique & technologie
Ingénierie aérospatiale
South pole
Online Access:https://orbi.uliege.be/handle/2268/306990
https://orbi.uliege.be/bitstream/2268/306990/1/244501_1_5.0144687.pdf
https://doi.org/10.1063/5.0144687
Description
Summary:peer reviewed The toolbox to study the Universe grew on 14 September 2015 when the LIGO-Virgo collaboration heard a signal from two colliding black holes between 30 and 250 Hz. Since then, many more gravitational waves have been detected as detectors continue to increase sensitivity. However, the current and future interferometric detectors will never be able to detect gravitational waves below a few Hz due to oceanic activity on Earth. An interferometric space mission, the laser interferometer space antenna, will operate between 1 mHz and 0.1 Hz, leaving a gap in the decihertz band. To detect gravitational-wave signals also between 0.1 and 1 Hz, the Lunar Gravitational-wave Antenna will use an array of seismic stations. The seismic array will be deployed in a permanently shadowed crater on the lunar south pole, which provides stable ambient temperatures below 40 K. A cryogenic superconducting inertial sensor is under development that aims for fm/ √ Hz sensitivity or better down to several hundred mHz, and thermal noise limited below that value. Given the 10 6 m size of the Moon, strain sensitivities below 10 − 20 1/ √ Hz can be achieved. The additional cooling is proposed depending on the used superconductor technology. The inertial sensors in the seismic stations aim to make a differential measurement between the elastic response of the Moon and the inertial sensor proof-mass motion induced by gravitational waves. Here, we describe the current state of research toward the inertial sensor, its applications, and additional auxiliary technologies in the payload of the lunar gravitational-wave detection mission. Lunar Gravitationnal-Wave Antenna

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