The Einstein Telescope is Europe’s next generation gravitational-wave detector. To develop all necessary technology, four research facilities have emerged across Europe: The Amaldi Research Center (ARC) in Rome (Italy), ETpathfinder in Maastricht (The Netherlands), SarGrav in the Sos Enattos mines on Sardinia (Italy) and E-TEST in Liége (Belgium) and its surroundings. The ARC pursues the investigation of a large cryostat, equipped with dedicated low-vibration cooling lines, to test full-scale cryogenic payloads. The installation will be gradual and interlaced with the payload development. ETpathfinder aims to provide a low-noise facility that allows the testing of full interferometer configurations and the interplay of their subsystems in an ET-like environment. ETpathfinder will focus amongst others on cryogenic technologies, silicon mirrors, lasers and optics at 1550 and 2090 nm and advanced quantum noise reduction schemes. The SarGrav laboratory has a surface lab and an underground operation. On the surface, the Archimedes experiment investigates the interaction of vacuum fluctuations with gravity and is developing (tilt) sensor technology for the Einstein Telescope. In an underground laboratory, seismic characterisation campaigns are undertaken for the Sardinian site characterisation. Lastly, the Einstein Telecope Euregio meuse-rhine Site & Technology (E-TEST) is a single cryogenic suspension of an ET-sized silicon mirror. Additionally, E-TEST investigates the Belgian–Dutch–German border region that is the other candidate site for Einstein Telescope using boreholes and seismic arrays and hydrogeological characterisation. In this article, we describe the Einstein Telescope, the low-frequency part of its science case and the four research facilities.
To achieve the expected level of sensitivity of third-generation
gravitational-wave observatories, more accurate and sensitive instruments than those of the second generation must be used to reduce all sources of noise.
Amongst them, one of the most relevant is seismic noise, which will require the
development of a better isolation system, especially at low frequencies (below 10
Hz), the operation of large cryogenic silicon mirrors, and the improvement of
optical wavelength readouts. In this framework, this article presents the activities
of the E-TEST (Einstein Telescope Euregio Meuse-Rhine Site & Technology) to
develop and test new key technologies for the next generation of GW observatories.
A compact isolator system for a large silicon mirror at a low frequency is proposed. The design of the isolator allows the overall height
of the isolation system to be significantly compact and also suppresses seismic
noise at low frequencies. To minimize the effect of thermal noise, the isolation
system is provided with a 100-kg silicon mirror which is suspended in a vacuum
chamber at cryogenic temperature (25-40 K). To achieve this temperature without
inducing vibrations to the mirror, a radiation-based cooling strategy is employed.
In addition, cryogenic sensors and electronics are being developed as part of the
E-TEST to detect vibrational motion in the penultimate cryogenic stage. Since
the used silicon material is not transparent below the wavelengths
typically used for GW detectors, new optical components and
lasers must be developed in the range above 1500 nm to reduce absorption and
scattering losses. Therefore, solid-state and fiber lasers with a wavelength of 2090
nm, matching high-efficiency photodiodes, and low-noise crystalline coatings are
being developed. Accordingly, the key technologies provided by E-TEST serve
crucially to reduce the limitations of the current generation of GW observatories
and to determine the technical design for the next generation.

The third-generation of gravitational wave observatories, such as the Einstein Telescope (ET) and Cosmic Explorer (CE), aim for an improvement in sensitivity of at least a factor of ten over a wide frequency range compared to the current advanced detectors. In order to inform the design of the third-generation detectors and to develop and qualify their subsystems, dedicated test facilities are required. ETpathfinder prototype uses full interferometer configurations and aims to provide a high sensitivity facility in a similar environment as ET. Along with the interferometry at 1550 nm and silicon test masses, ETpathfinder will focus on cryogenic technologies, lasers and optics at 2090 nm and advanced quantum-noise reduction schemes. This paper analyses the underpinning noise contributions and combines them into full noise budgets of the two initially targeted configurations: 1) operating with 1550 nm laser light and at a temperature of 18 K and 2) operating at 2090 nm wavelength and a temperature of 123 K.
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