R. L. Ward scite author profile

Advanced Virgo is the project to upgrade the Virgo interferometric detector of gravitational waves, with the aim of increasing the number of observable galaxies (and thus the detection rate) by three orders of magnitude. The project is now in an advanced construction phase and the assembly and integration will be completed by the end of 2015. Advanced Virgo will be part of a network, alongside the two Advanced LIGO detectors in the US and GEO HF in Germany, with the goal of contributing to the early detections of gravitational waves and to the opening a new window of observation on the universe. In this paper we describe the main features of the Advanced Virgo detector and outline the status of the construction.

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Quantum-Enhanced Advanced LIGO Detectors in the Era of Gravitational-Wave Astronomy

Tse¹,

Yu²,

Kijbunchoo³

et al. 2019

Phys. Rev. Lett.

540

323

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The Laser Interferometer Gravitational Wave Observatory (LIGO) has been directly detecting gravitational waves from compact binary mergers since 2015. We report on the first use of squeezed vacuum states in the direct measurement of gravitational waves with the Advanced LIGO H1 and L1 detectors. This achievement is the culmination of decades of research to implement squeezed states in gravitational-wave detectors. During the ongoing O3 observation run, squeezed states are improving the sensitivity of the LIGO interferometers to signals above 50 Hz by up to 3 dB, thereby increasing the expected detection rate by 40% (H1) and 50% (L1).

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Sensitivity of the Advanced LIGO detectors at the beginning of gravitational wave astronomy

Мартынов¹,

Hall²,

Abbott³

et al. 2016

Phys. Rev. D

369

268

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The Laser Interferometer Gravitational Wave Observatory (LIGO) consists of two widely separated 4 km laser interferometers designed to detect gravitational waves from distant astrophysical sources in the frequency range from 10 Hz to 10 kHz. The first observation run of the Advanced LIGO detectors started in September 2015 and ended in January 2016. A strain sensitivity of better than 10 −23 / √ Hz was achieved around 100 Hz. Understanding both the fundamental and the technical noise sources was critical for increasing the astrophsyical strain sensitivity. The average distance at which coalescing binary black hole systems with individual masses of 30 M could be detected above a signal-to-noise ratio (SNR) of 8 was 1.3 Gpc, and the range for binary neutron star inspirals was about 75 Mpc. With respect to the initial detectors, the observable volume of the Universe increased by a factor 69 and 43, respectively. These improvements helped Advanced LIGO to detect the gravitational wave signal from the binary black hole coalescence, known as GW150914.

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Sensitivity and performance of the Advanced LIGO detectors in the third observing run

Buikema¹,

Cahillane²,

Mansell³

et al. 2020

Phys. Rev. D

315

262

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On April 1st, 2019, the Advanced Laser Interferometer Gravitational-Wave Observatory (aLIGO), joined by the Advanced Virgo detector, began the third observing run, a year-long dedicated search for gravitational radiation. The LIGO detectors have achieved a higher duty cycle and greater sensitivity to gravitational waves than ever before, with LIGO Hanford achieving angle-averaged sensitivity to binary neutron star coalescences to a distance of 111 Mpc, and LIGO Livingston to 134 Mpc with duty factors of 74.6% and 77.0% respectively. The improvement in sensitivity and stability is a result of several upgrades to the detectors, including doubled intracavity power, the addition of an in-vacuum optical parametric oscillator for squeezed-light injection, replacement of core optics and end reaction masses, and installation of acoustic mode dampers. This paper explores the purposes behind these upgrades, and explains to the best of our knowledge the noise currently limiting the sensitivity of each detector.

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A quantum-enhanced prototype gravitational-wave detector

et al. 2008

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The quantum nature of the electromagnetic field imposes a fundamental limit on the sensitivity of optical precision measurements such as spectroscopy, microscopy, and interferometry [1]. The so-called quantum limit is set by the zero-point fluctuations of the electromagnetic field, which constrain the precision with which optical signals can be measured [2,3,4]. In the world of precision measurement, laser-interferometric gravitational wave (GW) detectors [4,5, 7] are the most sensitive position meters ever operated, capable of measuring distance changes on the order of 10 −18 m RMS over kilometer separations caused by GWs from astronomical sources [8]. The sensitivity of currently operational and future GW detectors is limited by quantum optical noise [7]. Here we demonstrate a 44% improvement in displacement sensitivity of a prototype GW detector with suspended quasi-free mirrors at frequencies where the sensitivity is shot-noise-limited, by injection of a squeezed state of light [1,2,3]. This demonstration is a critical step toward implementation of squeezing-enhancement in large-scale GW detectors.

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R. L. Ward

Advanced Virgo: a second-generation interferometric gravitational wave detector

Quantum-Enhanced Advanced LIGO Detectors in the Era of Gravitational-Wave Astronomy

Sensitivity of the Advanced LIGO detectors at the beginning of gravitational wave astronomy

Sensitivity and performance of the Advanced LIGO detectors in the third observing run

A quantum-enhanced prototype gravitational-wave detector

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