Litcius/Paper detail

Gravitational-wave Merger Forecasting: Scenarios for the early detection and localization of compact-binary mergers with ground based observatories

Nitz, A., Schäfer, M., Canton, T.

2020MPG.PuRe (Max Planck Society)30 citationsOpen Access PDF

Abstract

We present the prospects for the early (pre-merger) detection and localization of compact-binary coalescences using gravitational waves over the next 10 years. Early warning can enable the direct observation of the prompt and early electromagnetic emission of a neutron star merger. We examine the capabilities of the ground based detectors at their "Design" sensitivity (2021-2022), the planned "A+" upgrade (2024-2026), and the envisioned "Voyager" concept (late 2020's). We find that for a fiducial rate of binary neutron star mergers of $1000 ~\\mathrm{Gpc}^{-3} \\mathrm{yr}^{-1}$, the Design, A+, and Voyager era networks can provide 18, 54, and 195s of warning for one source per year of observing, respectively, with a sky localization area $<$100 deg$^2$ at a $90\\%$ credible level. At the same rate, the A+ and Voyager era networks will be able to provide 9 and 43s of warning, respectively, for a source with $<$10 deg$^2$ localization area. We compare the idealized search sensitivity to that achieved by the PyCBC Live search tuned for pre-merger detection. The gravitational-wave community will be prepared to produce pre-merger alerts. Our results motivate the operation of observatories with wide fields-of-view, automation, and the capability for fast slewing to observe simultaneously with the gravitational-wave network.

Topics & Concepts

Gravitational waveUpgradeNeutron starBinary numberSkyPhysicsDetectorSensitivity (control systems)AstronomyComputer scienceAstrophysicsAerospace engineeringEngineeringOpticsElectronic engineeringArithmeticOperating systemMathematicsPulsars and Gravitational Waves ResearchGamma-ray bursts and supernovaeCosmology and Gravitation Theories