Binary Neutron Star Mergers and Third Generation Detectors: Localization and Early Warning

TL;DR

This paper develops a Fisher matrix approach to estimate sky localization and early warning capabilities of third-generation gravitational wave detectors like Einstein Telescope and Cosmic Explorer for binary neutron star mergers, considering long-duration signals and Earth's rotation effects.

Contribution

It introduces a novel Fisher matrix method accounting for Earth's rotation effects on long signals, improving localization and early warning predictions for third-generation detectors.

Findings

Einstein Telescope alone can localize most sources within 100 deg² at ≤200 Mpc.

Detector networks significantly improve sky localization, achieving ~1 deg² at ≤200 Mpc.

Early warning alerts can be issued hours before merger for nearby sources, enabling prompt electromagnetic follow-up.

Abstract

For third generation gravitational wave detectors, such as the Einstein Telescope, gravitational wave signals from binary neutron stars can last up to a few days before the neutron stars merge. To estimate the measurement uncertainties of key signal parameters, we develop a Fisher matrix approach which accounts for effects on such long duration signals of the time-dependent detector response and the earths rotation. We use this approach to characterize the sky localization uncertainty for gravitational waves from binary neutron stars at 40, 200, 400, 800 and 1600Mpc, for the Einstein Telescope and Cosmic Explorer individually and operating as a network. We find that the Einstein Telescope alone can localize the majority of detectable binary neutron stars at a distance of $\leq200$Mpc to within $100\text{deg}^2$ with 90% confidence. A network consisting of the Einstein Telescope and Cosmic Explorer can enhance the sky localization performance significantly - with the 90% credible region of $\mathcal{O}(1) \text{deg}^2$ for most sources at $\leq200$Mpc and $\leq100\text{deg}^2$ for most sources at $\leq1600$Mpc. We also investigate the prospects for third generation detectors identifying the presence of a signal prior to merger. To do this, we require a signal to have a network signal-to-noise ratio of $\geq12$ and $\geq5.5$ for at least two interferometers, and to have a 90% credible region for the sky localization that is no larger than $100 \text{deg}^2$. We find that the Einstein Telescope can send out such "early-warning" detection alerts 1 - 20 hours before merger for 100% of detectable binary neutron stars at 40Mpc and for $\sim58\%$ of sources at 200Mpc. For sources at a distance of 400Mpc, a network of the Einstein telescope and Cosmic Explorer can produce detection alerts up to $\sim 3$ hours prior to merger for 98% of detectable binary neutron stars.