Luminosity distance uncertainties from gravitational wave detections by third generation observatories

TL;DR

This paper investigates how third-generation gravitational wave detector configurations affect the precision of luminosity distance measurements, crucial for understanding cosmic expansion, by analyzing network topology, orientation, and inclination angle effects.

Contribution

It provides analytic and numerical insights into optimizing detector networks to minimize luminosity distance uncertainties, considering topology, orientation, and source inclination.

Findings

Detector network configuration significantly impacts distance measurement accuracy.

Prior knowledge of source inclination improves distance estimation precision.

Optimal detector placement can approach the fundamental lensing limit at high redshift.

Abstract

A new generation of terrestrial gravitational wave detectors is currently being planned for the next decade, and it is expected to detect most of the coalescences of compact objects in the universe with masses up to a thousand times the solar mass. Among the several possible applications of current and future detections, we focus on the impact on the measure of the luminosity distance of the sources, which is an invaluable tool for constraining the cosmic expansion history of the universe. We study two specific detector topologies, triangular and L-shaped, by investigating how topology and relative orientation of up to three detectors can minimize the uncertainty measure of the luminosity distance. While the precision in distance measurement is correlated with several geometric angles determining the source position and orientation, focusing on bright standard sirens and assuming redshift to be measured with high accuracy, we obtain analytic and numerical results for its uncertainty depending on type and number of detectors composing a network, as well as on the inclination angle of the binary plane with respect to the wave propagation direction. We also analyze the best relative location and orientation of two third generation detectors to minimize luminosity distance uncertainty, showing that prior knowledge of the inclination angle distribution plays an important role in precision recovery of luminosity distance, and that a suitably arranged network of detectors can reduce drastically the uncertainty measure, approaching the limit imposed by lensing effects intervening between source and detector at redshift $z \gtrsim 0.7$.