Cosmographic parameters from current and next-generation gravitational wave detectors

Abstract

We evaluate the capability of current and next-generation gravitational wave detectors, such as Advanced LIGO, Einstein Telescope and DECIGO, to constrain cosmographic parameters using electromagnetically bright standard sirens. By adopting a third-order Taylor expansion, we analyze how signal-to-noise ratios and the number of events impact the estimates of the Hubble constant (H0), the deceleration (q0) and jerk (j0) parameters. Our results show that while Advanced LIGO provides a calibration-free measurement of H0 at the few-percent level, it remains insensitive to higher-order parameters. In contrast, the Einstein Telescope and DECIGO reach sub-percent accuracy for H0. Notably, DECIGO achieves a precision better than 10\% for the deceleration parameter q0 and a few tens of percent for the jerk parameter j0.