Gravitational waveforms from the inspiral of compact binaries in the Brans-Dicke theory in an expanding Universe

TL;DR

This paper develops comprehensive gravitational waveforms in Brans-Dicke theory, incorporating both wave generation and propagation effects, to improve parameter estimation accuracy for standard sirens in an expanding universe.

Contribution

It constructs consistent waveforms that include both wave generation and propagation effects in Brans-Dicke theory, addressing a gap in previous models.

Findings

Bias in redshifted chirp mass estimation can be several times larger than statistical errors.

The ratio of theoretical bias to statistical error is significantly larger for the source distance.

Impacts parameter estimation for black hole-neutron star binaries like GW191219.

Abstract

In modified gravity theories, such as the Brans-Dicke theory, the background evolution of the Universe and the perturbation around it are different from that in general relativity. Therefore, the gravitational waveforms used to study standard sirens in these theories should be modified. The modifications of the waveforms can be classified into two categories: wave generation effects and wave propagation effects. Hitherto, the waveforms used to study standard sirens in the modified gravity theories incorporate only the wave propagation effects and ignore the wave generation effects; while the waveforms focusing on the wave generation effects, such as the post-Newtonian waveforms, do not incorporate the wave propagation effects and cannot be directly applied to the sources with non-negligible redshifts in the study of standard sirens. In this work, we construct the consistent waveforms for standard sirens in the Brans-Dicke theory. The wave generation effects include the emission of the scalar breathing polarization $h_b$ and the corrections to the tensor polarizations $h_+$ and $h_\times$; the wave propagation effect is the modification of the luminosity distance for the gravitational waveforms. Using the consistent waveforms, we analyze the parameter estimation biases due to the ignorance of the wave generation effects. Considering the observations by the Einstein Telescope, we find that the ratio of the theoretical bias to the statistical error of the redshifted chirp mass is two orders of magnitude larger than that of the source distance. For black hole-neutron star binary systems like GW191219, the theoretical bias of the redshifted chirp mass can be several times larger than the statistical error.