Abstract
We investigate the impacts of the gravitational-wave (GW) standard siren observation of the Einstein Telescope (ET) on constraining the total neutrino mass. We simulate 1000 GW events that would be observed by the ET in its 10-year observation by taking the standard ΛCDM cosmology as a fiducial model. We combine the simulated GW data with other cosmological observations including cosmic microwave background (CMB), baryon acoustic oscillations (BAO), and type Ia supernovae (SN). We consider three mass hierarchy cases for the neutrino mass, i.e., normal hierarchy (NH), inverted hierarchy (IH), and degenerate hierarchy (DH). Using Planck+BAO+SN, we obtain ∑mν<0.175 eV for the NH case, ∑mν<0.200 eV for the IH case, and ∑mν<0.136 eV for the DH case. After considering the GW data, i.e., using Planck+BAO+SN+GW, the constraint results become ∑mν<0.151 eV for the NH case, ∑mν<0.185 eV for the IH case, and ∑mν<0.122 eV for the DH case. We find that the GW data can help reduce the upper limits of ∑mν by 13.7%, 7.5%, and 10.3% for the NH, IH, and DH cases, respectively. In addition, we find that the GW data can also help break the degeneracies between ∑mν and other parameters. We show that the GW data of the ET could greatly improve the constraint accuracies of cosmological parameters.
Highlights
On 17 August 2017, the signal of a gravitational wave (GW) produced by the merger of a binary neutronstar system (BNS) was detected for the first time [1], and the electromagnetic (EM) signals generated by the same transient source were observed subsequently, which indicates that the age of gravitational-wave multimessenger astronomy is coming
Comparing the results from the two data combinations, we find that the accuracy of Ωm is increased by about 60% and the accuracy of H0 is increased by about 68% when the GW data of the Einstein Telescope (ET) are considered in the cosmological fit
For the three-generation neutrinos, we considered the cases of normal hierarchy, inverted hierarchy, and degenerate hierarchy
Summary
On 17 August 2017, the signal of a gravitational wave (GW) produced by the merger of a binary neutronstar system (BNS) was detected for the first time [1], and the electromagnetic (EM) signals generated by the same transient source were observed subsequently, which indicates that the age of gravitational-wave multimessenger astronomy is coming. The GW observations can serve as a cosmic “standard siren”, which can be developed to be a new cosmological probe if we can accurately observe a large number of merger events of this class. There are some observations for the growth history of largescale structure (LSS), such as the shear measurement of the weak gravitational lensing, the galaxy clusters number counts in light of Sunyaev-Zeldovich (SZ) effect, and the CMB lensing measurement, etc. When using these observational data to make cosmological parameter esti-
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