Systematic errors on optical-SED stellar mass estimates for galaxies across cosmic time and their impact on cosmology

TL;DR

This study investigates how systematic errors in estimating galaxy stellar masses at different redshifts affect cosmological measurements, finding that corrections are necessary for precision but have limited impact on key parameters.

Contribution

It introduces redshift-dependent corrections for stellar mass estimates of galaxy hosts, addressing systematic biases in SNe Ia cosmology analyses across cosmic time.

Findings

Stellar masses are underestimated at higher redshifts due to wavelength coverage.

Applying corrections slightly alters cosmological parameters, reducing some systematic biases.

Systematic errors in host mass estimates are manageable but important for future precision cosmology.

Abstract

Studying galaxies at different cosmic epochs entails several observational effects that need to be taken into account to compare populations across a large time span in a consistent manner. We use a sample of 166 nearby galaxies that hosted type Ia supernovae (SNe Ia) and have been observed with the integral field spectrograph MUSE through the AMUSING survey. Here, we present a study of the systematic errors and bias in the host stellar mass with increasing redshifts that are generally overlooked in SNe Ia cosmological analyses. We simulate observations at different redshifts (0.1<z<2.0) using four photometric bands (griz, similar to the Dark Energy Survey-SN program) to then estimate the host galaxy properties across cosmic time. We find that stellar masses are systematically underestimated as we move towards higher redshifts, due mostly to different rest-frame wavelength coverage, with differences reaching 0.3 dex at z~1. We have used the newly derived corrections as a function of redshift to correct the stellar masses of a known sample of SN Ia hosts and derive cosmological parameters. We show that these corrections have a small impact on the derived cosmological parameters. The most affected is the value of the mass step $\Delta_M$, which is reduced by $\sim$0.004 (6% lower). The dark energy equation of state parameter $w$ changes by $\Delta w \sim $0.006 (0.6% higher) and the value of $\Omega_m$ increases at most by 0.001 ($\sim$0.3%), all within the derived uncertainties of the model. While the systematic error found in the estimate of the host stellar mass does not significantly affect the derived cosmological parameters, it is an important source of a systematic error that one should correct for as we enter a new era of precision cosmology.