Mapping the Hubble flow from z∼0 to z∼7.5 with H <scp>ii</scp> Galaxies
Ricardo Chávez, R. Terlevich, E. Terlevich, A. L. González-Morán, David Fernández-Arenas, Fabio Bresolin, M. Plionis, Spyros Basilakos, R. Amorín, Mario Llerena
Abstract
ABSTRACT Over twenty years ago, Type Ia Supernovae (SNIa) observations revealed an accelerating Universe expansion, suggesting a significant dark energy presence, often modelled as a cosmological constant, $\Lambda$. Despite its pivotal role in cosmology, the standard lambda cold dark matter ($\Lambda$CDM) model remains largely underexplored in the redshift range between distant SNIa and the cosmic microwave background (CMB). This study harnesses the JWST’s advanced capabilities to extend the Hubble flow mapping across an unprecedented redshift range, from $z \approx 0$ to $z \approx 7.5$. Using a data set of 231 H ii galaxies and extragalactic H ii regions, we employ the $\text{L}\!-\!\sigma$ relation that correlates the luminosity of Balmer lines with their velocity dispersion, to define a competitive technique for measuring cosmic distances. This approach allows the mapping of the Universe expansion history over more than 12 billion years, covering 95 per cent of its age. Our analysis, using Bayesian inference, constrains the parameter space $\lbrace h, \Omega _m, w_0\rbrace = \lbrace 0.731\pm 0.039, 0.302^{+0.12}_{-0.069}, -1.01^{+0.52}_{-0.29}\rbrace$ (statistical) for a flat universe. Our results provide new insights into cosmic evolution and imply a lack of change in the photokinematical properties of the young massive ionizing clusters in H ii galaxies across most of the history of the Universe.