Cosmological Constraints on Thermal Friction of Axion Dark Matter

Abstract

In this paper, we investigate the process in which axion dark matter undergoes thermal friction, resulting in energy injection into dark radiation, with the aim of mitigating the Hubble tension and large-scale structure tension. In the early universe, this scenario led to a rapid increase in the energy density of dark radiation; in the late universe, the evolution of axion dark matter is similar to that of cold dark matter, with this scenario resembling decaying dark matter and serving to ease the large-scale structure tension. We employ cosmological observational data, including cosmic microwave background (CMB), baryon acoustic oscillation (BAO), supernova data (SNIa), H0 measurement from SH0ES, and S8 from the Dark Energy Survey Year-3 (DES), to study and analyze this model. Our results indicate that the thermal friction model offers partial alleviation of the large-scale structure tension, while its contribution on alleviating Hubble tension can be ignored. The new model yields the value of S8 is 0.795 0.011 at a 68% confidence level, while the model yields a result of 0.8023 0.0085. In addition, the new model exhibits a lower 2tot value, with a difference of -2.60 compared to the model. Additionally, we incorporate Lyman-α data to re-constrain the new model and find a slight improvement in the results, with the values of H0 and S8 being 68.76+0.39-0.35 km/s/Mpc and 0.791 0.011 at a 68% confidence level, respectively.