Constranits of dynamical dark energy models from different observational datasets

Abstract: The measurements of baryon acoustic oscillation by the Dark Energy Spectroscopic Instrument Data Release 2 indicate that dark energy may be a dynamical quantity with a time-varying equation of state. This challenges the core assumptions of the $\Lambda$CDM model and has generated significant interest in dynamical dark energy models. Therefore, studying the parameterization of the equation of state for dynamical dark energy is crucial. Existing work has achieved fruitful results in the dark energy models, exploring various parameterization forms, but it is relatively scattered and lacks systematic parameter constraints based on the latest dataset combinations. We use the $\Lambda$CDM as a baseline model and carry out rigorous statistical constraints on key cosmological parameters for seven representative parameterization models. Planck PR4 and DESI DR2 observations are incorporated into our study. We use three dataset combinations: CMB+BAO+PantheonPlus, CMB+BAO+DES-Y5, and CMB+BAO+Union3. The ${H}{0}$ and ${\sigma }{8}$ values of all dynamical dark energy models are lower than the $\Lambda$CDM model, indicating that our results may not effectively alleviate ${H}{0}$ tension, but can significantly reduce ${\sigma }{8}$ tension. By comparing the $\chi^2$ and the Akaike Information Criterion obtained for each model, we demonstrate that the linear Chevallier-Polarski-Linder parameterization model is not the optimal choice in all cases. Specifically, when combined with the CMB+BAO+DES-Y5 dataset, the Barboza-Alcaniz, Logarithmic, and Exponential models demonstrate superior statistical fitting performance compared to the $\Lambda$CDM model. The Barboza-Alcaniz model shows a great advantage in fitting performance, leading to the most significant improvement.