Tachyonic dark energy- Constraints from current observations
Authors
Ramanpreet Singh, Athul C N, H. K. Jassal
Categories
Abstract
Recent observations from the Dark Energy Spectroscopic Instrument (DESI) survey have reignited the debate on the true nature of dark energy, challenging the standard cosmological constant model of cosmology. The results suggest a preference for dark energy to be dynamical rather than a cosmological constant. Several recent analyses of DESI data indicate that the universe's expansion may not be accelerating in the way suggested by supernova based cosmology. Motivated by these studies, we investigated a tachyon type scalar field $φ$ as a model for dark energy, assuming an exponential potential for the field and performed parameter estimation using Markov Chain Monte Carlo (MCMC) techniques. Such a model offers solutions that have $w \sim -1$ and are decelerating without requiring a phantom like equation of state. The present day value of the equation of state parameter is treated as a free parameter; however, for the reference model, we fix its present value to $-1$. The analysis is carried out using the latest Supernovae dataset (Pantheon+) and BAO measurements from DESI. The results show that both types of datasets consistently predict a turnaround in the equation of state, regardless of whether $w_{φ0}$ is treated as a free parameter or fixed to $-1$. The corresponding deceleration parameter also exhibits a future turnaround for both datasets when $w_{φ0}$ is free. However, in the reference model with $w_{φ0} = -1$, the deceleration parameter instead approaches $-1$ asymptotically. A model comparison using the Akaike and Bayesian Information Criteria shows that the Pantheon+ dataset favors the free $w_{φ0}$ scenario, while BAO observations prefer the $w_{φ0} = -1$ case. This indicates a disagreement in the future evolution trends predicted by the two datasets within the tachyon type dark energy model.
Tachyonic dark energy- Constraints from current observations
Categories
Abstract
Recent observations from the Dark Energy Spectroscopic Instrument (DESI) survey have reignited the debate on the true nature of dark energy, challenging the standard cosmological constant model of cosmology. The results suggest a preference for dark energy to be dynamical rather than a cosmological constant. Several recent analyses of DESI data indicate that the universe's expansion may not be accelerating in the way suggested by supernova based cosmology. Motivated by these studies, we investigated a tachyon type scalar field $φ$ as a model for dark energy, assuming an exponential potential for the field and performed parameter estimation using Markov Chain Monte Carlo (MCMC) techniques. Such a model offers solutions that have $w \sim -1$ and are decelerating without requiring a phantom like equation of state. The present day value of the equation of state parameter is treated as a free parameter; however, for the reference model, we fix its present value to $-1$. The analysis is carried out using the latest Supernovae dataset (Pantheon+) and BAO measurements from DESI. The results show that both types of datasets consistently predict a turnaround in the equation of state, regardless of whether $w_{φ0}$ is treated as a free parameter or fixed to $-1$. The corresponding deceleration parameter also exhibits a future turnaround for both datasets when $w_{φ0}$ is free. However, in the reference model with $w_{φ0} = -1$, the deceleration parameter instead approaches $-1$ asymptotically. A model comparison using the Akaike and Bayesian Information Criteria shows that the Pantheon+ dataset favors the free $w_{φ0}$ scenario, while BAO observations prefer the $w_{φ0} = -1$ case. This indicates a disagreement in the future evolution trends predicted by the two datasets within the tachyon type dark energy model.
Authors
Ramanpreet Singh, Athul C N, H. K. Jassal
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