Constraining an Early Dark Energy Motivated Quintessential α-Attractor Inflaton Potential

Abstract

We construct a new model of quintessential α attractor inflation in conjunction with the features of non-oscillating early dark energy (EDE). Slow-roll plateau of this model is obtained, and analyzed in k-space, through the inflaton field and its first-order perturbation over a quasi de-Sitter metric fluctuation in the range k=0.001-0.009 Mpc-1. The estimated cosmological parameters are found to obey Planck+BICEP2/Keck bounds with 68\% CL with the required trend of spectral tilts in the ns-r parametric space. We verify that, the inclusion of the EDE does not significantly affect the observed parameters. Its presence manifests in obtaining improved values of the energy scale of inflation (M) and the present-day vacuum density (V). They are found to be M=5.58× 10-4-4.57× 10-3 MP and V=1.042× 10-119-4.688× 10-116 MP4. However, the α-parameter is drastically constrained in two ways. Its lower end is fixed by the consistency analysis of the k-mode equations, while the upper end is evaluated as a derived expression of α-cut-off through the aspects of EDE viz., the effects of Enhanced Symmetry Point (ESP) in the potential during inflation. Improvised range of α is found to be 0.001≤α<0.1 for the model parameters γ and n lying within 0.01≤γ≤ 0.09 and 8≤ n≤ 10 respectively. These ranges are shown to be essential for satisfying the COBE/Planck normalized energy scale of inflation and the Planck-value of present-day vacuum density. If we choose γ=0.0818 and n=8, then we get 0.001≤α≤ 0.0186. Thus, the lower and upper limits of α are diminished substantially, compared with those in the earlier studies.