Mode analysis of cosmological perturbations with the $E$-model $\alpha$-attractor inflaton potentials

TL;DR

This paper performs a detailed mode analysis of inflationary perturbations using $E$-model $ ext{alpha}$-attractor potentials, calculating key cosmological parameters and comparing results with observational data.

Contribution

It introduces a comprehensive $k$-mode analysis of single-inflaton slow-roll inflation with quantum fluctuations using $E$-model $ ext{alpha}$-attractor potentials, aligning theoretical predictions with observations.

Findings

Calculated $n_s$ and $r$ values consistent with universal $ ext{alpha}$-attractor formulas.

Obtained $n_s=0.956908$ and $r=0.005571$ at $k=10^6$ for $n=1$.

Results compatible with Planck-2018 and ACT-2020 observational data.

Abstract

We have carried out detailed $k$-mode analysis of single-inflaton slow-roll inflationary perturbations including quantum fluctuations by setting up non-linear coupled differential equations of inflaton field ($\phi$), its perturbation ($\delta\phi$) and the metric perturbation (the Bardeen potential, $\Phi_B$), and calculated the number of e-folds ($N$), scalar spectral index ($n_s$), tensor spectral index ($n_h$), scalar power spectrum ($\Delta_s$), tensor power spectrum ($\Delta_h$), tensor-to-scalar ratio ($r$) and the Hubble parameter ($H$) for different $k$ values at the horizon crossing. In these calculations we have employed the $E$-model $\alpha$-attractor potentials which are found to display slow-roll behaviour. The values of $n_s$ and $r$ obtained by us are consistent with those given by the well-known universal $\alpha$-attractor formulae. We got $n_s = 0.956908$ and $r= 0.005571 $ at $k = 10^6$ Planck unit for the value of the potential parameter $n = 1$. These can be compared with the Planck-2018 data viz., $n_s = 0.9649\pm 0.0042$ at $68\%$ CL, $r<0.064$ at $95\%$ CL and ACT-2020 data viz., $n_s = 0.9691\pm 0.0041$ at $68\%$ CL.