A novel way of constraining the α-attractor chaotic inflation through Planck data
Abstract
Defining a scale of k-modes of the quantum fluctuations during inflation through the dynamical horizon crossing condition k = aH we go from the physical t variable to k variable and solve the equations of cosmological first-order perturbations self consistently, with the chaotic α-attractor type potentials. This enables us to study the behaviour of ns, r, nt and N in the k-space. Comparison of our results in the low-k regime with the Planck data puts constraints on the values of the α parameter through microscopic calculations. Recent studies had already put model-dependent constraints on the values of α through the hyperbolic geometry of a Poincar\'e disk: consistent with both the maximal supergravity model N=8 and the minimal supergravity model N=1, the constraints on the values of α are 13, 23, 1, 43, 53, 2, 73. The minimal N=1 supersymmetric cosmological models with B-mode targets, derived from these supergravity models, predicted the values of r between 10-2 and 10-3. Both in the E-model and the T-model potentials, we have obtained, in our calculations, the values of r in this range for all the constrained values of α stated above, within 68\% CL. Moreover, we have calculated r for some other possible values of α both in low-α limit, using the formula r=12αN2, and in the high-α limit, using the formula r=4nN, for n=2 and 4. With all such values of α, our calculated results match with the Planck-2018 data with 68\% or near 95\% CL.
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