Slow-roll inflation in (dual) Kaniadakis cosmology

TL;DR

This paper explores how Kaniadakis entropy modifies slow-roll inflation dynamics, deriving constraints on the deformation parameter from observational data and examining potential observable imprints on primordial perturbations.

Contribution

It introduces a framework for inflation within Kaniadakis cosmology, analyzing the effects of the deformation parameter on inflationary predictions and observational consistency.

Findings

Viable slow-roll inflation scenarios are compatible with Planck data for certain $ppa$ values.

Stringent bounds on the deformation parameter $ppa$ are derived from observational constraints.

Kaniadakis cosmology can produce primordial power spectra consistent with current observations.

Abstract

We investigate slow-roll inflation within the framework of Kaniadakis and dual Kaniadakis cosmology, where the usual entropy formalism is generalized through a deformation parameter $\kappa$. By deriving the modified Friedmann equations and the corresponding inflationary dynamics induced by Kaniadakis entropy, we analyze the deviations from standard inflation arising from $\kappa$-corrections. We compute the scalar and tensor spectral indices, the tensor-to-scalar ratio, and examine the observational constraints on the deformation parameter. Our results show that consistency with current observational data imposes stringent bounds on the deformation parameter $\kappa$. In the standard Kaniadakis formulation, viable slow-roll inflationary scenarios compatible with the Planck constraints on the scalar spectral index $n_s$ and the tensor-to-scalar ratio $r$ can be obtained, although the allowed values of $\kappa$ are strongly suppressed. For the dual Kaniadakis formulation, we find that the primordial power spectrum of scalar perturbations can remain consistent with observational data within certain parameter regions. We also verify the compatibility of the predicted scalar power spectrum with the latest Planck results and discuss the phenomenological implications of the $\kappa$-induced corrections. These findings suggest that Kaniadakis cosmology may leave potentially observable imprints on primordial perturbations, providing a possible connection between non-extensive thermodynamics and the physics of the early universe.