Inflation without an Inflaton II: observational predictions

TL;DR

This paper computes the scalar power spectrum in an inflation model driven solely by a de Sitter background, linking fluctuations to quantum effects and predicting inflationary parameters without a fundamental inflaton field.

Contribution

It provides a complete second-order calculation of scalar fluctuations sourced by tensor perturbations in the inflation without inflaton framework, establishing observational predictions and bounds.

Findings

Scalar spectrum is scale-invariant without a fundamental scalar.

Inflation scale is linked to observed fluctuation amplitude, predicting $H_{inf}$.

Quantum effects impose an upper bound on the number of inflation e-folds.

Abstract

We present a complete computation of the scalar power spectrum in the \emph{inflation without inflaton} (IWI) framework, where the inflationary expansion is driven solely by a de~Sitter (dS) background and scalar fluctuations arise as second-order effects sourced by tensor perturbations. By explicitly deriving and numerically integrating the full second-order kernel of the Einstein equations, we obtain a scale-invariant scalar spectrum without invoking a fundamental scalar field. In this framework, the amplitude of the scalar fluctuations is directly linked to the scale of inflation. More precisely, we show that matching the observed level of scalar fluctuations, $\Delta_{\phi}^2(k_\ast)\approx 10^{-9}$ at Cosmic Microwave Background (CMB) scales, fixes the inflationary energy scale $H_{\rm inf}$ as a function of the number of observed e-folds $N_{\rm obs}$. For $N_{\rm obs}\simeq 30 - 60$, we find $H_{\rm inf} \simeq 5\times 10^{13}\,\mathrm{GeV} - 2\times 10^{10}\,\mathrm{GeV}$, corresponding to a tensor-to-scalar ratio $r \simeq 0.01 - 5\times 10^{-9}$. In particular, requiring consistency with instantaneous reheating, we predict a number of e-folds of order~$\mathcal{O}(50)$ and an inflationary scale $H_{\rm inf} \simeq 10^{11}\,\mathrm{GeV}$. We also incorporate in our framework the quantum break-time of the dS state and show that it imposes an upper bound on the number of particle species. Specifically, using laboratory constraints on the number of species limits the duration of inflation to $N_{\rm obs}\lesssim 126$ e-folds. These results establish the IWI scenario as a predictive and falsifiable alternative to standard inflaton-driven models, linking the observed amplitude of primordial fluctuations directly to the quantum nature and finite lifetime of dS space.