Analytic Gravitational Wave Spectrum in Next-to-Minimal Bouncing Cosmology

TL;DR

This paper introduces the next-to-minimal bouncing cosmology (NMBC), which predicts a broken power-law gravitational wave spectrum, potentially detectable and free from trans-Planckian issues, using a novel matrix-representation analytical method.

Contribution

The paper presents the NMBC model with an added contraction phase, deriving a closed-form spectrum and demonstrating its consistency and detectability with current bounds.

Findings

NMBC predicts a broken power-law SGWB spectrum

All models satisfy N_{ m eff} bounds and avoid trans-Planckian problems

Potential for detection in astrophysical and laboratory experiments

Abstract

Bouncing cosmology offers a singularity-free alternative to inflation, but its minimal realization-comprising only four cosmic phases-predicts a simple power-law stochastic gravitational-wave background (SGWB) with a narrow observational window. We introduce the next-to-minimal bouncing cosmology (NMBC), which adds an extra early contraction phase that imprints a broken power-law feature in the SGWB spectrum, enhancing detectability. Using our matrix-representation method grounded in an inequality algebra, we derive a closed-form expression for the NMBC SGWB spectrum. From this analytical result, we show that all NMBC models satisfying the current \(\Delta N_{\rm eff}\) bound \(\Omega_{\rm GW}h^2(f)<1.7\times10^{-6}\) automatically avoid the trans-Planckian problem, \(\rho_{s\downarrow}^{1/4}<0.79\,m_{\rm pl}\). These findings establish the NMBC as a self-consistent, self-contained framework capable of generating a potentially detectable SGWB in both astrophysical and laboratory searches, and demonstrate the broad utility of our matrix-representation method for future SGWB analyses in multi-phase cosmologies.