Gravitational Wave Constraints on the Bouncing Energy Scale of Big Bounce Cosmology
Abstract
Big bounce cosmology provides a solution to the Universe's initial singularity, and stochastic gravitational wave background (SGWB) searches offer a promising avenue for testing this paradigm. In this work, we establish an analytical relation between the bouncing energy scale, s1/4, and SGWB spectrum, GW(f)h2, for big bounce cosmology. By combining sensitivities from major GW detectors (e.g., Planck/BICEP, PTA, and LIGO/Virgo across low, medium, and high frequencies, respectively), we provide the first systematic GW constraint on s1/4. Our results show that the region -13 < w1 < -0.17 is excluded by current SGWB searches, given the constraint s1/4 > 1~TeV, where w1 is the contraction-phase equation of state parameter. Additionally, no detectable SGWB can be generated for 0.038 < w1 < ∞ with s1/4 < 1016~TeV. We identify a window, -0.17 < w1 < 0.038, in which a detectable SGWB can be produced, disfavoring nearly all big bounce models except for the matter-dominated contraction model (w1 0).
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