We propose an informational-compression cosmological model in which the pre-Big Bang universe is described as a maximally compressed informational configuration, conceptualized as an “informational spring. ” In this framework, matter and antimatter exist as latent, superposed informational states within the compressed substrate. The Big Bang arises not from external perturbations but from an internal instability triggered by infinitesimal vibrational differentiation. In the hyper-compressed regime, even minimal vibrational perturbations cannot remain localized and propagate globally across the informational configuration. This global propagation generates an extreme thermodynamic regime inherent to maximal compression. The resulting heat is not a byproduct of expansion but an emergent condition that enables informational differentiation. Once differentiation becomes thermodynamically accessible, the informational spring loses stability, leading to a dynamical, non-simultaneous release of latent modes. The expansive mode is released at t 0 and manifests as matter, while a specular compressive mode is released after a finite delay t, manifesting as antimatter. This intrinsic temporal delay provides a natural, symmetry-based explanation for the observed matter–antimatter asymmetry without requiring new CP-violating interactions or physics beyond the Standard Model. The model predicts potentially observable signatures, including subtle modulations in the cosmic microwave background power spectrum and large-scale directional anisotropies. Overall, the framework offers a coherent informational mechanism linking pre-Big Bang compression, thermodynamic emergence, and cosmological asymmetry within a unified and testable structure.
Giuseppe Junior Greco (Fri,) studied this question.