Pre-Big Bang Informational Compression and the Delayed Release of Antimatter

This work introduces an informational-compression cosmological model in which the pre-Big Bang universe existed as a maximally compressed informational configuration, described as an “informational spring,” storing matter and antimatter as latent, superposed informational states. In this framework, the Big Bang does not create particles, nor is it triggered by external perturbations. Instead, it arises as an internal instability of maximal informational compression. In the hyper-compressed regime, even an infinitesimal vibrational differentiation cannot remain localized and necessarily propagates across the entire informational configuration. This global propagation manifests initially as an extreme thermodynamic regime, inherent to informational hyper-compression. The resulting heat is not dissipative and not a byproduct of expansion, but an emergent condition that renders compressed information structurally differentiable. Only once informational differentiation becomes thermodynamically accessible does the informational spring lose stability, triggering a dynamical, non-simultaneous release of latent informational modes. The expansive mode activates at t ≈ 0 and manifests as matter, while a specular compressive mode is released after a finite temporal delay Δt, producing antimatter. This intrinsic delay provides a natural, symmetry-based explanation for the observed matter–antimatter imbalance without invoking strong CP violation, exotic baryogenesis mechanisms, or physics beyond the Standard Model. The model predicts falsifiable observational signatures, including dual-phase imprints in the cosmic microwave background (CMB), such as subtle power-spectrum modulations and large-scale directional anisotropies. Overall, the framework presents a coherent, information-centric mechanism linking pre-Big Bang compression dynamics, thermodynamic emergence, and cosmological asymmetry within a unified and testable theoretical structure.