This paper introduces "MQ-Coherence", a novel theoretical framework that approaches cosmology and fundamental physics through the lens of quantum information theory. Instead of viewing the early universe through purely geometric or classical thermodynamic models, the author proposes that the universe originates from an active, informationally structured quantum vacuum (the Quantum Informational Background). In this model, black holes serve as cosmic information gateways capable of seeding new "child" universes, carrying over a permanent informational imprint that sets their fundamental constants and fixes the value of the cosmological constant. A key feature of the framework is its strict mathematical rigidity, operating with zero free parameters. The paper bridges cosmic scales with subatomic physics by mapping the phenomenon of quark confinement in Quantum Chromodynamics (QCD) directly onto a quantum error-correcting algorithm known as a Surface Code. Within this context, hadrons (such as protons and neutrons) are interpreted as protected "logical qubits" that shield the universe's fundamental information from thermal noise and decoherence. The Big Bang singularity is redefined not as a point of infinite density, but as a state of maximum thermal noise where all quantum error-correction structures collapse. Finally, the framework delivers four specific, numerically falsifiable observational predictions. These include a predictable distribution of cosmological constants, a specific mass scale and a slight structural excess in the mass function of supermassive black holes, and the persistence of anomalous long-range quantum correlations at cosmological scales, offering concrete pathways for future astronomical surveys to test the validity of the model.
Luciano La Guzzi (Tue,) studied this question.