Resolving Matter-Antimatter Asymmetry and Quantum Nonlocality: A Divided Pre-Universe Model

This study introduces a novel framework that simultaneously addresses the prevailing matter-antimatter asymmetry and the phenomenon of quantum nonlocality observed in modern physics. By proposing a divided pre-universe model, the paper suggests that the initial entanglement between particles establishes a unique tagging process, where each particle is imprinted with a quantum identity linked to a common origin. These tags form a network of 'force lines' that guide the radial paths of particles, allowing for instantaneous updates in quantum correlations despite particles moving at subluminal speeds. Through this approach, the model reconciles the apparent superluminal effects in quantum mechanics with the relativistic limitations on mass/energy, offering a unified explanation for the underlying processes that govern the evolution of the early universe.