Information Structure of Spacetime Vacuum Levels and Gravitational Information Dynamics

This paper explores the possibility that the structure of spacetime is fundamentally determined by information constraints associated with vacuum energy states. Building on previous work on gravity–vacuum energy correspondence and holographic information limits, we propose that vacuum energy levels correspond to discrete configurations of spacetime information. In this view, spacetime geometry, vacuum energy, and gravitational dynamics may emerge from deeper information-theoretic structures. Black hole thermodynamics suggests that the information content of a region of spacetime is bounded by its surface area rather than its volume. If spacetime has a finite information capacity, the vacuum state of spacetime may represent a particular configuration of that information. Extreme gravitational processes such as black hole collapse may compress spacetime information toward the holographic bound. When this information density approaches a critical limit, the spacetime configuration may become unstable and transition to a new information state corresponding to a different vacuum energy level. In this framework, gravitational energy drives transitions between spacetime information configurations. Black holes may therefore act as transformation regions where spacetime information reorganizes, potentially generating new expanding spacetime domains. This perspective suggests that cosmogenesis, vacuum energy transitions, and gravitational dynamics may all be manifestations of a deeper information structure underlying spacetime.