Abstract This paper introduces the Fractal Universe Theory (FUT), a comprehensive unified framework that redefines the physical vacuum as an active Fractal Dielectric Network (FDN) rather than a passive, smooth manifold 1. We postulate that the fundamental substance of the universe is informational connectivity, characterized by a complex vacuum impedance () that governs energy propagation across all scales. In the subatomic regime, we provide a first-principles solution to the Yang-Mills Mass Gap problem 5 by demonstrating that mass emerges as a topological resonance within the discrete nodes of the FDN. Specifically, we show that the observed mass hierarchy in quantum chromodynamics—exemplified by the ratio between tensor and scalar glueball states 9—is a direct consequence of a network spectral dimension . To bridge the gap between quantum scales and general relativity, we derive the T-Factor (), a universal scaling operator based on the ratio between the Planck length and the Hubble horizon 1. By applying this operator, we resolve the 120-order-of-magnitude vacuum energy discrepancy, yielding a predicted Dark Energy density of that aligns with cosmological observations 3. A major breakthrough of this framework is the resolution of the Hubble Tension. We demonstrate that the expansion rate is a scale-dependent transfer function of the FDN's impedance. The expansion's logarithmic amplitude is derived from the fine-structure constant () 8, eliminating the systematic discrepancy in local measurements by linking cosmic expansion directly to quantum coupling 2, 4. Furthermore, the theory derives the MOND critical acceleration () 7 as the minimum structural impedance floor of the vacuum, effectively eliminating the requirement for non-baryonic dark matter. Finally, the FUT offers a specific, falsifiable prediction: a residual phase noise signature in the vacuum. This framework suggests that gravity, inertia, and nuclear forces are emergent manifestations of a single, self-similar informational infrastructure, marking a paradigm shift from traditional field theory to Fractal Metric Engineering 1.
Tomas Mariano Romero (Tue,) studied this question.