TITLE:
A Resolution to the Vacuum Catastrophe: The Role of the Omniom Vacuum
AUTHORS:
Nader Butto
KEYWORDS:
Cosmological Constant, Vacuum Density, Dark Energy Density, Singularity Density, Fundamental Constants
JOURNAL NAME:
Journal of High Energy Physics, Gravitation and Cosmology,
Vol.11 No.3,
July
24,
2025
ABSTRACT: The cosmological constant problem, or vacuum catastrophe, highlights the enormous gap between observed vacuum energy density and the vastly larger values predicted by quantum field theory, often differing by 120 orders of magnitude. This discrepancy presents a significant challenge to our understanding of the universe. Originally introduced by Einstein to allow for a stationary universe, the cosmological constant was abandoned after Hubble’s discovery of the universe’s expansion, only to be revisited with the discovery of the accelerating expansion, driven by dark energy. Today, the cosmological constant is regarded as a low-energy effective theory of dark energy, but it fails to explain the full nature of the vacuum. This work proposes the concept of the Omniom vacuum, a primordial state that existed before the Big Bang, with a static density estimated through fundamental constants to be approximately 9.51 × 10−27 kg/m3. This Omniom vacuum served as the infinite container within which the universe’s expansion began. As the universe expanded, part of this vacuum condensed into matter and dark matter, while the remaining portion evolved into dark energy, which has a lower density than the original Omniom vacuum. The density of dark energy is observed to be around 5.91 × 10−27 kg/m3, whereas the Omniom vacuum before the Big Bang maintained a higher density. Additionally, at the moment of the singularity, the universe’s density spiked to the Planck density, approximately 5.155 × 1096 kg/m3, revealing a stark contrast with the more stable Omniom vacuum. This framework provides a new perspective on vacuum energy and cosmology, distinguishing between the primordial Omniom vacuum, the dark energy driving current cosmic expansion, and the extreme density of the singularity at the universe’s birth. By clarifying these distinctions and calculating the density of the Omniom vacuum through constants like the speed of light, vacuum permittivity, and gravitational constant, this work offers fresh insight into the cosmological constant problem and a pathway toward resolving the mystery of the universe’s accelerating expansion.