lobal Journal of Science Frontier Research, A: Physics and Space Science, Volume 24 Issue 4

This view challenges current cosmological interpretations and suggests that, instead of a universe that renews itself, we are observing a universe that is slowly dying, replicating its memories in its last stellar expansions before finally succumbing to total cosmic inactivity. VIII. I nteraction between A xion and UNO The theory suggests that, in the early stages of the universe, Axion particles began to interact with UNO particles. This process involved the transfer of energy from Axion particles to UNO particles, resulting in oscillations that transformed that energy into electromagnetic radiation — light. This phenomenon gave rise to the observable universe, creating the foundation for the existence of the luminous radiation we know today. IX. C old S pot The image also highlights the "cold spot" of the observable universe, a region where the cosmic microwave background radiation is affected by the presence of the dead universe. This low-temperature region manifests as a "thermal anomaly," caused by the gravitational influence of the dead universe on our visible universe. The existence of Axions is predicted by physical theories to be produced in extreme environments, such as in stellar cores during events like supernovae. These particles, when emitted by stars into the universe, could briefly interact with surrounding magnetic fields, temporarily converting into photons and potentially becoming detectable. "In the specific case of Betelgeuse, a red giant star on the verge of becoming a supernova, MIT conducted research to search for axions due to its condition as a 'natural factory' of these particles. Utilizing the NuSTAR space telescope, the researchers searched for axion signatures in the form of X-ray photons but found no detectable signals. These results significantly narrowed the possible characteristics of axions, setting more stringent constraints on their existence and properties." A search led by MIT for axions from the nearby star Betelgeuse (pictured here) yielded no results, significantly narrowing the search for hypothetical dark matter particles. Credits: Image: MIT News Collage. Image of Betelgeuse courtesy of ALMA (ESO/NAOJ/NRAO)/E. O'Gorman/P. Kervella The conclusions show that if axions exist, they interact very weakly with photons, making them difficult to detect. The research suggests that future investigations should explore other energy ranges, such as gamma rays, especially in events like supernovae. However, in 2021, the results of these searches did not detect the expected axion signatures in the form of X-ray photons. These findings indicated that ultralight axions, which could interact with photons across a wide range of energies, were excluded by the research. Global Journal of Science Frontier Research ( A ) XXIV Issue IV Version I Year 2024 41 © 2024 Global Journals Astrophysics of Shadows: The Dead Universe Theory — An Alternative Perspective On The Genesis of the Universe