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

This light could form the basis for the observable universe we know. The Dead Universe is described as a completely dark space, composed of Axion particles, UNO particles, and dark matter. Additionally, there are dark radiation stars, dark nebulas, and planets immersed in darkness and chaos. These characteristics align with the initial hypothesis of a Dead Universe composed of inert stellar elements. Simultaneously, the second hypothesis suggests that this darkness and chaos result from stellar death on a massive scale. In both scenarios, the Dead Universe remains a vastly unknown structure where life and light are rare exceptions in a predominantly extinguished cosmos. The representation in the image is based on the "Dead Universe" theory, a new interpretation of the cosmos' origin and evolution. This hypothesis suggests that our universe may have originated from the remnants of a previous universe and that we are merely remaining fragments of a cosmos that entered a state of stellar death or that, in its original nature, was essentially dead. Thus, we inhabit an immense black hole, while countless supermassive bodies are situated on the margins of this Dead Universe. Possibly, supermassive black holes exist, some of which, in a single unit, may be larger than the observable universe. Behind the primary conception of the Dead Universe, in the sense of stellar death, numerous galaxies are inert. The dating of the Big Bang, estimated at 13.8 billion years, may be reconsidered to understand that the universe's structure may have much more time. Studying these dead galaxies, just as we study dinosaur fossils, and with the help of technology and quantum computing, we may conclude that we have been wrong for more than 100 years. In the second hypothesis, as proposed in this article, the Dead Universe theory assumes a different perspective, while the Big Bang model completely loses its validity as a paradigm for studying this primitive structure. In this hypothesis, the Dead Universe still exists in hypothetical primitive particles, such as UNO, Axion, dark energy, and dark matter. Figure 4: The images in this article were generated using computational technology designed to visually represent complex astrophysical concepts. Each visualization is created through precise algorithms to reflect the intricacies of the "Dead Universe" theories, utilizing specific parameters based on scientific data and theoretical models to ensure the most accurate representation possible within the theoretical context presented. Image Credits: Global Journals. https://globaljournals.org/ We can formulate a simplified equation to describe the rate of energy conversion from Axions to light through interaction with UNO particles: The image above illustrates the theoretical interaction between Axion particles and UNO particles, which could have led to the formation of the observable universe. Axion particles form a dark matter field that, when interacting with UNO particles, results in the conversion of energy into electromagnetic radiation, or light, thus creating the universe we know. Between the observable universe and the dead universe, there is a layer of plasma composed of Axion particles and another layer of UNO particles. The Axion plasma, which is the origin of the dark matter that forms black holes, acts as a barrier, while the UNO plasma, being invisible, allows for the separation and interaction Global Journal of Science Frontier Research ( A ) XXIV Issue IV Version I Year 2024 39 © 2024 Global Journals Astrophysics of Shadows: The Dead Universe Theory — An Alternative Perspective On The Genesis of the Universe