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

Axions, proposed as hypothetical dark matter particles, could explain the composition of 85% of the universe. The theory suggests that stars like Betelgeuse, in their final stages, could function as "natural factories" of axions, which, when interacting with magnetic fields, could convert into detectable photons. X. UNO H ypothetical P article The UNO particle is conceptualized as the "zero equation" of all particles, representing a primordial state of masslessness. In the initial quantum fluctuations of the universe, the UNO could have manifested as a fundamental entity. This entity, by dividing or interacting with the quantum vacuum, gave rise to all other particles, generating the complexity of the universe we observe today. The axion, being a hypothetical particle with nearly zero mass, can be considered one of the first elements to emerge in the cosmos after the manifestation of the UNO. Although practically undetectable due to its extremely light mass, the axion could have acted as a multiplier, triggering the processes that led to the formation of more complex particles and eventually the structuring of the universe. Combining these concepts, the UNO, by its nature as the "zero equation" (a state prior to what we consider particles), provides the foundation upon which particles like the axion manifested. In this way, the axion could be seen as the first tangible step in the evolution of the cosmos, directly influencing the formation of matter and the expansion of the universe according to contemporary particle physics models. The UNO particle, described as the "zero equation" of all particles, can be understood as a primordial state of perfect symmetry. This state would not be exactly "nothing," but rather a form of infinite potential, containing within it all the possibilities for the manifestation of particles and forces. This concept can be related to the idea of perfect symmetry in particle physics, where the early universe was highly symmetrical, and only after the breaking of this symmetry did particles and forces as we know them emerge. To deepen the concept of how the UNO particle divides or interacts to create other particles, we can compare it to the Higgs Field. The Higgs Field is known for giving mass to particles through interaction with the Higgs boson. Similarly, the UNO could be seen as a fundamental field that, through a "symmetry break," gave rise to other particles, such as quarks, leptons, and bosons. This symmetry break could occur through a process of intense quantum fluctuations in the early moments of the universe. These fluctuations would allow the UNO to "fragment" into various particles, each with its own properties of mass, charge, and interaction. The UNO Particle theory can be integrated into the standard model of particle physics, particularly concerning the Higgs Field. While the Higgs Field is responsible for giving mass to particles through interaction with the Higgs boson, the UNO can be seen as the precursor to this field. In other words, the UNO would be the fundamental state that, upon "breaking," created both the Higgs Field and the particles that interact with it. Figure 6: The images in this article were generated using computing technology, designed to visually represent complex astrophysical concepts. Each visualization is created through precise algorithms to reflect the complexities of the "Dead Universe" theories, utilizing specific parameters based on scientific data and theoretical models to ensure the most accurate representation possible within the presented theoretical context. Image credits: Global Journals . https://globaljournals.org Global Journal of Science Frontier Research ( A ) XXIV Issue IV Version I Year 2024 42 © 2024 Global Journals Astrophysics of Shadows: The Dead Universe Theory — An Alternative Perspective On The Genesis of the Universe