The Origin of the Universe: An Explanation Through the First Atom and Antiatom

Introduction

The concept of the Big Bang as the origin of the universe remains the dominant theory in cosmology. However, recent insights into the universe suggest a more intricate starting point: the merging of Hydrogen and Antihydrogen. This article delves into how these fundamental particles first manifested and how they paved the way for the Big Bang and the formation of our universe.

The First Atom and Antiatom: Hydrogen and Antihydrogen

According to the current scientific understanding, the first atom in the universe was not just hydrogen, but a pair of hydrogen and antihydrogen. This was a result of the fundamental properties of the universe itself, which arise from the infinite nature of space and time. The theory posits that due to the symmetry of space-time, the universe contains equal amounts of matter and antimatter, each created from nothing.

Fundamental Symmetry: Matter and Antimatter

The fundamental assumption is that the universe can only contain matter if it contains the corresponding antimatter. This principle is mathematically represented as X minus X equals zero, where X signifies the mass of matter. Therefore, one electron is paired with one positron, and one proton with one antiproton. These particles annihilate each other billions of times, but occasionally separate, leading to the formation of hydrogen and antihydrogen.

Formation of Hydrogen and Antihydrogen

Once enough hydrogen and antihydrogen accumulates, a singularity or 'pre-Big Bang mass' forms. The immense gravitational force compresses the mass to a point of infinite density, and when it reaches a critical mass equivalent to that of the entire universe, the mass is converted into energy, leading to the phenomenon known as the Big Bang. This event released cosmic microwave background radiation, marked the separation of matter and antimatter, and initiated the expansion of the universe.

The Structure of the Universe: A Diamond Model

The universe is hypothesized to be structured like a diamond, with 4 pre-Big Bang masses surrounded by 4 other universes. These 4 pre-Big Bang masses exert a gravitational pull on our universe, explaining phenomena such as dark energy and dark matter. Dark energy is merely the effect of gravity pulling our universe from these pre-Big Bang masses, rather than pushing it out by some mysterious force.

Unexplained Phenomena and Their Explanations

The universe presents several unexplained phenomena, including the acceleration in the expansion rate, the presence of dark matter, the largest void in the universe, the cosmic microwave background, and the formation of galaxies too soon after the Big Bang. These phenomena can all be explained by the diamond model of the universe and the formation of pre-Big Bang masses.

Acceleration in Expansion Rate of the Universe

The accelerating expansion of the universe, attributed to dark energy, is actually caused by the gravitational pull of the 4 pre-Big Bang masses. The force of gravity, a well-established physical concept, is the true explanation for this phenomenon, not dark energy which lacks empirical evidence.

Dark Matter

Dark matter, detected by the gravitational effects on our universe, is explained as the mass of 4 pre-Big Bang masses and 12 outer universes pulling on our universe. These masses are not directly observable but their gravitational effects are measurable, thus dark matter is identified as a significant component of the universe.

The Largest Void in the Universe

The largest void in the universe is explained as a result of the diamond structure of the universe. As galaxies are diverted towards the pre-Big Bang masses, four largest voids are formed at the center of the triangles of the diamond structure. This distribution accounts for the uneven distribution of galaxies across the universe.

Cosmic Microwave Background

The cosmic microwave background, thought to be leftover light from the early universe, is actually light from distant outer universes. Due to the heavy gravitational force of the pre-Big Bang masses, the light is bent and converted into microwave radiation, guiding our understanding of the universe's expansion and structure.

Formation of Galaxies Too Soon After the Big Bang

The formation of galaxies before the Big Bang can be explained as galaxies from outer universes falling onto pre-Big Bang masses, initiating the Big Bang there. Some galaxies are pushed away by the Big Bang and are currently being observed by the James Webb Space Telescope.

Conclusion

The universe, as we know it, is a result of the interaction between matter, antimatter, and the unifying force of gravity. The Big Bang, often seen as a singular event, is now understood as a routine process in the infinite expanse of space and time. Any questions or further discussions on this topic are welcome in the comments section.