Unraveling the Origin: The Role of Singularity and Pre-Bang Masses

The universe, as we know it today, has its roots in the singularity, a concept fundamental to our understanding of its origins. But where did this singularity come from? Can we trace its existence back to the beginning of time and space?

From Singularity to Big Bang

According to our understanding, the universe started with a singularity, a point of infinite density and zero volume. This singularity contained exactly equal and opposite quantities of mass and antimatter, representing a balanced state of zero net mass. This can be mathematically represented as X - X 0.

From this point, universes of mass of matter and mass of antimatter were created. Over time, these universes would annihilate each other, leaving behind pure energy. This process eventually led to the event known as the Big Bang, where all this energy was converted into the vast array of galaxies and structures we observe today.

The Role of Pre-Bang Masses

Before the Big Bang, there existed a pre-big bang mass that held the potential to evolve into the universe. Let's explore what this pre-big bang mass is and its significance.

Pre-Bang Mass Composition

The mass of the pre-big bang was approximately 99% of the total mass of the universe. Despite the vast mass, its volume was significantly smaller due to the extreme force of gravity pulling all components towards the center. As more mass accumulated, the limit for compression was reached, leading to the conversion of mass into energy.

Acceleration and Dark Energy

Acceleration in the Expansion Rate of the Universe—One of the most intriguing phenomena in the universe is the accelerating expansion. This has been attributed to a mysterious force known as dark energy. However, this theory is not fully understood, and direct evidence for dark energy is scarce.

The accelerating expansion could be better explained by the gravitational force of the 4 pre-big bang masses. These masses exert a significant gravitational pull on our universe, causing the observed acceleration.

Dark Matter and the Structure of the Universe

The presence of dark matter is another unexplained phenomenon in the universe. Dark matter is inferred from the gravitational effects it exerts but remains elusive due to its lack of detectable interaction with electromagnetic radiation. This theory could provide a plausible explanation for the observed gravitational effects.

The tetrahedron-like structure of 4 pre-big bang masses leads to the formation of 4 big voids at the center of each triangle. These voids are a result of the diversion of galaxies towards the pre-big bang masses.

Cosmic Microwave Background and Gravitational Lensing

The cosmic microwave background (CMB) is another mystery. CMB is thought to be the leftover radiation from a time when the universe was much younger. However, a detailed analysis reveals that it is actually a glow coming from the outer universes, bending and converting light into microwaves due to gravitational forces.

Galaxy Formation and Dark Matter

The early formation of galaxies just after the Big Bang presents another puzzle. Recent evidence suggests that galaxies from surrounding universes merge with these pre-big bang masses, leading to the Big Bang event as we understand it. This idea challenges our conventional understanding of galaxy formation, suggesting a more complex interplay of gravitational forces.

In summary, the universe's origin and evolution can be more comprehensively understood if we consider the concepts of singularity, pre-big bang masses, and a gravitational force framework. These ideas provide a more cohesive explanation for many unexplained phenomena, such as dark energy, dark matter, and the structure of the universe.

Through this examination, not only can we gain a deeper insight into the universe's history but also challenge and refine our understanding of its current state. As we continue to explore and develop new theories, the universe will undoubtedly reveal more of its mysteries.