Theoretical Insights into Dark Matter and Dark Energy: A New Perspective

The Journey in the Quest for Dark Matter

Despite the tireless efforts of researchers globally, the study of dark matter remains a mystery, often attributed to a need for new physics beyond our current understanding. This confirmation bias, rooted in the reluctance to accept failed predictions, adds to the complexity. It is intriguing to consider that dark matter might serve as a validation of our existing theories, rather than a challenge to them.

The kinetic energy of a spinning gyroscope can be explained by the photon exchange along its circumference, influenced by the Lorenz transformation. However, this phenomenon hints at a deeper understanding of how two-dimensional entities interact with three-dimensional space, prompting us to explore the influence of space-time or ether on the motion of celestial bodies.

The Intuitive Nature of Current Research

The current state of research on dark matter is still in its intuitive phase. Until we can experiment with dark matter directly, our understanding remains rooted in theoretical models. This intuitive phase highlights the need for further exploration and experimental validation.

The Composition of the Universe

The universe is composed of approximately 27% dark matter, 68% dark energy, and 5% ordinary matter. The presence of dark matter is crucial for the gravitational interactions that shape the universe, yet it remains elusive, not emitting, reflecting, or absorbing electromagnetic radiation. Dark energy, while unproven, is posited as a driving force causing the accelerated expansion of the universe.

A New Theory: Pre-Big Bang Masses and External Universes

A novel hypothesis suggests that the solutions to the enigmas of dark matter and dark energy lie outside our current universe. The theory posits that your universe is surrounded by four pre-big bang masses, each of which is enveloped by four additional universes, forming a diamond-like structure. Each pre-big bang mass is presumed to have a mass almost equivalent to 99% of the universe.

Explaining Unexplained Phenomena

tAccelerating Expansion of the Universe: Dark energy, which has no known evidence, is actually a misinterpretation. The acceleration in the expansion rate can be attributed to the gravitational pull of the four pre-big bang masses, acting as a force of gravity rather than a mysterious dark energy. tDark Matter: The gravitational effects of the pre-big bang masses on your universe are detectable but not directly testable, hence termed dark matter. This matter is sufficiently far away, resulting in the inverse square law effect. tThe Biggest Void in the Universe: The distribution of galaxies is not uniform, with four largest voids in the universe forming at the centers of the triangular structures of pre-big bang masses. tCosmic Microwave Background (CMB): The CMB is not residual light from our universe but light from an even larger distance from outer universes. As it passes through the heavy gravitational forces of the pre-big bang masses, it loses energy, converting to microwave radiation. tFormation of Galaxies: The early formation of galaxies can be explained by the gravitational pull of pre-big bang masses, leading to the event of the big bang that shaped the universe.

Conclusion

The complex dynamics of the universe, particularly the mysteries of dark matter and dark energy, challenge our current understanding. By exploring the possibility of external universes and pre-big bang masses, we can bring these enigmas into a theoretical framework that addresses the unexplained phenomena of the cosmos. Further research and experimentation are needed to validate these theories and bring us closer to understanding the true nature of the universe.

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