Exploring the Expansion of the Universe and Its Unexplained Phenomena

The expansion of the universe has been a subject of immense interest and study for decades. While the idea of the universe expanding near or faster than the speed of light is intriguing, it is not supported by current scientific evidence. Let's delve deeper into the expansion of the universe and the unexplained phenomena surrounding it.

What Drives the Expansion of the Universe?

Before we address the specifics, it is important to clarify that neither space itself nor the universe is expanding at near or faster than the speed of light. The idea that galaxies are moving away from each other at such speeds is a common misconception. According to modern cosmology, the universe is expanding due to the force of gravity exerted by pre-big bang masses, which are located outside our observable universe.

Understanding Pre-Big Bang Masses and Universal Expansion

Imagine the universe as a diamond-like structure, with four pre-big bang masses at its core. These masses, each comprising about 99 percent of the mass of the universe, exert a gravitational pull that is responsible for the observed acceleration in the expansion rate. This phenomenon is often attributed to dark energy, but our theory posits that the expansion is driven by this gravitational force, not by some mysterious substance.

Three of these pre-big bang masses are 12 universes away, far beyond our detection capabilities. However, the fourth mass is much closer, exerting a significant pull on galaxies within our observable universe. This gravitational force is well understood by physicists and aligns with established theories of physics, making the concept of dark energy unnecessary.

The Multiverse and Cosmic Microwave Background

Our universe, surrounded by these multiverses, is like a bubble floating in an infinite space. The four pre-big bang masses exert a gravitational pull that shapes the distribution of galaxies and voids within our universe. The cosmic microwave background (CMB), often interpreted as leftover radiation from the big bang, is actually a glow coming from the outer universes. This light, dimmed by the gravitational forces, reaches us in a nearly parallel manner.

Why do we observe the CMB and not visible light? The gravitational forces from the pre-big bang masses cause the light to lose energy, bending it into microwave radiation. This natural phenomenon explains the CMB without invoking the concept of dark energy or dark matter.

The Formation of Galaxies and Other Phenomena

The rapid formation of galaxies shortly after the big bang is another unexplained phenomenon. Our theory provides a simpler explanation: as galaxies from the outer universes fall onto the pre-big bang masses, they trigger events that we observe as the big bang. The James Webb Space Telescope has recently spotted galaxies that were formed before the big bang, aligning with our theory of gravity-driven expansion.

Challenging Traditional Theories

Our understanding of the universe is continually evolving. While traditional theories often invoke dark energy and dark matter to explain unexplained phenomena, the diamond-like structure of the universe offers a different perspective. Instead of positing the existence of mysterious substances like dark energy, we propose that the expansion is driven by well-understood gravitational forces.

Unproven Hypotheses vs. Theoretical Explanations

The idea of the universe expanding at near or faster than the speed of light is often based on unproven hypotheses. Our theory, however, relies on measurable gravity and observed phenomena. We challenge the concept of dark energy as a driving force for expansion and argue that the observed acceleration is due to the gravitational pull of pre-big bang masses.

Conclusion and Further Exploration

While the expansion of the universe and its unexplained phenomena continue to challenge our understanding of the cosmos, the diamond-like structure of the universe offers a compelling alternative to traditional theories. By re-examining these phenomena through the lens of gravity and pre-big bang masses, we can challenge established theories and explore new avenues of scientific inquiry.

Further Reading and Discussion

If you have any questions or would like to discuss these ideas further, please leave your comments below. Join the discussion and let's explore the mysteries of the universe together.