Understanding Einstein's Spacetime and Its Limitations

Most people would agree that 1 1 2 is correct. But is it truly meaningful? The distinction between the abstract and the practical is crucial. For instance, stating that 1 apple 1 apple 2 apples is both correct and meaningful because it reflects a tangible, observable outcome. On the other hand, Einstein’s equations of spacetime, while mathematically sound, often lack the essential WHY behind the phenomena they describe.

Why Einstein's Equations Fall Short

Albert Einstein, while unparalleled in his ability to describe the HOW of spacetime and gravity, did not have a complete understanding of the WHY underlying these phenomena. His theories lacked the context of the Big Bang, the most significant mechanical motion ever observed. His equations, such as 1 1 2, capture the mechanics accurately but fail to explain the fundamental reason behind the observed phenomena.

Consider the analogy of 1 apple plus 1 orange equals whatever we say it is, without any logical progression. Similarly, Einstein's work, while mathematically rigorous, does not fully capture the essence of the universe's mechanics.

The Role of the Big Bang and Galaxy Formation

The key to understanding the mechanics of galaxy formation lies in the mechanics of the Big Bang itself. Galaxies, including our Milky Way, are essentially groups of stars moving at high speeds in the same direction, much like skaters on a frozen canal. Each star, however, has its own force, much like each skater. If one skater were to stop, it would disrupt the group.

Our Milky Way, with its 100 billion stars, cannot come to a halt. The motion imparted to these stars during the Big Bang is fundamental and continues to this day. This motion can be traced back to the initial conditions set during the Big Bang event.

The Mystery of the Big Bang and Galaxy Formation

What about the matter and energy that forms galaxies? How did it come to be? The Big Bang event, as described by the Big Whisper model, reveals a surprising truth: the matter and energy in our galaxy did not originate from the center of the Big Bang. To form a group in space, like a group of rockets launched from the same location, all the matter and energy must have originated from a common point.

Imagine launching rockets from two different locations on Earth. They will not remain in a group in space. Similarly, the rockets of our galaxy—stars—needed to originate from a single, flat area to remain a cohesive group. This area, denoted as Zone 2, is where all the matter and energy for our galaxy came from.

The Big Whisper Model Explained

The Big Whisper model, named after the discovery of cosmic microwave background radiation by Arno Penzias and Robert Wilson, offers a different perspective on the Big Bang. This model rejects the idea that the center of the Big Bang generated all the matter. Instead, matter came from Zone 2, a tiny, flat area that was not under pressure but eventually led to the formation of the universe's galaxies and structures.

The model posits that the Big Bang was an event where the energy in Zone 1 remained in a high-pressure state and did not produce matter. Meanwhile, Zone 2, being flat and under less pressure, began to expand and produce matter and energy, which eventually formed galaxies in different directions.

Conclusion

In essence, Einstein's spacetime equations provide a profound understanding of how the universe expands, but they do not explain the underlying reason for the mechanics of galaxy formation. The Big Whisper model, by providing a clearer understanding of the initial conditions of the Big Bang, helps us better understand not only the expansion of space but also the formation of galaxies.