Understanding the Expansion of Space During the Big Bang: A Deeper Dive

When we consider the expansion of the universe during the Big Bang, it becomes clear that traditional notions of velocity and the speed of light are not entirely applicable. This phenomenon is best understood when we consider space itself as a signal with inherent properties such as wavelength, frequency, and time period of vibration.

Properties of Space as a Signal

Just as a signal can have distinct properties, each unit of space contains force fields and can be characterized by its wavelength, which is directly related to its volume at any instant in time. The wavelength of space is constrained to a range, with the lowest value being zero and the highest value being equal to the speed of light, 299,792,458 meters per second.

Before the Big Bang, the wavelength of space was infinitesimally small, located at Planck's length. Subsequently, there was a sudden increase in this wavelength, starting from the initial value of Planck's length and expanding at multiple integral lengths. This expansion continues to this day and varies with distance from a given point in the universe.

Rate of Expansion and Quantum Mechanics

The rate of expansion of space is not a velocity and does not conform to the laws of classical physics. It’s a rate that increases with distance, meaning that expansion can exceed the speed of light at certain distances from any point in the universe. This concept is crucial to understanding phenomena like quantum entanglement.

Chemistry and Physics of Space Expansion

It’s important to distinguish between the rate of expansion of space and the limitations of communication. Communication is the transmission of vibrations from one unit of space to the next, and this process cannot exceed the speed of light. This is why phenomena like quantum entanglement, which involves interactions at a distance, seem to defy the speed of light, but are still governed by the properties of space.

The Nature of Space and Entanglement

Space, much like a periodic function, can take on any shape. No two units of space can coexist simultaneously, which is a fundamental reason for quantum entanglement. This principle underscores how space is the medium through which quantum properties can manifest.

Conceptualizing the Big Bang

One intriguing aspect of the early universe is that we may not even have a concept of a 'before' the Big Bang. The idea is that space-time itself was created by the Big Bang. Therefore, there was no pre-existing framework within which the Big Bang could take place; it was the beginning of everything.

Conclusion

Understanding the expansion of space during the Big Bang requires a nuanced perspective that accounts for the unique properties of space as a physical medium. The expansion is not constrained by the speed of light, nor is it a simple velocity. It’s a dynamic, complex process that governs the shape and evolution of our universe, and continues to be an active area of research in astrophysics and quantum mechanics.

References

[1] Big Bang - Wikipedia
[2] Understanding the Big Bang -