Unveiling the Universal Expansion: A New Perspective on the Big Bang and the Concept of Em×c^2

In recent years, our understanding of the universe's expansion from the Big Bang has evolved significantly. However, there's a fundamental equation at the heart of this expansion that has remained relatively unchanged: E m×c^2. This equation, introduced by Albert Einstein, is often interpreted solely as a mass-energy equivalence. Yet, this perspective might not encompass the full scope of the equation's implications. This article explores the concept of Em×c^2 extended to include space-time interactions, providing a more comprehensive understanding of the Big Bang and the expansion of the universe.

Understanding Em×c^2: Mass-Energy Equivalence with Space-Time

The equation E m×c^2 is the cornerstone of modern physics, representing the equivalence of mass and energy. The constant c, the speed of light, is central to this relationship, implying a deep connection to the fabric of space-time. The square of the speed of light, c^2, signifies an integrated value of space-time, suggesting that mass-energy is intertwined with the structure of space-time itself.

1. Time as a Result of Space-Energy-Mass Interactions

Time, in this extended interpretation, represents a result of the interactions and interconversions between space, energy, and mass. It is not an independent entity but an emergent property of these interactions. The equation dt dx × E / m^1/2 implies that time can be represented as a function of space, energy, and mass. This means that changes in these factors directly influence the passage of time, challenging the conventional view of time as a constant, measurable progression.

2. Space-Mass-Energy as Expressions of Cumulative Time Content

According to this extended view, space, mass, and energy are all manifestations of cumulative time content. This perspective suggests that space-time is a dynamic entity, where changes in mass and energy lead to changes in the fabric of space-time. This interconnectedness provides a more holistic understanding of how the universe evolves and expands.

The Big Bang: A Transcription of Reality

The concept of the Big Bang can be reimagined as a transcription of reality into the process value-time of our local universe. Unlike the traditional interpretation, where the Big Bang is seen as a sudden, dramatic expansion of pre-existing space, this new perspective views it as a process where primeval atoms, or unit1 existence entities, transcribe into local universes.

The Absolute Origin

The absolute origin is not a state of absolute nothingness but a superimposed summation of all possibilities, including all real and imaginary states, past, present, and future. This concept suggests that the absolute origin is an absolute totality of all options, making it inherently dynamic and ever-evolving. During the Big Bang or similar events, primeval atoms reincarnate as quantized infinitesimal entities, leading to the expansion and evolution of our local universe.

Prevention of Repeated Big Bangs

Given the dynamic equilibrium of our local universe, the expansion and evolution of the universe are not driven by a periodic recurrence of the Big Bang. Instead, the high mass-energy densities of the universe create a state of equilibrium that prevents the occurrence of another Big Bang. This equilibrium is maintained by the continuous interplay of space, mass, and energy, creating a state of stasis that resists further dramatic expansions.

Conclusion

The equation E m×c^2 extends beyond mere mass-energy equivalence to encompass the complexities of space-time interactions. This extended interpretation offers a new perspective on the Big Bang, viewing it as a transcription of reality rather than a sudden expansion. By integrating the concepts of space, energy, and mass into a dynamic framework, we gain a deeper understanding of the universe's expansion and the fundamental nature of time and space.

Key Points: E m×c^2 as a mass-energy equivalence extended to space-time interactions. Time as a result of space-energy-mass interactions. Space, mass, and energy as expressions of cumulative time content.