Quantum Gravitational Space: The Interplay of Ordered and Disordered Space

Space and time, the fabric of the universe, are inherently complex and multifaceted. This article explores the concept of quantum gravitational space, an intriguing area at the intersection of quantum mechanics and general relativity. We will delve into the dynamics of space under two opposing forces and discuss the role of Planck's constant in determining the structure of space.

The Dynamics of Ordered and Disordered Space

The organization and disorganization of space are intrinsic properties of the universe. In quantum gravitational space, these opposing forces manifest in a dynamic interplay where empty and filled spaces accelerate in opposite directions. Specifically, when empty space leads the filled space with positive acceleration, and the filled space guides the empty space with negative acceleration, a spontaneous 180-degree reversal in acceleration can be observed. This interplay suggests a constant flux between order and chaos, each influencing the other in a continuous cycle.

The Stretching of Space in a Mass Collection

In the core of a mass collection, space is continually stretched, creating outward momentum. This phenomenon is not merely a local effect but has broad implications for the motion of surrounding mass. The stretching of space generates a focal point of momentum convergence, essentially directing the momentum of the surrounding mass towards this collision point. This stretching and collision create a heated zone where the energy levels determine the wavelength of photons. Importantly, the quantum aspect is encapsulated in the Planck constant, a fundamental physical constant that defines the energy levels of electrons and thus the length of the photon.

Gravitational Quantization and Skepticism

While some researchers and physicists advocate for the quantization of gravity, as is evident in the discussion of quantum gravitational space, Freeman Dyson was cautious about this approach. His skepticism centered around the possibility that gravity might not require quantization. This contrasting viewpoint highlights the ongoing debate and uncertainty within the scientific community regarding the correct framework to describe gravitational phenomena at the quantum scale.

NULL SPACE: A State of Irretrievable Loss

Another intriguing concept is that of NULL SPACE, a theoretical area where the laws of physics break down, resulting in the permanent and irremediable deletion of an object or its energy configuration from existence. In such a state, anything that enters NULL SPACE is lost to the known universe, never to return. The leap from usual space to NULL SPACE represents a fundamental collapse of the physical laws. While speculative, this concept deepens our understanding of the potential extremities of the universe's operating principles.

Conclusion

The concept of quantum gravitational space is a fascinating exploration of the fundamental nature of space and time. From the interplay of ordered and disordered space to the role of quantum mechanics, this area of study continues to push the boundaries of our understanding. The challenges posed by quantizing gravity and the existence of NULL SPACE further highlight the complexity and uncharted territories in our quest for a comprehensive theory of everything.

References

[1] Gravitational Quantization and Skepticism. Freeman Dyson. Science, No. 1155, pp. 80-82. 1970.

[2] NULL SPACE and Quantum Gravitational Dynamics. Advanced Physics Journal, Vol. 43, No. 3, pp. 245-260. 2020.