Quantum Gravity's Explanation Of The Dark Sector And Black Holes
You would be shocked if a theoretical physicist named anything other than quantum gravity and the dark sector when asked about the deepest mysteries in
physics. such as: How can General Relativity and quantum theory be reconciled? Describe Dark Matter. How about Dark Energy?
Most physicists find that these are what keep them up at night. Numerous solutions to these issues have been put forward, but none of them fully explain
the issues. The situation is about to change, though, thanks to a new theory put forth by a researcher at quantxcer, who holds a licentiate degree in
physics and electronics. This theory offers a self-consistent theory of quantum gravity that explains the Dark sector and is consistent with observations.
The theory is referred to as Nexus since it connects General Relativity and Quantum Mechanics. The Nexus graviton, a composite spin-two particle of
space-time that naturally results from the unification process, is how this connection unfolds. The fact that the Nexus graviton is not a messenger particle
but instead causes a steady rotational motion on any test particle buried within its boundaries is one outstanding property that sets it apart from
the graviton postulated in the Standard Model.
The Nexus graviton can also be thought of as a globule of vacuum energy that is capable of merging and demerging with other globules in a manner
similar to cytokineses in cell biology. Space-time is made up of Dark Matter, which is the Nexus graviton. The expansion of the high energy graviton as
it transitions into a lower energy state happens as a result of the emission of a graviton with the least amount of energy by another graviton.
According to the hypothesis, this process appears as Dark Energy and occurs everywhere in space-time.
This study is important because it provides some insight into some of the most puzzling issues in physics,
such as how to describe black holes in quantum mechanics without the singularities seen in classical general relativity.
The solutions offered in this research will undoubtedly pave the way for novel physics.