"In a dramatic twist on classical physics, scientists have cooled a mirror to near absolute zero with lasers to see if gravity might be quantum. This breakthrough could reshape how we understand the universe. Credit: SciTechDaily.com" (ScitechDaily, MIT’s Chilling Experiment That Could Prove Gravity Is Quantum)
Quantum gravity: mass, density, and weight form gravity. And every single particle has a quantum field. The gravity is the interaction with quantum dots and the gravity center is the collection of those quantum dots. The quantum dot forms when a spinning particle binds quantum fields from around it into the particle's structure. The outcoming field denies the destruction of the particle by pressing it together.
The spin of the particle is normally 1/2. Which means. When the particle turns its direction, it stops and releases energy. When the spin direction turns, the particle simply pushes quantum fields away from it. In that case, a particle binds energy, but that time is so short that energy cannot turn a particle into a black hole.
If we want to turn particles into black holes. We must impact energy in it. When a particle binds energy from around it, it forms a gravity pothole. When that pothole turns deeper that pothole-particle combination pulls energy from larger and larger areas.
The quantum gravity theory can be proven or disproven. But the idea in the quantum gravitational model is that. Every single particle in the universe has a gravity field. Quantum gravity means that all nuclear fundamental interactions have the "domination limit". There is a certain mass, size, or density of the objects. The object's size determines which of the fundamental interactions turn dominating.
Dominating interaction between quarks and gluons is strong interaction or strong force. Dominating interaction between hadrons is a weak nuclear interaction. The dominating interaction between an atom's nucleus and electrons is the electromagnetic interaction. That makes the quantum gravity model hard to prove. The gravity wave is so weak at the quantum level that it's almost impossible to detect. Other interactions cover that effect below them.
Dominating interaction makes atoms stay in the form. And it determines the position where subatomic particles are. Gravitational interaction affects long distances and only between large objects. Or, if we follow the recent text, we can say that gravitation forms in the entirety there are multiple gravitational centers. Or, every gravitational center involves multiple gravitational centers.
Dark matter and quantum gravity model.
And then we can introduce an interesting model of dark matter. Dark matter can be material that spins too fast. That spin makes them bind quantum fields inside their structures faster than they should. So, when quantum fields travel in those particles those fields pull them closer together.
That explains why compact dwarf galaxies' stars are too close to each other. When some outside effect pulls dark matter halo out from the dwarf galaxies that causes the effect that the outside energy tries to fill those points. And that pulls stars closer to each other. When some outside gravity field pulls dark matter halo from away from the dwarf galaxy. That can turn those quantum shadows stretch. That thing makes quantum fields move to those positions that that movement releases.
Another interesting model is that the WIMP (Weakly interacting massive particle) can be the situation that the other particle will go in some particle. That means we cannot see that other particle because the other particle covers it. So, if we think that the hypothetical graviton is that particle that gives mass to all other particles the graviton curves the quantum field or superstrings that form the whisk-shaped structure or bubble around that graviton. In some models, the graviton is the small, quantum-size black hole.
The standard model is very functional until we face gravitation. Gravitation has no repelling effect and that makes it interesting. There are theoretical models about things like antigravity but they are not proven.
There are models that gravity can be a mixture of other three fundamental forces, strong. And weak nuclear forces and electromagnetism. There is also a model that the spinning movement of the particles binds quantum fields to them. So when particles turn wave movement into kinetic energy. They just harness energy from around them and bind that energy to their structure.
And then to the quantum gravity model. The idea is that all particles are quantum spots (or balls) that bind quantum fields around them. That means all gravity centers are collections of quantum dots. So, those quantum dots form all gravitational centers in the universe. The thing that forms the black holes are the internal quantum dots.
The quantum field is like a canvas that travels through and between those quantum dots. The size of the holes, or the distance of those quantum dots determines how strong those quantum fields can be. The thing is that quantum gravity means that mass, weight, and density are things that determine the particle's gravity field.
https://scitechdaily.com/mits-chilling-experiment-that-could-prove-gravity-is-quantum/
https://en.wikipedia.org/wiki/Dark_matter
https://en.wikipedia.org/wiki/Fundamental_interaction
https://en.wikipedia.org/wiki/Graviton
https://en.wikipedia.org/wiki/Spin_(physics)
https://en.wikipedia.org/wiki/Standard_Model
https://en.wikipedia.org/wiki/Weakly_interacting_massive_particle
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