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What is the nature of dark matter?


Gravitation may interact through dark matter. And that means dark matter or its hypothetical particle WIMP (Weakly Interacting Massive Particle) is the connector between gravitation and visible material. 

We can think that all objects act similarly when they travel through space. When a high-speed object travels in gas, it forms a low-pressure cone behind it. In the same way, when a particle travels in spacetime, there is a similar low-pressure quantum vacuum behind it. 

When particles or objects travel in spacetime. There is always a low-pressure channel behind them. If we think that the gravitational center pulls objects very hard into it through gravitational strings, there is also another quantum cone behind that particle. The graviton that could be an extremely small particle doesn't make exceptions with this thing. 

Graviton itself may be WIMP or the WIMP is the next particle between graviton and maybe gluon. The thing is that WIMP could be the gate to the fourth dimension or energy level, where a particle loses its ability to interact with three-dimensional particles. 



The size of the gravitational string is very small. So there is a model that thing the gravitational string pulls in it is WIMP (Weakly Interacting Massive Particle), or hypothetical dark matter particle. And then the visible material particle follows that dark matter particle in its quantum low-pressure cone. 

When the gravitation is strong enough, the cone behind the object stops it. That freezing happens at the speed of light. So what is the direction in which particles travel? That depends on the symmetry of those low-pressure cones. If those cones are symmetrical or have the same strength, particles cannot move and that field traps them. 

The light cone could also introduce a situation where particles reach the speed of light. The energy that pushes the particle has the same strength as the energy that pushes the particle back. So those energy cones have the same strength. 

So how gravitation can break this model? The idea is that gravitation pulls other particles to the cone behind the particle that falls into the black hole. In that model, the other particles and radiation that come behind the particle mash it through the event horizon. 



The idea is this: gravitation interacts through dark matter. The number of those gravitational strings determines the power of the gravitational field. And in that model gravitons forming in dark matter impacts in the middle of gravitational centers. Maybe the Euclid mission can prove this thing. 

The idea is that gravitation interacts through strings that form behind gravitons. The surface area of those strings where there is an electromagnetic or quantum vacuum is so small that interaction can be seen only in the smallest parts of atoms. When the speed of the particle is high enough, the cone behind it pulls it back. And at the speed of light, the cone behind the particle pulls it back so strongly that it cannot accelerate anymore.

So if we think that gravitation is interacting with dark matter, we might make a model of a graviton. The idea is this: in the center of all gravitational centers is a point where dark matter particles (weakly interacting massive particles, WIMPs) impact.

When a graviton, or hypothetical gravitational transporter, travels out from the gravitational center, it forms the hollow quantum string behind it. That string interacts with dark matter. The idea is that WIMP is a small particle with a large quantum power field. The power field causes small energy asymmetries in particles.

And then they fall into the gravitational field, which is a group of hollow strings. Those strings are like tubes where there is quantum or electromagnetic low pressure. When visible matter starts to fall into those stirrings, that matter acts like a plug. There is low electromagnetic pressure in that string that pulls particles to the gravitational center.


Dark matter annihilation happens in all gravitational centers. The strength of that phenomenon depends on the strength of gravitation. And the number of gravitational stríngs determines the power of gravitation. 


There are two ways this could happen.


1) The WIMP travels at the front of the particle. That means the graviton channel pulls WIMP into the gravitational center. And visible material particles are traveling behind the WIMP and its quantum low-pressure channel.

2) The WIMPs impact visible particles in the quantum field opposite the gravitational center. That causes energy asymmetries where electromagnetic low-pressure forms on the particle's front side. That thing could explain the gravitational interaction.


The particle where WIMPs touch could be a gluon or a string between gluons and quarks.


Dark matter's annihilation forms gravitons. So graviton is the particle that is the result of those dark matter impacts. The idea is that when WIMPs impact, they send graviton particles around those impacts. When hypothetical gravitons travel through spacetime there is a quantum tunnel behind them. That tunnel or string pulls those particles back into the gravitational center. Even if gravitons are small particles they still interact like all other particles. 

When the graviton starts to fall, it takes WIMP particles with it. The WIMP is such a small particle that its interaction is hard to notice, and maybe that interaction where gravitons, as well as WIMPs, interact with visible matter is the gluon or string between gluons and quarks. The WIMP interacts like a hook that pulls the smallest parts of matter into the middle of the gravitational centers.


https://www.nasa.gov/image-feature/shining-a-light-on-dark-matter

https://phys.org/news/2023-08-astronomers-dark-annihilation-center-earth.html

https://profmattstrassler.com/articles-and-posts/relativity-space-astronomy-and-cosmology/dark-matter/dark-matter-annihilation/

https://en.wikipedia.org/wiki/Dark_matter

https://en.wikipedia.org/wiki/Modified_Newtonian_dynamics

https://en.wikipedia.org/wiki/Weakly_interacting_massive_particle

Image 2) https://profmattstrassler.com/articles-and-posts/relativity-space-astronomy-and-cosmology/dark-matter/dark-matter-annihilation/

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