Black holes, fractals, and G-field interaction.

  Black holes, fractals, and G-field interaction. 

"Illustration of two novel theories exploring dark matter origins through a mirror world and early universe horizon." (Rude Baguette, “Dark Matter May Come From A Mirror World”: Bold Theories Suggest Hidden Twin Universe And Particle Factory At The Edge Of The Young Cosmos)

There is a possibility that some conditions in black holes are similar to those in a hypothetical anti-universe. That means black holes can be the source of dark matter. But if that is true. That model requires. There is a small anti-universe, or an anti-universe-like space, in every black hole. And if the only thing that differs between the anti-universe and our universe is the direction of time, that means there can be a small anti-universe in the black holes. Time travels in the opposite direction in black holes. So, maybe there are anti-universe-type conditions, and maybe. Some part of dark matter, or mysterious gravitational effects, forms in black holes. 

The new interesting theory about the origin of dark matter in the anti-universe requires more thinking. The thing is that the dark matter formed in the anti-universe is somehow utopian. However, theoretically, there could be anti-universes or structures that behave like an anti-universe within our universe. Those places are black holes. Behind the event horizon, time should move backward. And that thing can form a small-sized mini-universe in the black hole. 

The problem is how those weakly interacting massive particles, WIMPs, hypothetical dark matter particles, can escape from the black holes? The black hole vaporization can cause those particles to escape from the black hole. All black holes are losing mass. During that thing, the black hole sends gravitational waves. So, there is a possibility. The gravitational waves form when hypothetical gravitons are left outside the event horizon. When a black hole loses its mass. The event horizon withdraws, and that causes particles like gravitons to be left outside it. 

Another way to think about the black hole vaporization is to think of the black hole as a whirl. That while it always interacts with its environment, as all other whirls do. That whirl causes friction in the medium between the whirl's internal and outside structure. That means the contact between those whirls and the outside environment causes small whirls that steal energy from the higher energy space or field. 

Above: A Fractal can introduce a model of how a black hole, or the whirl in the Gravity, or G-field, creates other whirls around it. When it interacts with the outside G-field. 

The idea is that. The G-field makes a whirl when it impacts with another G-field that moves in another direction. In the same way, water forms whirls into the points where water flows in opposite directions. 

So, if we think that time is also like wave movement, the time that moves backward behind the event horizon can form a whirl in time or 4th. Dimension in the point where time moves forward and backward. And that point is the black hole event horizon. 

When escape velocity turns higher than the speed of light. That means time turns to travel backwards. 

At the point where escape velocity reaches the speed of light, time stops. And then the time starts to travel in the opposite direction when escape velocity turns higher than the speed of light. So, there should be some kind of whirl in time. 

And if we think that a black hole is like a time arrow that moves back in time, that means it should push particles around it forward in time faster than otherwise. That means if we use the time arrow model for that case, the particle near the black hole's event horizon should turn "very light" so that it can fall to the future. That means the time arrow, or the arrow of time, should push particles in the opposite direction when it travels through the spacetime. But that is only a philosophical expansion of that model. 

In the black hole case, the whirl is like in a G-field. That whirl interacts with the G-field that is outside that black hole or dense gravity, or the G-field whirl. When those environments touch each other, that forms a whirl. And that means the event horizon is full of whirls that are lying. The whirl's center is horizontal to the event horizon. And they can drive energy out from a black hole.

In some other models, the event horizon is a layer that seems to be full of photons. Those photons might make it seem like a ball, made of car tyres. That means the gravitons can escape from the middle of those photons. Or they can send gravitational waves to gravitons outside the event horizon. The event horizon can also send whirls inside the event horizon, and that forms entropy in the black hole. 

The idea is that the G-field is an independent energy field. That G-field forms from gravity waves. In black holes, the G-field has a higher energy level than the G-field outside the black hole. That means the G-field travels outside the black hole. The G-field is one of the fields of four fundamental forces. Those forces are gravity, weak, and strong nuclear interactions. And electromagnetism. 

Those fields are independently interacting substances. And that means G-field can rise to a very high energy level, and that doesn't mean that other fields must rise their energy level. But if the G-field is at a very high energy level. Or its density is so high that it can push other fields from around it. In the same way, if the G-field spins fast enough, that thing doesn't let other fields in it. 

The whirl interacts like a wheel that lets material and wave movement travel through the black hole. There could be a superstring or energy string that travels through the center of the whirl. But then. Those whirls are pumping energy out from the black hole. The black hole can also form whirls that can separate from the event horizon. Those whirls are like small kugelblitz-black holes. There is a possibility. Those whirls just explode immediately after they separate from the event horizon. 

https://www.rudebaguette.com/en/2025/08/dark-matter-may-come-from-a-mirror-world-bold-theories-suggest-hidden-twin-universe-and-particle-factory-at-the-edge-of-the-young-cosmos/

https://scitechdaily.com/two-wild-new-theories-could-finally-explain-dark-matter/

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

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

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

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

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