Can dark matter transform planets or red dwarfs into a black hole?

   Can dark matter transform planets or red dwarfs into a black hole? 

"Black hole inside? Exoplanet observations could provide a new way to search for superheavy dark matter. (Courtesy: NASA/JPL-Caltech)" (Physics world, Exoplanets suffering from a plague of dark matter could turn into black holes)

Theoretically, any object in the universe can transform into a black hole. That means dark matter can form a black hole like visible matter. Dark matter can also play a role in cases where small red dwarfs or planets turn into black holes. There are no observations about those planetary-sized black holes. But they can exist. 

Theoretically, black holes' relativistic jets. Or supernova explosions can turn a planet’s atmosphere into super-high temperatures. And this can cause energy to flow into the planet’s or a small star’s core. And if the gravity field travels to the front of the shockwave, that can cause a situation where the object just vanishes. 

Dark matter that travels into the small object’s core can pull that core into form. There, the self-sustaining nuclear fusion can begin. The mass of the star should be high enough that the whirls and entropy cannot break the fusion core. If the star is too light and fusion starts, it blows the star’s shell out. And that pulls the fusion core larger, causing energy loss. 

If a star is too heavy, the fusion that starts in the middle of it can be too strong. And that blows the star’s shell outside. The loss of energy causes a different situation. Gravity pulls the shell back into its form. And then the star turns into a black hole, immediately when its fusion begins. In the cases of the heaviest nebulae, the nebula can fall straight into the black hole. 

When we think about the possibility that dark matter can transform a planet into a black hole, that can happen in two ways.

1) The dark matter can move into the planet’s core and pull it into a black hole. 

2) Dark matter can form a plague on the planet’s shell. In that case, dark matter annihilation, or other interactions, can form dark energy. That dark energy that travels into the planet’s core can cause an implosion, where a small reflecting wave can make a small vacuum in the planet’s core. The idea is that dark matter doesn’t let energy travel out from that object. That can cause the planet to fall into a form. That we call a black hole. 

When a star forms, the energy level in its shell must be higher than in the core. Then that outside energy pushes particles into the form that fusion can begin. If that fusion is too strong, it detonates the star. When fusion ignites, the star blows a little bit of its mass away, and that forms rings around stars. That forms the asteroid belts around our sun. And that flash can form the situation that some other stars around that star also ignite. 

New theory suggests that dark matter can transform planets into black holes. In the original text, only giant planets are mentioned. Maybe dark matter particles can also transform less massive objects into black holes. The idea is simple. Dark matter interacts with other dark matter particles or “units”. We don’t know what dark matter is, so we could use the word “unit” to describe the dark matter centers. In this text, 'dark matter particles' refers to the same concept as the 'dark matter units”. 

We must realize that the electromagnetic fields near the gravity center are weaker than the outer shell of that field. And that makes the energy travel into the gravity center, taking particles with it. So, the idea is that dark matter units or particles can make the group or cloud. If the massive dark matter cloud travels into the planet’s core, that thing can cause the planet to collapse into a black hole. Dark matter can be massive particles that can cause a situation where the planet falls into a black hole. 

But what is dark matter, or some kind of condensed material impacts things like red dwarfs? That kind of condensed material can pull lots of energy out from that star. There is a possibility that a red dwarf will follow the route of the dark matter beam that travels to the black hole. That dwarf star can collect the dark matter in its core. And that can cause a fall into the black hole. Another scenario can be that. 

Condensed material can pull lots of energy out from a red dwarf. That can cause a situation where the red dwarf turns into a very low-energy form. If the red dwarf loses its energy production and its core turns into a too-low-energy form, the red dwarf can fall like all other stars. But can its mass and energy turn that object into a black hole? In that case, the object cannot explode if the nuclear fusion doesn’t ignite during the fall. 

The idea is that the dark matter can increase the weight of the planet’s core. Then the energy increases the planet’s atmospheric energy level. The super-hot atmosphere put energy to travel into the middle of the planet. Another model is that a planet or a small star can lose its core’s energy level. And that makes energy and matter fall into the middle of the planet. In the same way, extreme conditions near the center of Milky Way-type galaxies can cause a situation where even red or brown dwarfs start to glow hotter than they should. In that model, the density of the dark energy can cause a situation where Dark energy can make small stars glow hotter than they should. 

Can dark matter be the thing that makes the smallest known M-type stars create self-sustaining nuclear fusion? 

The dark matter interaction can also explain. Why some of the smallest known red dwarfs can maintain nuclear fusion. The idea is that the small protostar can pull dark matter into its nucleus, and that thing pulls the nucleus. And starts the nuclear fusion. 

Conditions near the galaxy center or near black holes are extremely. When a planet or a red dwarf loses energy from their core and their atmosphere turns into very high energy, that thing can push those objects into black holes. We know that dark matter is not homogeneously spread throughout the universe. There are points where the dark matter forms denser structures than at other points. So if the planet or red dwarf travels into the dark matter cloud. It can start to pull dark matter into it. 

Dark matter behaves like regular material, and that means it positions itself into a planet’s core, or a red dwarf's core. That can cause a situation where that planet or a small star collapses into a black hole. The thing that can press even a small planet into a black hole can be a situation where a condensed photon beam takes all the energy from the planet’s core. Then the high-energy shell and atmosphere press the planet into the singularity. 

https://physicsworld.com/a/exoplanets-suffering-from-a-plague-of-dark-matter-could-turn-into-black-holes/

https://scitechdaily.com/can-dark-matter-turn-giant-planets-into-black-holes/