What if all we thought about dark matter is wrong?

   What if all we thought about dark matter is wrong? 

Above: Cosmic gamma-ray background.

So, what makes gravitational waves and gravitational fields move? That is the key question in dark matter research. There are suggestions that the gravitational effect that we know as “dark matter” can be quantum-sized black holes, or some kind of particles like axions. The problem is that nobody has seen any axion yet. And if somebody says that the still hypothetical free graviton particles are the thing that forms dark matter, the next question is: what are gravitons? Are they quantum-size black holes?

Gravitons are theoretical gravitation transporter particles. Those particles are things that cause gravitational waves moving. But another thing is that dark matter can be anything that we can imagine. The only known fact is this: there is some kind of gravitational effect whose origin is unknown. 

All four fundamental interactions are some kind of radiation. And each of those interactions has its own individual wavelength. Each fundamental interaction, gravity, strong nuclear force, weak nuclear force, and electromagnetism, has its own individual radiation type. 

Then we can think about the shape of materia. The particle is like a whisk. The strings that form the particle shell have a certain height. When a particle spins, it binds energy into it as kinetic energy. Sometimes a particle’s energy level turns higher than its environment. And in that moment particle sends waves. Those waves’ wavelength is the same as the particle’s diameter. But the height of those strings also causes limits in that interaction. Strings on the particle’s shell touch the field. Those strings are like flaps on paddlewheels. Their height determines the wave types that the particle can bind to. If those strings are high, that particle can bind a longer wavelength. 

There is one rule for interaction. Radiation or water must have access between those flaps. If the paddlewheel or propeller spins too fast, that causes an effect called supercavitation. The water has no time to fall between those flaps or between the propeller’s blades, which causes the paddle wheel or propeller to spin in a bubble. And that causes an interesting hypothesis. 

Could there be a particle that spins so fast that it causes supercavitation in the quantum fields? Can some particle spin so fast that it can make a cavitation bubble in the gravitational field? If that particle exists, that means gravitation will not affect that particle. Gravitation affects that particle’s quantum bubble. But it doesn’t affect the particle itself like other particles. If particle groups like hadrons spin very fast, their quarks can turn into a straight row. 

That spin can cause a situation where quantum fields or radiation travel to the axle of that particle row. And that can make the particle a hard target for observers. Fast spin can also throw radiation past the particle. This makes it invisible. But can that thing be possible with elementary particles? And can some particle throw gravitational radiation, or gravitational waves, past it? That causes an effect where gravitational waves slide over particles without causing interaction. But can this be true? Heaven knows. 

And in that case. Longer wavelengths. Like electromagnetism covers other, shorter wavelenght below them. That means electromagnetic force covers weak and strong nuclear forces. And gravity below it. If something pulls the G-field into something, that field pulls other fields to that particle. 

There is a possibility to press all parts of an atom into one entirety called a singularity. The reason why we cannot see the singularity is that its so smooth. Those superstrings on its surface are so low that they can bind only short-wave radiation. That means the particle will be surrounded by the standing gravity field. The singularity harnesses the G-field that transports other fields to the singularity.  How long will that singularity remain? As long as the outside fields can press that thing into one entirety. 

But there is a possibility that if the particle spins very fast. That causes a situation where longer wavelengths have no time to fall between those strings. That means the extremely fast-spinning particle drives fields past it like a stealth aircraft. The idea is that the G-field is the shortest wave radiation, and the fastest spinning objects can cause a situation where the only thing that can interact with that particle is the G-field. The G-field is the only thing that has time to fall between those strings. 

This causes another very interesting question. Can there be a so fast-spinning particle that even the gravity field, or G-field, has no time to fall between those strings? If that kind of particle exists. That would be the revolution for physics. 

https://www.space.com/astronomy/dark-universe/what-if-weve-been-thinking-about-dark-matter-all-wrong-scientist-wonders