The dark matter researchers fail to create dark matter.

Are neutrinos dark matter? 

Are neutrino stars possible? The thing that makes neutron stars possible is that neutrons have north and south poles. So if neutrinos also have N/S poles. That makes it possible that also neutrino can form similar lattice structures as neutrons form in neutron stars. Neutrino is an elementary particle that is far smaller than a neutron. And if neutrino stars are possible. 

They reflect radiation in a much shorter wavelength than neutron stars. When a particle reflects radiation first it takes it into its quantum field. Then the quantum field's energy level must rise higher than its environment. At that moment, the particle sends wave movement. Those particles' wavelengths are the same as the particle's size. 

The reason why the frequency of small and high-energy particles is shorter is that there is not very much space in those particles. Theoretically, theoretical graviton or dark matter particle is so small, that it transmits all energy back immediately. That thing could form the quantum disk around that particle. 

And that thing could make it possible that radiation travels past those particles. The quantum disk interacts similar way as material disks of neutron stars or black holes. It pushes radiation away from it. But it also makes the quantum-maser emission in the middle of it. 

Nuclear reactors and stars can form neutrinos. The question is are neutrinos in other particles? Or is the thing that forms them the whirl that forms when neutrons or some other particles impact each other? Sometimes so-called sterile neutrinos are introduced as dark matter. Sterile neutrinos are hypothetical neutral or almost neutral particles. In some visions, the neutrino has two poles. And it is quite similar to a neutron that is not an elementary particle. 

The idea of that model is that the difference in the domination of the N/S North and South poles in the elementary particle is the thing that determines if the particle is neutrino or electron. If a particle only has a north pole that thing makes it a lepton called an electron. And if that particle's north and south poles are in balance or they have the same strength. 

That makes the particle neutrino. So if we think that particle slides from the electron state to the neutrino state we might understand why dark matter doesn't react. The polarity of that particle makes it spin extremely fast. Ot its spin turns >1. And that thing turns neutrino act like a drill that pushes quantum fields and superstrings away from it. The fast spin makes an effect where quantum fields cannot touch a very fast rotating particle.

The Dark matter detector. 

If a sterile neutrino is a polar particle that has N/S poles, neutrinos could create similar structures like atoms. So if neutrinos can form lattice structures like neutrons and other polar particles that thing means that in the universe is the neutrino stars. And the question is, can we see those stars? 

The problem in attempts to create dark matter is simple. Dark matter does not interact with electromagnetism. And that makes it invisible. The atom clock is the only real thing that can make observations of dark matter. The only known interaction between dark matter and visible material is gravitation. And the creation of dark matter requires the possibility to create a gravitational maser or laser that shoots gravitational waves as its rays. The gravitational maser can make dark matter. 

But the problem is that nobody knows how to make that thing. We know that a gravitational lens can change even a photon's trajectory. Gravitational lenses are giant galaxies. There is also one thing that can focus gravitational waves. And that thing is the gravitational field. The synthetic gravitational field could make it possible to create dark matter. But then we must realize one thing. We don't know, does the dark matter send, or does it receive gravitational waves. 

In some theories, the spin of dark matter particles is so high, that sends energy in the peaks that can penetrate the visible material. In this model, the extremely powerful spin makes the superstring. That simply pushes other superstrings away from its route. So this mystery ghost material can tunnel itself through the fermions or their bonds. 

Or maybe we think that dark matter particles spin extremely fast and that thing can form a hole in the middle of the particle. The electromagnetic fields fall into that hole. And then they will impact each other in the middle of the particle. That forms a radiation impulse in the equator of that particle. And then that radiation impulse pushes electromagnetic radiation over the particle. 

If we want to make some material that requires the ability to interact and manipulate it. The problem with dark matter is that it cannot interact in other ways than through gravitation. And all our manipulation methods are acoustic or electromagnetic. Electromagnetic radiation or electromagnetic field cannot create dark matter because it cannot interact with that material. 

If we want to stress atoms using lasers. That stress can almost form dark matter. But then just in the energy point where visible material turns to dark matter where it loses its ability to interact with visible material, the radiation loses its touch with those particles. When that touch ends dark matter sends radiation away. And then it cannot turn to dark matter. But this theory is only a hypothesis. We don't know if dark matter is on a higher or lower energy level than visible matter. 

The problem is this. Dark matter is not the same as black holes. It's a similar material as visible. But somehow it cannot interact with electromagnetic windows. The only confirmed interaction between visible and dark matter is gravitational. There is no sign of weak force interaction between dark and visible material. 

Sometimes is asked are WIMPs or Axions the dark matter. The fact is that both of those hypothetical particles can form dark matter. The thing is that we don't know the interactions of things like muons very well. We know that all elementary particles, like muons. And especially neutrinos do not seem to belong in any known structures in the universe. 

https://www.universetoday.com/162629/dark-matter-experiment-fails-to-turn-up-the-mysterious-particle-but-narrows-its-hiding-places/