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Can a Roman telescope find dark matter?


"Sometimes, stars can be stripped away from globular clusters as they orbit a massive galaxy. Researchers have identified several instances in our own Milky Way galaxy – and they’ve also spotted gaps between these looping tendrils. What caused those gaps? One possibility: a substance known as dark matter. Following the launch of the Nancy Grace Roman Space Telescope, astronomers will use its vast, high-definition images to spot many more tidal streams – and potentially their accompanying gaps – in nearby galaxies for the first time. " (ScitechDaily, Can NASA’s Roman Space Telescope Unlock the Secrets of Dark Matter?)

"A prime candidate is our neighbor, the Andromeda galaxy, which appears in the illustration above. Soon, not only will researchers be able to identify tidal streams in Andromeda, they may also be able to use Roman’s fine resolution to pinpoint more properties of this mysterious substance. Credit: NASA, Joseph Olmsted (STScI)"  (ScitechDaily, Can NASA’s Roman Space Telescope Unlock the Secrets of Dark Matter?)

 Can a Roman telescope find dark matter? That is a good question. The Roman telescope has very much potential. But the problem is that there are no perfect models for dark matter. If we want to model weakly interacting massive particle WIMP, we can use the sombrero model. The gravity pothole of WIMP would be too deep, and the energy hill at the middle of the sombrero would be too low. 

If the top of the WIMP's energy hill is lower than the edge of the gravity pothole. That makes the particle invisible. 

If we want to make a 2D model of particle-Higgs field interaction we can say, that because the top of the particle is above the bottom, that thing pulls energy through the particle. And that thing makes the gravity around the particle. 

The particle is in the middle of a gravity pothole which is a "hole" in the Higgs field. When the particle touches the Higgs field, it pulls energy from the field into it. That effect forms the gravity- or energy pothole around the particle. 


Image: CERN

Above: If the particle is in the middle of the gravity pothole. Or energy pothole in the Higgs field. The particle is visible only if it rises above the edge of the gravity pothole. The particle's energy level can rise until the center hill or energy hill turns out of balance. 

The thing that makes particles move is the asymmetry in the pothole. One of the things that can cause the asymmetry is the energy pothole that touches the gravity pothole around the particle. The graviton is the pothole forward of the particle, and the pothole pulls the particle forward. 


Theoretical superstrings could be chains of theoretical quantum-size black holes. 


We can think, that the superstrings can form elementary particles. It's possible. The superstrings can be quantum-size black hole chains. Those quantum-size black holes can explain why things like electrons spin 1/2.

The idea is that when a particle turns forward. There is an asymmetry in the transition disk around the quantum-size black hole. Those quantum-size black holes could be far smaller than quark or gluon. The transition disk around them is like a string. And when the hypothetical structure moves forward. That effect forms a quantum vacuum behind that structure. That vacuum pulls the particle backward. 

The hypothetical quantum-size black holes can explain why the particles send energy as they burst. If those quantum-size black holes exist, they can form the quantum-size Tesla coils that can send radiation, which we call "gravitation". 

Energy travels to the top of the particle through the superstrings that form the particle. The energy that the particle pulls grows and finally destroys it. And the reason for that is the standing wave or the electric arc in the particle or somewhere in its structure makes it oscillate. If that structure sends the wave movement that we call the gravitational waves. We can think that the structure is not homogenous. 

There could be plate-looking structures in the superstrings. And if that thing is true, that can prove the quantum-size black hole's existence. In some wild hypotheses, those superstrings that are the smallest known objects in the universe are the chains of quantum-size black holes. Proving that thing is quite difficult. But because gravitation affects long distances. 

That thing means there are some identical structures in all particles. The energy that those structures send pushes the Higgs field away from the particle. This means that gravity is field-effective. The field pulls objects into the gravity centers. 


https://cerncourier.com/a/one-higgs-three-discoveries/


https://scitechdaily.com/can-nasas-roman-space-telescope-unlock-the-secrets-of-dark-matter/


https://en.wikipedia.org/wiki/Higgs_field_(classical)


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


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


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