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Can dark matter interact in some other ways than just through gravity?



Dark matter is a wonderful thing. Its only known interaction is through gravity. And that thing makes it a remarkable thing. Then, we can start to think about the shape of dark matter. 

Researchers think that dark matter has a particle form. The name of that particle is a weakly interacting massive particle, WIMP. But are WIMPs real or virtual particles? We could say, that WIMP is the quantum gravitational center for an unknown gravitational effect called dark matter. And that means black holes are groups of WIMPs. 


We cannot observe the system in its entirety if we are in the system. This makes it hard to detect the Higgs field. We are in the Higgs field. And that's why we cannot detect it. In this model, gravity is the movement in the Higgs field. 

We can say that gravity is the hole or low-energy area, or some void in Higgs field, that can tell about the shape of dark matter. The reason why the Higgs field or base energy field is so hard to detect is that we are in that field. We must get out of the field so that we can detect it. In the same way, we can think that the entire universe is full of air that we can breathe because we are in the Earth's atmosphere. 

Earth's atmosphere is less than a microscopic part of the solar system. But because we are in it. We think that the atmosphere is enormous. The thing is like this we can sit in the castle above clouds. If we ever go out of that castle, we can think: it's enormous. In that case, the castle is our entire world. In the same way, people think that Earth is enormous because spend here our entire life. 

We can make measurements of the Earth's atmosphere and energy fields only by stepping out from them. And it took over 90 years to detect Earth's electric field. And finally, we can say that the Earth's atmosphere is quite thick. But if we compare our atmosphere with Venus, we can say that our atmosphere is thin. 


That means everything is relative. We can always take something bigger or heavier to say, that something is small or light. We can say that our sun is very cold if we compare it with Spica. But same way, we can think that our sun is very hot. If we compare it with Proxima Centauri. And the Earth's global electric field can be very weak. But it has a crucial role, in turning ions away from Earth's atmosphere. That means the weak effect can be important. 

The dark matter can be some kind of group of low-energy bubbles in the Higgs field. That means there is an object that interacts only with the Higgs field. In that model, the WIMP might look like the neutron star or black hole, but it's far smaller. 

Like other particles and objects, WIMP doesn't create any energy form. It just collects wave movement or field into it. Energy is wave movement. And the wavelength determines the name of the energy. All four fundamental forces, gravity, electromagnetism, and weak and strong nuclear forces are wave movements. That travels in the universe. And the wavelength separates them from each other.  


And if we think that Higgs field is like water and gravity is the effect. That makes Higgs field travel to the gravitational center. In that model, particles flow in a Higgs field that travels to the gravitational center. When we think that the gravity center focuses Higgs field gravity center must get the Higgs field from somewhere. That means it collects that field and then that field can travel away from the spin axle. 

The idea is that the WIMP can be an extremely slight particle. So it cannot touch or send wave movement away from it like visible particles. That particle could aim the Higgs field from its "equator" to the spin axle.  If we think that visible particles look like whisk. The superstrings are around the electromagnetic low pressure. The outside energy presses that structure into the form called a particle. And sometimes particles let an outside energy field go between those superstrings. That thing causes wave movement that travels away from the particle. The idea is like spinning a whisk in the water. 

But in this case, the hypothetical WIMP could be so tight that it cannot let the outside energy and wave movement go between those superstrings. And that thing denies the wave movement from those particles. Or, otherways saying, all energy that WIMP collects travels into its spin axle and then it travels to the universe in the form of a thin energy pike. That could explain the dark energy or at least part of it. 


https://bigthink.com/starts-with-a-bang/dark-matter-interact-non-gravitationally/


https://science.nasa.gov/science-research/heliophysics/nasa-discovers-long-sought-global-electric-field-on-earth/


See also:


Higgs field


Fundamental interaction


The standard model of physics

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