Dark matter sends gravitational waves like visible matter.

Dark matter sends gravitational waves like visible matter. 

There may be two types of gravitational waves. The gravitational waves with ultra-short wavelength. And gravitational waves that have ultra-long wavelengths. The idea came into my mind because some galaxies seem to wave. If that thing is true, another gravitational effect can interact with the smallest parts of the material. Another long-wave gravitational effect can interact only with large material entireties. 

Ultra-accurate clocks search differences in time. And those differences would hope to make dark matter visible. In those ideas, the system tries to detect differences that dark matter can cause in time. So those systems measure time dilation. Researchers are interested in dark matter,  because, it can open the road to complete gravitational models. 

When researchers try to create a gravitational model the key element is that the gravitation effect forms when some kind of radiation acts like a heat pump. When that radiation, called gravitational waves comes out from the gravitational center, it makes the front side of the particle colder. 

When energy travels to that colder area. It makes particles travel to the gravitational center. So gravitation makes particles colder. And that makes energy travel in it. Then in the middle of the gravitational center forms the point where that wave movement impacts forming a stading wave.  

Then reflection from the middle of the gravitational center causes things, called gravitational waves. Gravitational effect means. That radiation that reflects out from the middle of the gravitational center makes a lower energy point in the front of the particle. 

Or maybe the gravitational waves can be radiation or wave movement with extremely short wavelengths. The particles are whisk-like structures where quantum fields form the quantum lightning around the vacuum or graviton. A graviton can be an extremely small quantum-size black hole. Gravitational interaction may look like Earth's plasma pulses, but gravitational waves interact in different scale entireties. And those entireties are smaller than atoms or smaller than even quarks and gluons. 

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Can gravitational interaction look like plasma pulses near Earth? However, the size of the gravitational interaction is much smaller than the plasma-pulse interaction. 

If gravitational interaction forms like plasma pulses around Earth that can explain why we cannot see dark matter. In that model, gravitational waves travel past some structure in particles. Then that thing forms an impact or gravitational pulse behind that particle. If dark matter is a 2D ring-shaped skyrmion that thing denies that gravitational pulse cannot push that material in any direction. 

It's possible. That dark matter can send gravitational waves. But itself cannot interact with gravitational fields. In that model, WIMP is like a ring and that structure makes gravitational waves reflect from the middle of that particle. The dark matter gravitational interaction looks like a galaxy with relativistic jets. 

But gravitational waves replace those jets in this extremely small object. That structure makes dark matter send gravitational waves. However, gravitation is a one-way interaction in this model. Outcoming gravitational waves cannot form gravitational wave pulses to those 2D particles. And that makes gravitational interaction one-way in the case of dark matter. 

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In this model, gravitational waves travel past the particle or some part of its structure. Then they impact behind that particle. There are gravitational waves forming bubbles or quantum high pressure that pushes the particle forward or opposite direction from that "gravitational pulse". The gravitational pulse is like a plasma pulse. But it interacts with subatomic particles. 

We cannot see dark matter straight. But we can see dark matter's gravitational effect. That means there is some unifying thing in material and dark matter where gravitation can touch. That means dark matter also sends gravitational waves that we can observe. Gravitational waves cause gravitational interaction. And gravitational interaction requires that both participants in the system send those waves. The lack of other than gravitational interaction causes a question: can there be something in dark matter, that makes dark matter itself unable to react to gravitational fields or gravitational waves? 

In this model, a hypothetical WIMP (Weakly Interacting Massive Particles) can be like skyrmions or ring-shaped quantum fields. The gravitational waves form in the middle of that ring. But that structure forms gravitational stealth around that hypothetical dark matter particle. The reflection from inside the ring-shaped structure pushes other gravitational waves away. And that thing means that the gravitational interaction between visible and dark matter is one way. The dark matter itself sends gravitational waves. However, it doesn't interact with the gravitational field because gravitational waves cannot form a gravitational pulse behind it. 

The antigravity means that this gravitational pulse will turn so high energy that it starts to mirror gravitational waves to the front of the particle. The idea is that the gravitational effect forms when a gravitational pulse forms behind the particle from the direction of the gravitational center. And that shines energy on the particle. If that gravitational pulse forms at the front of the particle or system can create a stronger gravitational pulse to the front of the particle. That thing pushes the particle backward from the gravitational center. 

When researchers talk about gravitational centers they mean dominating gravitational center. All particles and superstrings are gravitational centers. In the Earth-Moon system, Earth is dominating the gravitational center. But the moon is also a gravitational center. The distance between the observer and the object determines which object dominates. If the observer is close to the moon, the moon dominates. And the observer falls to the moon even if the dominating center of the system is Earth.