The problem with dark energy.

 The problem with dark energy. 

The problem with calculating dark energy is that we cannot make that wave movement interact with our sensors. So all things that we know about those things are theoretical models. In some versions, dark energy is wave movement that falls into the universe and reflects from the middle of it away. 

If some other universes exist, they could very easily explain the dark energy. The radiation that comes from other universes impacts the middle of our universe. But that means our universe is like an electric arc between other universes. Nobody has ever seen other universes. And if that someday happens it proves multiverse. 

The multiverse explains many things. In that theory, the universe is like a bubble in the middle of other bubbles that are other universes. Or those universes can exist in other dimensions. That means their energy levels are so far away from each other that those universes cannot interact with each other. Then there formed a hole or channel between those energy levels. That caused a reaction called Big Bang. But nobody cannot prove that theory in our lifetime. 

So in that theory, dark energy is wave movement whose origin is in the superstrings of subatomic particles. In that model black hole sends gravitational radiation to the material. And then those gravitational waves make the superstrings that are forming subatomic particles oscillate. That means the particle's smallest parts are the origin of the dark energy in those superstrings. 

All particles spin. And that spin impacts wave movement that hits the subatomic particle's structure. When a whisk-looking structure rotates that thing sends wave movement to the gravitational waves. The idea is similar when the whisk is rotating in water. That thing forms weak waves. So maybe subatomic particles act like whisks in water. And there is the possibility that those subatomic particles are forming multiple frequencies of the dark wave movement. 

Even if we say that dark energy's origin can be in black holes we are not sure, what is the form of that mysterious force. The dark energy is wave movement. And there is one interesting model that came to my mind. If black holes transmit very high energy radiation like gravitational waves with very high frequency. That can make it possible that there is a forming virtual version of the Casimir effect between those waves. 

Image: BigThink/The big theoretical problem of dark energy

There is a possibility that electromagnetic fields (or quantum fields ) can act as virtual Casimir plates. And maybe that kind of thing is behind dark energy. 

There is possible that Casimir plates can virtualize. In that case, is forming quasiparticle or standing wave movement between traveling wave fields. And those standing waves can be the dark energy. But then we can think that dark energy acts a little bit like gamma rays. The thing that makes gamma rays so hard to detect is that they are so high-energy radiation. 

But the energy level is not the thing that makes gamma-ray so hard to detect. The particle that sends gamma rays sends wave movement burst so often that receiving particles have no time to transfer their extra energy to their environment. 

We should rather say that the sender particles of gamma rays are sending wave movement so often that the receiving particles will send wave movement in so short periods that the changes of the energy levels are hard to detect. So if the dark energy is monotonic wave movement without cuttings. That means the particles have no time to send wave movement. 

That means the period where extra energy travels to the environment is so short that we cannot see that radiation. If dark energy is so-called monotonic radiation that means all particles would reach the energy level of that radiation. And then the particle that transfers energy from its environment must wait. 

Dark energy loads its energy level higher than the environment. So the particle sends energy but that energy transmit comes from the superstrings. In that version, the dark energy has so small a change in energy level that we cannot detect it. 

In the natural universe, zero kelvin is three degrees higher than in the laboratory. 

There are temperatures below zero kelvin. Those temperatures are in space outside the universe. But the energy minimum in the universe is zero kelvin or −273.15 degrees celsius. That means we cannot reach lower temperatures inside the universe. We must go outside that thing for reaching lower energy levels. 

The absolute zero point is the ultimate energy minimum. The minimum energy level that we can reach is zero kelvin or −273.15 degrees celsius is the energy minimum in the Universe. That temperature reached in the laboratory. But then we must realize one thing. 

The universe's temperature is three degrees over the level reached in the laboratory. The reason for that is the three-kelvin cosmic background. So in the laboratory researchers reached -3 kelvin degrees if we compare that laboratory temperature with the natural cosmic background. 

One of the reasons why dark energy is so hard to detect could be that its temperature is below zero Kelvin. The zero Kelvin is an absolute zero point because our detectors cannot detect lower energy levels. 

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

https://bigthink.com/starts-with-a-bang/big-problem-dark-energy/

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