Molecules and hadrons are entirety. Atoms and quarks reflect radiation. But also bonds between those particles are reflecting wave movement with a frequency that is the same as their diameter. Also, electrons reflect wave movement that hits them. The reflection happens through superstrings that form the elementary particle.
And if the length or state of those strings is different. That means the elementary particle transforms wave movement to a new frequency. Or because the state of energy level in those strings is individual. Every single superstring has its unique frequency.
Those particles are transforming impacting energy to multiple frequencies. So the information that hits particles scatters in multiple states. And that means there is a possibility that we just haven't been able to search the dark energy from the right frequencies.
Is the source of dark energy in gluons or gluon channels? That is transmitting the strong nuclear force? So gravitational waves can stress those channels. And that forms energy that is hard to see. If the black holes are the source of dark energy we must ask: does dark energy come straight from black holes or is there some transformation particle that transforms gravitational waves to dark energy? The fact is that a black hole can act like an elementary particle. And it can send radiation that is unknown to us.
First, we must realize one thing. The theory of black holes as the source of dark energy is not closing the existence of dark matter. In that model, gravitational waves play a key role in the dark energy. When energy hits molecules and particles. Their energy level rises until it's higher than the environment. When energy or wave movement impacts molecules. Their atoms reflect that wave movement. But also chemical bonds between atoms send wave movement in their frequency. That depends on their diameter. So if energy travels straight out from those bonds that energy is hard to detect.
Same way when energy hits to hadron like the proton and neutron it reflects that radiation as an entirety. But also quarks and bonds between those quarks are reflected. The reason why we cannot see radiation that comes from for example gluons or channels between quarks is that gluons are so small particles. They send radiation that wavelength is the same as their size. So that's why we cannot see that radiation quite easily.
And that causes an idea that dark energy is wave movement that comes from some point if the atom that we just notice it. There is a possibility that gravitational waves are interacting only with strings between atoms that form molecules.
Or maybe that reflection happens from inside a proton or neutron where gravitation interacts with gluon channels or gluons that are traveling between quarks. When that energy hits the gluon sends it through an energy channel between it and the quark. But a little bit of that wave movement travels straight out from the atom.
There are two versions of how gravitational waves can form dark energy.
1) Energy can transform in some particles. So when the gravitational wave hits some particle or particle's substructure that structure modifies its frequency.
2) Black holes and their gravitational waves themselves are the sources of dark energy. That means dark energy is antigravitation.
1) Gravitational waves can impact something. That is turning that extra gravitational energy into dark energy. So dark energy forms when some yet unknown particle transforms the wavelength of gravitational waves. Those particles can be "real particles". Or they can be virtual particles like small gravitational tornadoes.
Sometimes individual superstring of electrons is introduced as the source of dark energy. In that case, when gravitational wave impacts the superstring which acts like a guitar string and sends wave movement around the universe.
2) Gravitational waves can themselves be dark energy. In that model, the gravitational wave that travels in the opposite direction can form a situation where gravitation turns to repel objects.
Black holes send gravitational waves all the time. That thing forms the model where black holes are like outwards traveling gravitational waves. And that means the event horizon is moving all the time. So that thing makes an interesting model of the gravitation around extremely massive objects.
When gravitational waves travel out of the black hole. They are forming a vacuum behind them. That vacuum pulls objects into the black hole. Just in the middle of a black hole is the point where gravitational waves are forming statues or standing gravitational waves.
When particles and wave movement are falling to the black hole's center. They are stuck to that gravitational statute called a singularity. There is the possibility that gravitational waves are forming closer to the event horizon. The requirement for that thing is a standing gravitational wave.
When a gravitational wave travels out from a black hole it loses its energy. A black hole pulls also those waves back in. Or otherways all times when those outwards traveling gravitational wave impacts incoming particle and releases their energy to that particle. And in the point of the event horizon, its strength is dropped and it starts to let information travel through it in both directions.
The energy level of the singularity increases until it turns higher than the energy that travels into the black hole. When the energy level of the black hole's center rises high enough it sends a gravitational wave. The power of a gravitational wave must be high enough that it can break the pull of a black hole.
When those gravitational waves are impacting the point called the event horizon. Their energy turns lower. That energy impacts particles that are close to an event horizon.
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