"Dark energy might not be a constant after all. DESI’s analysis of millions of galaxies shows signs that it could be evolving, hinting at a major shift in cosmology. Credit: SciTechDaily.com" (ScitechDaily, A Hidden Shift in Dark Energy Could Rewrite the Laws of Physics)
"The latest findings from the Dark Energy Spectroscopic Instrument (DESI) challenge long-held beliefs about dark energy." (ScitechDaily, A Hidden Shift in Dark Energy Could Rewrite the Laws of Physics)
Dark energy might not evolve. But relations between four interactions, electromagnetism, weak- and strong nuclear forces, and gravity evolving
When other energy forms turn weaker. Increases the role of dark energy in the universe. So when the universe turns colder it uncovers the dark energy. When other interactions turn weaker.
That raises the dark energy role in the system. That we know as the universe.
In the universe, dark energy doesn't probably evolve. But its interaction evolves. Because the universe itself evolves.
Maybe dark energy itself doesn't evolve. But the universe evolves. That means in the young universe the universe itself was hotter. The universe's size was smaller. That means the interactions had different types of strength than in the modern universe. The energy level in plasma between galaxies was hotter.
And that means also electromagnetism pushed galaxies away. In the young universe, dark energy interacted with electromagnetism because young galaxies were closer to each other and material was denser. That means the material between galaxies and galaxy clusters was hotter.
When the energy level between galaxies and galaxy nebulas was hotter that caused a stronger electromagnetic push-effect. That means the nature of the universe and the relations between interactions change.
The universe is a complex environment. And the entirety of the different interactions. The gravitation is not the only interaction. Things like material vaporization cause the effect. That wave movement pushes lightweight particles away from each other. Cosmic superstructures like the cosmic web cause the effect that gravity is not homogenously spread all around the universe. Those cosmic webs and material centers form asymmetry in gravity fields. And that puts material in the move.
We can say that dark energy is like all other energy forms. It has an effect on large-scale structures in the universe. The shape of that energy is and is not a mystery. Dark energy is wave movement.
Which could have an extremely short or extremely long wavelength.
If the dark energy has an extraordinary wavelength it's hard to see.
Let's say that the dark energy has a light-years-long wavelength. Or, a very short wavelength it is impossible to see changes in dark energy's energy level. And those changes are things that we see when we observe radiation.
Dark energy has an effect. Only on the biggest structures in the universe. That means that even in galactic superclusters gravity wins. So that energy interaction is visible only between galaxy superclusters.
That means that energy can affect the lightest particles in the universe. Those lightest particles form the biggest entireties in the universe. The question of dark energy is this: what makes that energy move?
That energy can have an effect on the large plasma structures in the universe. And in some visions dark energy forms in some kind of energy vacuum. Those vacuums cause energy asymmetry in the structures around the galactic supergroups. It's possible that dark energy forms when material between galactic superclusters vaporizes.
So the origin of that energy can be in some particles like neutrons, gluons, or neutrinos that vaporize or turn in the wave movement. When particles like neutrons decay they release gluons and quarks around them. Gluon doesn't exist for a long time in that low-energy environment. And it can be the key to dark energy.
And somebody suggested that the origin of this mysterious force is in other universes. Also, things like quantum-size black holes are suggested. Being the origin of that mysterious energy flow.
The plasma clusters can be many times bigger and heavier than all galaxies in the galactic superclusters. When something puts that plasma move it moves galaxies with it. It's possible. That other radiation covers dark energy below it.
But then we can say that dark energy evolving. Energy itself might not evolve but the universe around us evolves. The energy level in the universe decreases. That causes material vaporization. Or, the material turns into wave movement. That turns the material lighter. In the young universe electromagnetic interactions were stronger than in the cold universe. The universe expands. But the galactic clusters are reduced. Distance between local clusters decreases in superclusters.
And that turns their size smaller and lighter. That decreases their quantum gravity. Quantum gravity can have a longer distance effect in stable conditions where disturbing radiation doesn't cover that gravitational effect under it.
Plasma in those superclusters is hotter and the material in them turns denser. But that means the distance between the edges of the superclusters is increasing. That means the universe between those superclusters turns colder. That means the nature of the universe changes.
Differences in global scale energy levels turn higher. And that causes particles and energy to travel faster. When a particle travels in a cosmic vacuum it vaporizes faster than otherwise.
https://scitechdaily.com/a-hidden-shift-in-dark-energy-could-rewrite-the-laws-of-physics/
https://scitechdaily.com/is-the-universe-changing-breakthrough-data-suggests-dark-energy-is-evolving/
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