“New JWST observations hint that some of the universe’s first luminous bodies weren’t ordinary fusion stars at all, but supermassive dark stars – vast hydrogen-helium structures powered by dark-matter annihilation. A team now reports four ultra-distant candidates whose spectra and morphology fit this picture, including a tentative helium-ion (He II 1640 Å) absorption feature. If confirmed, these objects could help explain JWST’s puzzlingly bright early sources and the rapid rise of supermassive black holes. (Artist’s concept). Credit: SciTechDaily.com” (ScitechDaily)
JWST might have found a new type of star that takes its energy from dark matter. If that dark matter star exists, that thing can mean revolution in dark matter and dark energy research. JWST found that star at the edge of the universe, and it might be a giant structure of hydrogen and helium. And the dark matter annihilation or dark matter particles’ impacts give energy to the star.
That explains dark energy. This model also works with some virtual particles. If the dark matter is in so-called mini voids. Impacts of those minivoids can also release energy. When those voids impact the quantum walls around them. Impact each other, and that can send the energy wave to the universe.
There is also a possibility that dark matter itself doesn’t send energy that can interact with the helium and hydrogen. There is a possibility. Dark energy can interact with some subatomic particles. Like electrons or certain quark types. There is a possibility that dark energy has a short wavelength. It can affect only particles like gluons.
When dark energy impacts the particle. It raises its energy level and mass. If dark matter is the structure that spins at a very high speed. That thing binds energy fields into that structure. And that thing binds hydrogen and helium together. Dark energy can make. The star glows. If its density is high enough. The dark matter can release dark energy if the hypothetical Weakly Interacting Massive Particles (WIMPs). Impact with other WIMPs.
That thing explains why we cannot see dark matter or dark energy. But if dark matter impacts are sources of dark energy, we must realize that the dark matter itself could be some kind of energy field that surrounds some kind of energy pothole. In that model. A skyrmion or an exciton can create the pothole, which locks the wave surrounding that pothole. That makes an effect. That looks like a gravitational interaction.
But then we must realize. That things like black holes eat quantum fields. When those fields travel in the black holes, there are fewer fields left between black holes. The fields turn weaker. And they can transmit less energy than before. When black holes pull matter and dark matter inside them, that thing changes the relations between the four fundamental interactions.
In an extremely hot universe. Just after the Big Bang. The dominant interaction was the strong nuclear interaction. When the universe turned colder. The weak nuclear interaction turned dominant. After that, the electromagnetic interaction turned dominant. And when the universe was cold enough, the gravity turned dominant. This means. The quantum fields' density. Or their power determines which of the four fundamental interactions is dominant.
This means that if some particle. Or an object presses the quantum fields into a dense enough state that it can change the dominance. Or relations of the four fundamental interactions. This thing could revolutionize our way. Of seeing energy and matter.
https://scitechdaily.com/jwst-may-have-discovered-a-new-kind-of-star-powered-by-dark-matter/
https://en.wikipedia.org/wiki/Dark_energy
https://en.wikipedia.org/wiki/Dark_matter
https://en.wikipedia.org/wiki/Fundamental_interaction
No comments:
Post a Comment
Note: Only a member of this blog may post a comment.