AI can find answers to many secrets in the universe.
Image 1) The model of bosonic cloud.
There is introduced an idea. That boson can also form the stars.
Is dark matter the missing bosons below Higgs boson? There is no confirmed information that some particles are missing in the Standard model. But because every line of the table is the same number of particles. There is the possibility. That is in the line of the Higgs boson could be three previously unknown particles.
There is introduced an idea. That boson can also form the stars. Like fermions could do. There is not a certain observation of the quark stars.
But those things would be the fermion stars. Quarks are fermions. But could also other fermions like electrons form the stars like giant electron crystals. And could bosons make the same thing? Maybe someday the AI can answer those questions.
Image 2 Fundamental particles of Standard Model
The AI can search molecules from exoplanets. And it can also solve the mystery of dark matter.
The AI can find molecules from the exoplanet atmosphere. And maybe someday the AI can find extraterrestrial lifeforms. And even alien civilizations and new natural laws. The thing is that artificial intelligence needs the matrix that is used to compile the data. That is collected from the astronomical instruments.
This is why researchers should send the telescope far away from the Sun. That telescope can collect data on what planet Earth looks like far away from it. Then that data can compile with the data that telescopes are collecting. And maybe someday those systems and AI can find the alien race.
The conditions of exoplanets can be extreme. The high temperature and extremely high radiation levels on the planets. Can cause that the atmosphere of the planet has an atomic form. That means the annealing of those atoms is pushing other atoms away from them. And that thing denies the form of molecules.
The conditions on exoplanets continue for millions of years. So that thing can make the chemical and physical environment that does not exist on Earth.
Maybe AI can solve the mystery of the ninth planet and dark matter.
Artificial intelligence is making it possible to analyze large data masses. And maybe that thing can solve the mystery of "Planet 9" or the mysterious errors in the trajectory of planet Neptune. There is a possibility that the mysterious X-ray bursts in the atmosphere of Uranus. Aave the connection with that phenomenon that causes those anomalies in the trajectory of Neptune.
Could that thing be the small black hole? If the black hole aims the particle flow passes it by using a parabolic trajectory that thing can happen without causing gamma-ray emission near the black hole itself.
There is the possibility that the mysterious "Planet 9" is even more exotic than some black hole. Could that thing be the bubble of dark matter? Or when we are talking about the things like Fermion stars. We are forgetting that there is the possibility that there is some kind of bosonic star in the universe.
Could it be possible that the fermion or bosonic stars are pushing particles away? The idea is that when those particles are spinning they are sending radiation. There is mentioned an "exotic star"
The term "An exotic star is a hypothetical compact star composed of something other than electrons, protons, neutrons, or muons". So could the bosons create that "exotic star"? (https://en.wikipedia.org/wiki/Exotic_star)
And that radiation can push objects or particles away. The reason why we cannot see that radiation could be the particle that sends the wave movement has a different size than particles that we know.
The fermion stars would be large electron crystals. And there is the possibility. That also bosons can create crystal structures. The quark stars would be the fermion stars. But the thing is that the boson stars would be even more exotic.
Image 3: Artists impression of Exoplanet KELT-9B
There is introduced an idea. That ghostly bosonic clouds are the key to dark matter. The idea is that the dark matter is actually "missing bosons" below the Higgs Boson. So that means that if those bosons are creating crystal structures those structures might be very ghostly.
The question is, could it be possible that the fermion or bosonic stars can also push objects away? In that case, the high energy load that hits those mysterious objects causes the case that fermions or bosons are starting to spin. They are releasing energy as radiation.
And that radiation can push objects away from the fermion or boson star. The reason why we cannot see that particle would be. That particle that sends that radiation or wave movement has a different size than particles that we already know.
There has been introduced an idea. That the ghostly bosonic clouds can be the key to dark matter. So could the dark matter be the "missing bosons" below Higgs boson?
Sources:
https://www.livescience.com/planet-nine-little-black-hole.html
https://newsbeezer.com/indonesiaeng/temperature-exoplanet-kelt-9b-similar-to-star-temperature/
https://physicsworld.com/a/x-ray-emissions-from-uranus-are-detected-for-the-first-time/
https://scitechdaily.com/ghostly-boson-clouds-could-solve-the-mystery-of-dark-matter/
https://theconversation.com/ai-can-reliably-spot-molecules-on-exoplanets-and-might-one-day-even-discover-new-laws-of-physics-172701
https://en.wikipedia.org/wiki/Exotic_star
https://en.wikipedia.org/wiki/Quark_star
https://en.wikipedia.org/wiki/Standard_Model
Image 1)https://scitechdaily.com/ghostly-boson-clouds-could-solve-the-mystery-of-dark-matter/
Image 2)https://en.wikipedia.org/wiki/Standard_Model
Image 3)https://awsimages.detik.net.id/visual/2015/08/15/4fbf27d9-ead2-4c98-b31d-44fe0dff7bbc_169.jpg?w=650
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