"Using advanced infrared spectroscopy, researchers set record-breaking limits on the lifetime of a dark matter candidate called the axionlike particle. Their findings refine our understanding of dark matter while hinting at possible anomalies that could bring us closer to discovery. (Artist’s concept.) Credit: SciTechDaily.com" (ScitechDaily, The Universe Is Hiding Something Huge – And Scientists Are Closer Than Ever to Finding It)
The mystic web in the universe can be the key to dark matter and maybe to dark energy. Those very large structures in the universe could uncover dark matter's nature. In some models, dark matter forms extremely large strings whose diameter can be billions of light years.
Dark matter does not exist at all points in the universe. And that thing can explain some part of dark energy. The axion, or hypothetical dark matter particle can send wave movement that makes it interact with other axions.
Can Axion be the WIMP? Both of them are hypothetical particles. So, maybe we can think that the axion and WIMP are the same thing. But are those particles real or quasiparticles? Can the axion be a particle in superposition with a hole that is similar to an exciton? If that superposition is possible that means the particle can send its radiation to its hole and that can make the particle invisible.
The axion can be WIMP, or WIMP can be an axionlike particle. So, we can write about axion and WIMP as the same particle until their existence is proved. And their real nature is uncovered.
But axions (or axionlike particles). Weakly interacting massive particles WIMPs are so different than visible material that they cannot have other types of interactions. There is the possibility that the axion spins so fast that the radiation slides over it causing a situation where there is no reflection. The new observations tell about the theoretical limits of the axion or WIMP lifetime. Another thing is that those megastructures are interesting.
They are things that put energy into moving in the universe. And maybe those things help open the dark matter mystery. If a dark matter particle exists and it turns radiation that particle sends radiation that affects other dark matter particles.
"The quantum fluctuations inherent to space, stretched across the Universe during cosmic inflation, gave rise to the density fluctuations imprinted in the cosmic microwave background, which in turn gave rise to the stars, galaxies, and other large-scale structures in the Universe today. This is the best picture we have of how the entire Universe behaves, where inflation precedes and sets up the Big Bang. Unfortunately, we can only access the information contained inside our cosmic horizon, which is all part of the same fraction of one region where inflation ended some 13.8 billion years ago." (BigThink, Ask Ethan: Does the multiverse explain our fundamental constants?)
"This chart of particles and interactions details how the particles of the Standard Model interact according to the three fundamental forces that quantum field theory describes. When gravity is added into the mix, we obtain the observable Universe that we see, with the laws, parameters, and constants that we know of governing it. However, many of the parameters that nature obeys cannot be predicted by theory, they must be measured to be known, and those are “constants” that our Universe requires, to the best of our knowledge." (BigThink, Ask Ethan: Does the multiverse explain our fundamental constants?)
That can cause so-called dark energy interaction between those particles. If the WIMP that turns into energy can push other dark matter particles that thing can scatter the dark matter structures. And that decreases the dark matter gravitational effect.
In some models the dark energy forms because there is some energy source outside the universe. This means that hypothetical radiation can form an electromagnetic shadow on the other side of the particle. That EM shadow makes energy travel in it. And that thing can cause a gravitational effect. The energy field that travels into the particles forms situations where particles store that energy. The universe's expansion and maybe the outside gravity effect can explain the universe's expansion acceleration.
The particle releases that energy only if its energy level rises higher than the environment. Because the energy level around the particle is always lower the particle sends flashes that are stronger than it should.
But that collective radiation model requires that there is another universe. Or some object that can send that radiation. Logically multiverse should exist. But getting evidence about that thing is very hard.
The dark matter and dark energy are not closing each other away. If multiverse does not exist another good candidate for dark energy is the "vaporization" of dark matter. In some models, dark matter clouds outside the universe pull visible matter outward. That can explain the universe's expansions. And dark matter vaporization can explain some things like dark energy and why the universe expands faster than it should.
When dark matter turns into radiation or wave movement, that thing decreases dark matter's gravitational effect. The thing that can push dark matter particles away from each other can be another dark matter particle. That sends radiation. When it transforms itself into energy.
This model means that the other universes send so pervasive radiation that it travels through other particles. The idea is that this hypothetical radiation can push quarks in the protons and neutrons like rolls and travel between them.
The problem is that the proton is more complicated than those three quarks. But it's possible that this kind of string-shaped radiation can travel between subatomic particles without causing reflection. That radiation string can travel over those particles and then the energy cannot travel to the particle.
It can impact with quantum field. If there is little space between that energy string that energy can travel to that lower energy space. And then the thin energy field or superstring can push it back to the particle.
https://bigthink.com/starts-with-a-bang/multiverse-explain-fundamental-constants/
https://scitechdaily.com/billion-light-year-superstructure-shakes-up-our-view-of-the-universe/
https://scitechdaily.com/the-universe-is-hiding-something-huge-and-scientists-are-closer-than-ever-to-finding-it/
https://en.wikipedia.org/wiki/Axion
https://en.wikipedia.org/wiki/Weakly_interacting_massive_particle
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