The idea behind Recycled Dark Matter is that dark matter is produced in a specific mechanism that researchers have dubbed “recycling” in a paper awaiting peer-review, because dark matter forms twice in the universe, with weird quantum mechanics and a black hole phase in the middle
A theory suggests that dark matter may be recycled to form an invisible periodic table of elements. The theory is that dark matter is produced through a process called “recycling”. This process occurs when dark matter forms twice in the universe, with the help of quantum mechanics and a black hole phase. This process is thought to have happened shortly after the beginning of the cosmos, about 13.8 billion years ago.
The theory suggests that the following process may have occurred:
- Particles got trapped into ultradense pockets
- Some of those pockets splintered off to become black holes
- These cosmic voids likely dissolved into a shower of multiple dark matter particle “species”
- This created a “dark matter periodic table” of invisible elements
Dark matter makes up about 85 percent of the total matter in the universe. It played an important role in the formation of galaxies. Dark matter is not known to interact with ordinary baryonic matter and radiation except through gravity, making it difficult to detect in the laboratory.
Dark matter is invisible because it doesn’t interact with electromagnetic radiation. It doesn’t absorb, reflect, or emit light. It’s also transparent.
Scientists can only infer the existence of dark matter from its gravitational effect on visible matter. Dark matter makes galaxies and galaxy clusters move in ways that don’t match the gravitational pull of other matter.
Scientists know dark matter exists because of its gravitational effect on visible matter. Dark matter can be found wherever normal matter is.
Here are some ways scientists detect dark matter:
- Gravitational lensing Dark matter’s gravity bends and distorts light from more distant objects.
- X-ray radiation Massive galaxy clusters emit X-ray radiation that confirms the presence of dark matter.
- Cosmic rays and gamma rays Dark matter can be detected indirectly through specific signatures in cosmic rays and gamma rays.
- Underground detectors Large, sensitive detectors located deep underground can directly search for dark matter particles.
The earliest evidence for dark matter in our universe is the pattern of fluctuations in the CMB, which dates from approximately 380,000 years after the Big Bang.
Dark matter is not antimatter because we don’t see the gamma rays that are produced when antimatter and matter annihilate.
Antimatter is matter with the opposite electrical charge to normal matter. For example, an electron has a negative charge, while a positron (an antimatter electron) has a positive charge. When a particle meets its anti-particle, they annihilate and release gamma photons.
Dark matter only interacts with gravity and the weak atomic force. It doesn’t interact with electromagnetism or the strong atomic force, so it can’t be seen and is hard to detect
Dark matter particles will only annihilate with anti-dark matter particles of the same type. For example, an electron will annihilate with a positron but not with an anti-muon or anti-proton. If you were to place positrons or anti-protons and dark matter together nothing would happen.
When matter and antimatter collide, the particles destroy each other, with a huge energy release. This energy is heat, light, and new, different particles may also be produced. For example, electrons and anti-electrons, also known as positrons, become gamma rays.
Dark matter can’t collide with normal matter. Dark matter can only interact with normal matter through gravity. This means that dark matter can’t bump into normal matter.
However, dark matter particles can penetrate all other forms of matter. For example, dark matter particles can pass through the Earth without losing any energy. When dark matter particles interact with normal matter inside a rock, a proton or neutron can get knocked loose. This can change the chemical composition of the rock.
Dark matter can also collide with and be absorbed by normal matter. For example, when a large burst of star formation takes place in a galaxy, the radiation can collide with and be absorbed by the normal matter.
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