You know what, you are right. I was reading the page for neutrino wrong. I mistook the two words. It does say that neutrinos are candidates right here: https://en.wikipedia.org/wiki/NeutrinoChalnoth said:What Wikipedia page is this? Because it isn't correct.
Anti-neutrinos are just the anti-matter partner of neutrinos. There were a large number of neutrinos and anti-neutrinos produced in the early universe (essentially equal numbers of each), but their total mass is much too small to explain dark matter. In particular, their velocities are too high to explain the formation of structure in the early universe.
What might be a candidate is a "sterile neutrino", which is a hypothetical type of neutrino that doesn't interact with normal matter as easily as the three known species of neutrino. This sterile neutrino would have to be far more massive than the known neutrino species to account for observations.
endoftimes said:WIkipedia says antineutrinos are candidates for dark matter.
It's actually pretty difficult to get multiple different components of dark matter where one doesn't completely dominate over the others. Even very small changes in mass or how much they interact can lead to very large differences of abundance. So the best bet is that a single type of particle makes up the vast majority of dark matter.Chronos said:Neutrinos are the low hanging fruit on the dark matter tree, but, have too little mass to be of much cosmological consequence. Sterile neutrinos might fill another gap, but, it appears the tree roots grow deeperr than that. I expect by the time we account for the majority of dark matter, we will have a complex mix of particles to add to the standard model
Antineutrinos are subatomic particles that have no electric charge and a very small mass. They are related to dark matter because some theories suggest that they could make up a significant portion of the mysterious substance that makes up a large part of the universe.
Scientists are using a variety of methods to search for antineutrinos as potential candidates for dark matter. These include underground detectors, such as the Super-Kamiokande experiment, which can detect the faint signals of antineutrinos interacting with matter.
Antineutrinos are considered good candidates for dark matter because they have several properties that make them suitable for this role. They are abundant in the universe, they have a small mass, and they interact very weakly with other particles, making them difficult to detect.
There is currently no conclusive evidence that antineutrinos are dark matter. However, some indirect evidence, such as observations of the cosmic microwave background radiation and the rotation of galaxies, support the idea that dark matter could be made up of particles like antineutrinos.
Studying antineutrinos as potential dark matter candidates presents several challenges for scientists. One major challenge is that antineutrinos are difficult to detect and require specialized equipment, making it a costly and time-consuming process. Additionally, there are still many unknowns about the properties and behavior of antineutrinos, making it challenging to study them in depth.