mathman said:I doubt if anyone has written a book on this subject. If you google "axion" you will get a lot of material, including some historical background, as well as implications for dark matter. This may be enough.
Jodo Kast said:Typically, theorized particles have been discovered.
Vanadium 50 said:You couldn't be more wrong. Most have not been discovered, and there are so many mutually contradictory theories out there that it's safe to say most will never be discovered.
You probably want to look at Pierre Sikivie's http://arxiv.org/pdf/hep-ph/9506229". That's the most elementary introduction out there.
Jodo Kast said:Thanks for the link; looks like a good read. If most particles that have been theorized have not been discovered, then there are many more particles than I am aware of. The books I have tend to be very realistic and list what particles have been discovered, which led me to believe that theoreticians have been doing a very good job. Particle physics seems very simple to me, with a small set of fermions (which lead to baryons) and bosons (which lead to mesons). Now that I know about axions and Majorana neutrinos (as opposed to the familiar Dirac neutrinos), I'm beginning to suspect things are a lot more complicated.
Axions are hypothetical particles that were proposed in the 1970s to solve a problem in the Standard Model of particle physics. They are thought to be very light and have no electric charge, making them difficult to detect.
Scientists are currently conducting experiments to try to detect axions and confirm their existence. They are also exploring the potential implications of axions for various theories, such as dark matter and the origin of the universe.
Some theories suggest that axions could make up a portion of dark matter, the mysterious substance that makes up about 85% of the matter in the universe. However, this has not been confirmed and is still a topic of research.
Scientists are using a variety of methods to search for axions, including particle accelerators, telescopes, and laboratory experiments. These methods involve looking for the effects of axions on other particles or using specialized equipment to directly detect them.
If axions are found to exist, they could have significant implications for our understanding of the universe and could potentially lead to new technologies. For example, they could be used to develop new forms of energy or improve our understanding of fundamental physics principles.