Sure.Is there any research going into antimatter at the moment?
Beta+ decays produce positrons without particle accelerators.Is it possible to create antimatter on Earth without using a particle accelerator?
When the Tevatron was still operational, antiprotons were kept circulating in its main ring for ~10-12 hours at a time.|mathematix| said:Is it possible to contain a sample of antimatter without it interacting and annihilating with matter?
See post 2.|mathematix| said:What about uncharged antimatter, is it possible to contain it?
That is a good approximation, indeed.I read that all the antimatter ever produce on Earth produces enough energy to heat a cup of coffee.
Economically for which application? No matter how you produce it (given the current knowledge of physics), it is very expensive.Is it theoretically possible to produce antimatter economically and efficiently?
Particle accelerators. Or completely new, undiscovered physics.Theoretically, what kind of technology would allow?
mfb said:Or completely new, undiscovered physics.
Antimatter is a type of matter composed of antiparticles, which have the opposite properties of regular particles. It is important to store antimatter because it has the potential to be used as a source of energy for space travel and other advanced technologies.
Yes, it is possible to contain antimatter. However, it is a difficult and complex process as antimatter has a tendency to annihilate when it comes into contact with regular matter. Scientists are continuously researching and developing new methods to contain antimatter more effectively.
Currently, antimatter is being stored using magnetic fields in specialized devices called Penning traps. These traps use a combination of electric and magnetic fields to keep the antimatter particles from coming into contact with regular matter and annihilating.
One of the biggest challenges in storing antimatter is its tendency to annihilate when it comes into contact with regular matter. Additionally, it is very expensive and energy-intensive to produce antimatter, making it difficult to create and store large quantities of it.
Antimatter has the potential to be used as a highly efficient and powerful source of energy for space travel, as well as for medical imaging and cancer treatment. It could also be used in the production of new materials and fuels for various industries.