That is a substantial amount of electrons. Consider Avogadro's number.dansmith170 said:
Charge on one electron is -1.602177 x 10-19 C, so 5 E24 would provide -801.9 kC of charge, which is a lot of charge, and there is an equivalent magnitude of charge of positrons +801.9 kC. One might look into how one stores electrons in that quantity. Would could also calculate the force required to separate the charges as a function of distance. Positrons have to be stored in a magnetic field, since in contact with normal matter, they annihilate with electrons.dansmith170 said:
Astronuc, thanks for the links and info! I didn't want to use normal pair production because I'm trying to produce the matter without using-up some supply of "fuel." That is why I prefer the multiphoton production. The generation of positrons is not exactly what I'm interested in, it's the production of positrons and electrons that would then be used as propellant aboard a "propellantless" spaceship.Astronuc said:
See link belowOne has to consider the energy necessary to produce the appropriate photons. One doesn't just generate electron-positron pairs out of thin air, or vacuum, as the case may be.dansmith170 said:Astronuc, thanks for the links and info! I didn't want to use normal pair production because I'm trying to produce the matter without using-up some supply of "fuel." That is why I prefer the multiphoton production. The generation of positrons is not exactly what I'm interested in, it's the production of positrons and electrons that would then be used as propellant aboard a "propellantless" spaceship.
I see, I guess I was thinking that the energy for accelerating the electrons and any other energy needed for pair production could be sourced externally as from an external laser aimed at the rocket (perhaps an array of lasers in the solar system). Although I suppose this would still be less efficient than just using light to propel the craft.Astronuc said:
Breit Wheeler Matter Production is a process in which matter is created from pure energy, following Albert Einstein's famous equation E=mc². It involves colliding two high-energy photons (particles of light) to create a pair of matter particles, such as an electron and a positron.
Traditional particle colliders, such as the Large Hadron Collider, involve colliding particles of matter at high speeds to study their interactions. Breit Wheeler Matter Production, on the other hand, involves colliding particles of pure energy (photons) to create matter particles.
Breit Wheeler Matter Production is significant because it provides a way to create matter from pure energy, which was previously only thought to be possible in extreme conditions such as the early universe. This process could also help us better understand the fundamental nature of matter and energy.
Yes, Breit Wheeler Matter Production has been observed in laboratory experiments using high-powered lasers to produce the high-energy photons needed for the collision. However, the process is still in its early stages of development and more research is needed to fully understand and control it.
Some potential applications of Breit Wheeler Matter Production include creating new sources of energy and studying the properties of matter in extreme conditions. It could also potentially be used in medical imaging and cancer treatment, as well as in the development of new technologies in the future.