Chan Pok Fung said:But the electron and positron possesses initial kinetic energy meaning that it is difficult for them to really collide in each other. Just like Earth is not dropping into the Sun even with the gravitational pull.
Drakkith said:Their attraction results in an acceleration of both charges, which causes the emission of electromagnetic radiation. This robs energy from both of them and causes them to very quickly spiral into each other.
As for the distance scale where annihilation occurs, I admit I don't know.
Chan Pok Fung said:We know that electrons are not emitting EM waves while "orbiting" around a proton, as long as they stay at the steady state (the orbital). Is it possible that an electron-positron system also has such a steady state so that they don't annihilate?
Chan Pok Fung said:We know that electrons are not emitting EM waves while "orbiting" around a proton, as long as they stay at the steady state (the orbital). Is it possible that an electron-positron system also has such a steady state so that they don't annihilate?
Or decay to any higher s orbital and annihilate from there. Or to a molecular or crystal orbital with s character at positron.mfb said:They can annihilate directly if they come close enough (not exactly a well-defined thing in quantum mechanics, but the classical analogy is not too bad here). The probability (the cross section) decreases with increasing energy. They can also form positronium first, decay to its ground state and then annihilate from there.
Not impossible but very unlikely.snorkack said:Or decay to any higher s orbital and annihilate from there.
If you measure it: Sure.snorkack said:Does an unbound orbit have a well-defined orbital angular momentum (s, p etc.)?
Not in case of 2s orbital.mfb said:Not impossible but very unlikely.
It doesn't have to, it is just the typical case. Annihilation can happen at higher energies. Particle colliders use this routinely.geoelectronics said:At rest it will contain 511 keV of mass energy, anything above that level must be lost to the environment before annihilation can occur.
link to a nice paper that reveals a lot about the 5 modes of e-p (or as I call it beta- / beta+ annihilation) annihilation:mfb said:SuperKEKB
An electron is a subatomic particle with a negative charge that orbits the nucleus of an atom. A positron is the antiparticle of an electron, with the same mass but a positive charge.
Electrons and positrons are considered unstable because they have a tendency to spontaneously annihilate each other, releasing energy in the form of photons. This is due to their opposite charges and the fact that they are antiparticles of each other.
The average lifetime of an electron and positron before annihilation is very short, on the order of 1 x 10^-22 seconds. This is due to the strong electromagnetic force between the particles.
Yes, under certain conditions, such as in a vacuum or in the presence of a strong magnetic field, electrons and positrons can be stable. This is because these conditions can prevent the particles from coming into contact and annihilating each other.
The instability of electrons and positrons plays a crucial role in the formation of matter in the universe. In the early stages of the universe, high energy collisions between particles created equal amounts of matter and antimatter, including electrons and positrons. However, due to their instability, the majority of these particles annihilated each other, leaving behind a small excess of matter that eventually formed the structures we see in the universe today.