Antiparticle: Difference between revisions

Latest revision as of 03:35, 28 March 2024

The complementary particle to every subatomic particle, identical in mass and, if charged, identical in charge magnitude but with opposite sign.
If a particle has a magnetic (dipole) moment, its antiparticle has an equal and opposite magnetic moment. For example, the electron and positron comprise a particle–antiparticle pair. Because the electron was discovered first (and electrons are more abundant), the electron is the particle and the positron the antiparticle (antielectron), but this designation is arbitrary. The electron could just as well be called the antipositron. Collectively, antiparticles are called antimatter. When a particle and its antiparticle interact, they are annihilated, their energy living on in the form of gamma rays. The inverse process, pair production, is possible: A gamma ray photon interacting with an atomic nucleus may be annihilated, its energy taken up by an electron–positron pair. Some neutral particles are their own antiparticles (e.g., the photon and the neutral pion).

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+The complementary [[particle]] to every [[subatomic particle]], identical in mass and, if  charged, identical in charge magnitude but with opposite sign.<br/> If a particle has a magnetic ([[dipole]]) [[moment]], its antiparticle has an equal and opposite magnetic  moment. For example, the [[electron]] and [[positron]] comprise a particle&ndash;antiparticle pair. Because  the electron was discovered first (and electrons are more abundant), the electron is the particle and  the positron the antiparticle (antielectron), but this designation is arbitrary. The electron could  just as well be called the antipositron. Collectively, antiparticles are called antimatter. When a  particle and its antiparticle interact, they are annihilated, their [[energy]] living on in the form of  [[gamma rays]]. The inverse process, [[pair production]], is possible: A gamma ray photon interacting  with an atomic [[nucleus]] may be annihilated, its [[energy]] taken up by an electron&ndash;positron pair.  Some neutral particles are their own antiparticles (e.g., the [[photon]] and the neutral pion).<br/>
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-<div class="definition"><div class="short_definition">The complementary [[particle]] to every [[subatomic particle]], identical in mass and, if  charged, identical in charge magnitude but with opposite sign.</div><br/> <div class="paragraph">If a particle has a magnetic ([[dipole]]) [[moment]], its antiparticle has an equal and opposite magnetic  moment. For example, the [[electron]] and [[positron]] comprise a particle&ndash;antiparticle pair. Because  the electron was discovered first (and electrons are more abundant), the electron is the particle and  the positron the antiparticle (antielectron), but this designation is arbitrary. The electron could  just as well be called the antipositron. Collectively, antiparticles are called antimatter. When a  particle and its antiparticle interact, they are annihilated, their [[energy]] living on in the form of  [[gamma rays]]. The inverse process, [[pair production]], is possible: A gamma ray photon interacting  with an atomic [[nucleus]] may be annihilated, its [[energy]] taken up by an electron&ndash;positron pair.  Some neutral particles are their own antiparticles (e.g., the [[photon]] and the neutral pion).</div><br/> </div>
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