They aren't 3 they are in fact 12 if you count anti matter as a separate particle from matter.
Electron, muon, tau, electron neutrino, muon neutrino and tau neutrino.
The same apply to anti matter positron, anti muon, anti tau, postrin neutrino, anti muon neutrino, and anti tau neutrino.
The conservation of lepton number in particle physics is important because it helps to explain why certain particles exist and why certain interactions occur. Lepton number conservation ensures that the total number of leptons (such as electrons and neutrinos) remains constant in a given reaction, which helps to maintain the stability and balance of fundamental particles in the universe. Violations of lepton number conservation could lead to new discoveries and insights into the nature of particle interactions.
The lepton number of an electron is important in particle physics because it helps to determine the conservation of leptons in interactions. Lepton number is a fundamental property that must be conserved in particle interactions, and it helps to understand the behavior of particles and their interactions in the subatomic world.
The wavelength of a lepton is inversely proportional to its momentum, which is related to its energy and mass. The spin of a lepton is a fundamental property intrinsic to the particle itself, independent of its momentum or wavelength.
An antineutrino is a subatomic particle that is the antimatter counterpart of a neutrino. It has opposite properties, such as opposite electric charge and lepton number, compared to a neutrino. Neutrinos are neutral particles, while antineutrinos have a negative charge.
There are far more than just two sub-atomic particles: electron, muon, and tau lepton; just for starters. The two types of such particles -- at least in the classification system of 2011 -- are quarks and leptons.
The conservation of lepton number in particle physics is important because it helps to explain why certain particles exist and why certain interactions occur. Lepton number conservation ensures that the total number of leptons (such as electrons and neutrinos) remains constant in a given reaction, which helps to maintain the stability and balance of fundamental particles in the universe. Violations of lepton number conservation could lead to new discoveries and insights into the nature of particle interactions.
Lepton is the common name given to electron, positron, neutrino, antinuetrino, mu-meson [muon] etc. So an atom has these elementary particles within and come out in specific circumstances.
The lepton number of an electron is important in particle physics because it helps to determine the conservation of leptons in interactions. Lepton number is a fundamental property that must be conserved in particle interactions, and it helps to understand the behavior of particles and their interactions in the subatomic world.
Leptons are divided into three families with 4 particles (2 particles, plus their two anti-particles) in each family. In the electron family we have the electron, positron, electron neutrino and electron anti-neutrino. Each family has a higher mass than the one before it so the tauon is heavier than the muon which is heavier than the electron. The physical reason for there being three families is completely unknown and will probably win you a Nobel prize if you can figure it out!
The smallest particle that retains the properties of an element is an atom. Quarks and leptons are just a family of elementary particles and do not carry any properties of the element.
i know this also includes the Photon which does not combine into anything. So how does 15 combine to create 3 subatomic particles? Actually, the electron is a lepton, so 15 making 2??
Internal subatomic particles refer to the constituents of atoms, primarily protons and neutrons, which are found in the nucleus, and electrons that orbit around the nucleus. Protons and neutrons themselves are made up of quarks, which are held together by the strong force mediated by gluons. Electrons, on the other hand, are considered elementary particles and belong to the lepton family. Together, these particles define the structure and properties of atoms, forming the basis of matter in the universe.
That should be the lepton. The electronic lepton (e-) to be accurate. More information: http://en.wikipedia.org/wiki/Lepton
Electrons, down quarks, strange quarks, bottom quarks, muon lepton, and tau lepton all have negative charge. Also, the boson can be negative.
The wavelength of a lepton is inversely proportional to its momentum, which is related to its energy and mass. The spin of a lepton is a fundamental property intrinsic to the particle itself, independent of its momentum or wavelength.
muon
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