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According to the [[Standard Model]] of particle physics quarks are one of the two fundamental building blocks of matter, the other being [[Lepton|leptons]]. There are six known flavours of quarks: up, down, strange, charm, bottom and top. The up, charm and top quarks have a positive electrical charge with a magnitude two thirds that of an electron whereas the down, strange and bottom quarks have a negative charge with a magnitude one third that of an electron.
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According to the [[Standard_Model#Quarks|standard model]] of particle physics, '''quarks''' are one of the two fundamental building blocks of matter, the other being [[Lepton|leptons]]. (The name was invented by the late [[Murray Gell-Mann]] (1929-2019), taken from [[Finnegans Wake]] by [[James Joyce]].} There are six known flavours of quarks: up, down, strange, charm, bottom, and top. The up, charm, and top quarks have a positive electrical charge with a magnitude two thirds that of an electron whereas the down, strange, and bottom quarks have a negative charge with a magnitude one third that of an electron.  Protons contain two up quarks and one down quark, thus resulting in a net charge of +1, while neutrons contain two down quarks and one up quark and therefore have no net charge.


In addition to an electric charge all quarks also carry a colour charge and so will interact via the [[Strong Force|strong nuclear force]]. The properties of this [[Strong Force|strong force]] leads to a property called [[Confinement|confinement]] whereby, at low energies, quarks are bound into states, called [[Hadron|hadrons]], with no net colour charge. Two types hadrons are known to exist: [[Meson|mesons]] which are a quark bound with an anti-quark and [[Baryon|baryons]] which are three quarks bound together. In the early twenty first century some experimental data suggesting four and five quark bound states was published but firm evidence of these states remains to be found.
In addition to an electric charge all quarks also carry a colour charge and so will interact via the [[Strong Force|strong nuclear force]] and are the only [[fermion]]s with this property. The properties of this [[Strong Force|strong force]] lead to a phenomenon called [[Confinement|confinement]] where, at low energies, quarks are bound into states, called [[Hadron|hadrons]], with no net colour charge. Two types of hadrons are known to exist: [[Meson|mesons]], which are a quark bound with an anti-quark, and [[Baryon|baryons]], which are three quarks (or three anti-quarks) bound together. In the early twenty-first century some experimental data suggesting four and five quark bound states was published but firm evidence of these states remains to be found.


The one exception to the confinement rule is the top quark which decays with a lifetime less than 5x10<sup>-25</sup>s. This is so rapid that there is insufficient time for the quark to hadronize i.e. form bound hadronic states. Thus top quarks are unique in decaying as a free quark and so offer a unique opportunity to measure the properties of a free quark directly.
The one exception to the confinement rule is the instance when a top quark decays with a lifetime less than <math>5\times10^{-25}\textrm{s}</math>. This decay is so rapid that there is insufficient time for the quark to hadronize, i.e., form bound hadronic states. Thus top quarks are unique in decaying as free quarks and so offer a unique opportunity to measure the properties of free quarks directly.


Just like the [[Lepton|leptons]] quarks are divided into three generations, each consisting of two quarks: one up-like quark and one down-like quark. Only the first generation, containing the up and down quarks, is stable. Only the weak force is capable of mixing generations of quarks.
Just like the [[Lepton|leptons]], quarks are divided into three generations, each consisting of two quarks: one up-like quark and one down-like quark. Only the first generation, containing the up and the down quark, is stable. Although quarks can interact via all four fundamental forces of nature, only the weak force does not conserve quark flavour. This is because the weak flavour eigenstates are not the same as the strong, EM, and mass eigenstates and hence the weak force introduces a mixing between flavours. This mixing can be expressed as a 3x3 unitary matrix, called the Cabibbo-Kobayashi-Maskawa (CKM) matrix, shown here in with the standard elements and the Wolfenstein parameterization:


[[Category:CZ Live]]
:<math>V=\left(\begin{matrix} V_{ud} & V_{us} & V_{ub} \\
[[Category:Stub Articles]]
                            V_{cd} & V_{cs} & V_{cb} \\
[[Category:Physics Workgroup]]
                            V_{td} & V_{ts} & V_{tb} \end{matrix}\right)
 
      =\left(\begin{matrix} 1 - \lambda^2/2            & \lambda        & A \lambda^3(\rho -i \eta) \\
                            -\lambda                  & 1 - \lambda^2/2 & A \lambda^2              \\
                            A \lambda^3(1 - \rho -i \eta) & -A \lambda^2  & 1 \end{matrix} \right)
</math>[[Category:Suggestion Bot Tag]]

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According to the standard model of particle physics, quarks are one of the two fundamental building blocks of matter, the other being leptons. (The name was invented by the late Murray Gell-Mann (1929-2019), taken from Finnegans Wake by James Joyce.} There are six known flavours of quarks: up, down, strange, charm, bottom, and top. The up, charm, and top quarks have a positive electrical charge with a magnitude two thirds that of an electron whereas the down, strange, and bottom quarks have a negative charge with a magnitude one third that of an electron. Protons contain two up quarks and one down quark, thus resulting in a net charge of +1, while neutrons contain two down quarks and one up quark and therefore have no net charge.

In addition to an electric charge all quarks also carry a colour charge and so will interact via the strong nuclear force and are the only fermions with this property. The properties of this strong force lead to a phenomenon called confinement where, at low energies, quarks are bound into states, called hadrons, with no net colour charge. Two types of hadrons are known to exist: mesons, which are a quark bound with an anti-quark, and baryons, which are three quarks (or three anti-quarks) bound together. In the early twenty-first century some experimental data suggesting four and five quark bound states was published but firm evidence of these states remains to be found.

The one exception to the confinement rule is the instance when a top quark decays with a lifetime less than . This decay is so rapid that there is insufficient time for the quark to hadronize, i.e., form bound hadronic states. Thus top quarks are unique in decaying as free quarks and so offer a unique opportunity to measure the properties of free quarks directly.

Just like the leptons, quarks are divided into three generations, each consisting of two quarks: one up-like quark and one down-like quark. Only the first generation, containing the up and the down quark, is stable. Although quarks can interact via all four fundamental forces of nature, only the weak force does not conserve quark flavour. This is because the weak flavour eigenstates are not the same as the strong, EM, and mass eigenstates and hence the weak force introduces a mixing between flavours. This mixing can be expressed as a 3x3 unitary matrix, called the Cabibbo-Kobayashi-Maskawa (CKM) matrix, shown here in with the standard elements and the Wolfenstein parameterization: