Standard Model

The Standard Model of particle physics is a theory of three of the four known fundamental interactions and the elementary particles that take part in these interactions. These particles make up all visible matter in the universe. The standard model is a gauge theory of the electroweak and strong interactions with the gauge group SU(3)×SU(2)×U(1).

Every high energy physics experiment carried out since the mid-20th century has eventually yielded findings consistent with the Standard Model. Still, the Standard Model falls short of being a complete theory of fundamental interactions because it does not include gravitation, dark matter, or dark energy. It is not quite a complete description of leptons either, because it does not describe nonzero neutrino masses, although simple natural extensions do.

Historical background

The first step towards the Standard Model was Sheldon Glashow's discovery, in 1960, of a way to combine the electromagnetic and weak interactions.^[1] In 1967, Steven Weinberg^[2] and Abdus Salam^[3] incorporated the Higgs mechanism^[4]^[5]^[6] into Glashow's electroweak theory, giving it its modern form.

The Higgs mechanism is believed to give rise to the rest masses of all the elementary particles, for which the Standard Model accounts. This includes the rest masses of the W and Z bosons, and the fermions. The Higgs mechanism is also believed to give rise to the mass of quarks and leptons. Quarks are fundamental components, which make up the hadrons, and leptons are elementary particles, with no fundamental components, such as the electron. (See the table above, which depicts the Standard Model).

After the discovery at CERN of neutral weak currents,^[7]^[8]^[9]^[10] caused by
Z
boson exchange, the electroweak theory became widely accepted. Glashow, Salam, and Weinberg shared the 1979 Nobel Prize in Physics for discovering the electroweak theory. The W and Z bosons were discovered experimentally in 1981, and their masses were found to be as the Standard Model predicted.

The theory of the strong interaction, to which many contributed, acquired its modern form around 1973–74, when experiments confirmed that the hadrons were composed of fractionally charged quarks.

Overview

At present, matter and energy are best understood in terms of the kinematics and interactions of elementary particles. To date, physics has reduced the laws governing the behavior and interaction of all known forms of matter and energy, to a small set of fundamental laws and theories. A major goal of physics is to find the "common ground" that would unite all of these theories into one integrated theory of everything, of which all the other known laws would be special cases, and from which the behavior of all matter and energy could be derived (at least in principle). "Details can be worked out if the situation is simple enough for us to make an approximation, which is almost never, but often we can understand more or less what is happening." (The Feynman Lectures on Physics, Vol 1. 2–7)

The Standard Model groups two major extant theories — quantum electroweak and quantum chromodynamics — into an internally consistent theory describing the interactions between all experimentally observed particles. The Standard Model describes each type of particle in terms of a mathematical field, via quantum field theory. For a technical description of these fields and their interactions, see Standard Model (mathematical formulation).

Particle content

Elementary particles: fermions

Organization of Fermions
	Charge	First generation		Second generation		Third generation
Quarks	+2⁄3	Up	u	Charm	c	Top	t
Quarks	−1⁄3	Down	d	Strange	s	Bottom	b
Leptons	−1	Electron	e⁻	Muon	μ⁻	Tauon	τ⁻
Leptons	0	Electron neutrino	ν _e	Muon neutrino	ν _μ	Tauon neutrino	ν _τ

The Standard Model includes 12 elementary particles of spin-1⁄2 known as fermions. According to the spin-statistics theorem, fermions respect the Pauli Exclusion Principle. Each fermion has a corresponding antiparticle.

The fermions of the Standard Model are classified according to how they interact (or equivalently, by what charges they carry). There are six quarks (up, down, charm, strange, top, bottom), and six leptons (electron, electron neutrino, muon, muon neutrino, tauon, tauon neutrino). Pairs from each classification are grouped together to form a generation, with corresponding particles exhibiting similar physical behavior (see table).

The defining property of the quarks is that they carry color charge, and hence, interact via the strong interaction. The infrared confining behavior of the strong force results in quarks being perpetually (or at least since very soon after the start of the big bang) bound to one another, forming color-neutral composite particles (hadrons) containing either a quark and an antiquark (mesons) or three quarks (baryons). The familiar proton and the neutron are the two baryons having the smallest mass. Quarks also carry electric charge and weak isospin. Hence they interact with other fermions both electromagnetically and via the weak nuclear interaction.

The remaining six fermions do not carry color charge and are called leptons. The three neutrinos do not carry electric charge either, so their motion is directly influenced only by the weak nuclear force, which makes them notoriously difficult to detect. However, by virtue of carrying an electric charge, the electron, muon, and tauon all interact electromagnetically.

Each member of a generation has greater mass than the corresponding particles of lower generations. The first generation charged particles do not decay; hence all ordinary (baryonic) matter is made of such particles. Specifically, all atoms consist of electrons orbiting atomic nuclei ultimately constituted of up and down quarks. Second and third generations charged particles, on the other hand, decay with very short half lives, and are observed only in very high-energy environments. Neutrinos of all generations also do not decay and pervade the universe, but rarely interact with baryonic matter.

Force mediating particles

Interactions in physics are the ways that particles influence other particles. At a macro level, electromagnetism allows particles to interact with one another via electric and magnetic fields, and gravitation allows particles with mass to attract one another in accordance with Newton's law of universal gravitation. The standard model explains such forces as resulting from matter particles exchanging other particles, known as force mediating particles. When a force mediating particle is exchanged, at a macro level the effect is equivalent to a force influencing both of them, and the particle is therefore said to have mediated (i.e., been the agent of) that force. Force mediating particles are believed to be the reason why the forces and interactions between particles observed in the laboratory and in the universe exist.

The known force mediating particles described by the Standard Model also all have spin (as do matter particles), but in their case, the value of the spin is 1, meaning that all force mediating particles are bosons. As a result, they do not follow the Pauli Exclusion Principle. The different types of force mediating particles are described below.

Photons mediate the electromagnetic force between electrically charged particles. The photon is massless and is well-described by the theory of quantum electrodynamics.

The
W⁺
,
W⁻
, and
Z
gauge bosons mediate the weak interactions between particles of different flavors (all quarks and leptons). They are massive, with the
Z
being more massive than the
W^±
. The weak interactions involving the
W^±
act on exclusively left-handed particles and right-handed antiparticles. Furthermore, the
W^±
carry an electric charge of +1 and −1 and couple to the electromagnetic interactions. The electrically neutral
Z
boson interacts with both left-handed particles and antiparticles. These three gauge bosons along with the photons are grouped together which collectively mediate the electroweak interactions.

The eight gluons mediate the strong interactions between color charged particles (the quarks). Gluons are massless. The eightfold multiplicity of gluons is labeled by a combination of color and an anticolor charge (e.g., red–antigreen).^{[nb 1]} Because the gluon has an effective color charge, they can interact among themselves. The gluons and their interactions are described by the theory of quantum chromodynamics.

The interactions between all the particles described by the Standard Model are summarized by the diagram at the top of this section.

The Higgs boson

The Higgs particle is a massive scalar elementary particle predicted by the Standard Model. It has no intrinsic spin, and for that reason is classified as a boson (like the force mediating particles, which have integer spin). Because an exceptionally large amount of energy and beam luminosity are theoretically required to observe a Higgs boson in high energy colliders, it is the only fundamental particle predicted by the Standard Model that has yet to be observed.

The Higgs boson plays a unique role in the Standard Model, by explaining why the other elementary particles, the photon and gluon excepted, are massive. In particular, the Higgs boson would explain why the photon has no mass, while the W and Z bosons are very heavy. Elementary particle masses, and the differences between electromagnetism (mediated by the photon) and the weak force (mediated by the W and Z bosons), are critical to many aspects of the structure of microscopic (and hence macroscopic) matter. In electroweak theory, the Higgs boson generates the masses of the leptons (electron, muon, and tauon) and quarks.

As yet, no experiment has directly detected the existence of the Higgs boson, but there is some indirect evidence for it.^{[citation needed]} It is hoped that the Large Hadron Collider at CERN will confirm the existence of this particle. It is also possible that the Higgs boson may already have been produced but overlooked.^[11]

Field content

The standard model has the following fields:

Spin 1

A U(1) gauge field B_μν with coupling g′ (weak U(1), or weak hypercharge)
An SU(2) gauge field W_μν with coupling g (weak SU(2), or weak isospin)
An SU(3) gauge field G_μν with coupling g_s (strong SU(3), or color charge)

Spin 1⁄2

The spin 1⁄2 particles are in representations of the gauge groups. For the U(1) group, we list the value of the weak hypercharge instead. The left-handed fermionic fields are:

An SU(3) singlet, SU(2) doublet with U(1) weak hypercharge −1 (left-handed lepton)
An SU(3) singlet, SU(2) singlet with U(1) weak hypercharge 2 (left-handed antilepton)
An SU(3) triplet, SU(2) doublet, with U(1) weak hypercharge 1⁄3 (left-handed quarks)
An SU(3) triplet, SU(2) singlet, with U(1) weak hypercharge −4⁄3 (left-handed up-type antiquark)
An SU(3) triplet, SU(2) singlet, with U(1) weak hypercharge 2⁄3 (left-handed down-type antiquark)

By CPT symmetry, there is a set of right-handed fermions with the opposite quantum numbers.

This describes one generation of leptons and quarks, and there are three generations, so there are three copies of each field. Note that there are twice as many left-handed lepton field components as left-handed antilepton field components in each generation, but an equal number of left-handed quark and antiquark fields.

Spin 0

An SU(2) doublet H with U(1) hyper-charge −1 (Higgs field)

Note that |H|², summed over the two SU(2) components, is invariant under both SU(2) and under U(1), and so it can appear as a renormalizable term in the Lagrangian, as can its square.^{[clarification needed]}

This field acquires a vacuum expectation value, leaving a combination of the weak isospin, I₃, and weak hypercharge unbroken. This is the electromagnetic gauge group, and the photon remains massless. The standard formula for the electric charge (which defines the normalization of the weak hypercharge, Y, which would otherwise be somewhat arbitrary) is:^{[nb 2]}

Q=I_{\mathrm {3} }+{\frac {Y}{2}}

Lagrangian

The Lagrangian for the spin 1 and spin 1⁄2 fields is the most general renormalizable gauge field Lagrangian with no fine tunings:

Spin 1:

\int -{1 \over 4}B_{\mu \nu }B^{\mu \nu }-{1 \over 4}\mathrm {tr} W_{\mu \nu }W^{\mu \nu }-{1 \over 4}\mathrm {tr} G_{\mu \nu }G^{\mu \nu }

where the traces are over the SU(2) and SU(3) indices hidden in W and G respectively. The two-index objects are the field strengths derived from W and G the vector fields. There are also two extra hidden parameters: the theta angles for SU(2) and SU(3).

The spin 1⁄2 particles can have no mass terms because there is no right/left helicity pair with the same SU(2) and SU(3) representation and the same weak hypercharge. This means that if the gauge charges were conserved in the vacuum, none of the spin 1⁄2 particles could ever swap helicity, and they would all be massless.

For a neutral fermion, for example a hypothetical right-handed lepton N (or N^α in relativistic two-spinor notation), with no SU(3), SU(2) representation and zero charge, it is possible to add the term:^{[clarification needed]}

\int MN^{\alpha }N^{\beta }\epsilon _{\alpha \beta }+{\bar {N_{\dot {\alpha }}}}{\bar {N_{\dot {\beta }}}}\epsilon ^{{\dot {\alpha }}{\dot {\beta }}}

This term gives the neutral fermion a Majorana mass. Since the generic value for M will be of order 1, such a particle would generically be unacceptably heavy. The interactions are completely determined by the theory – the leptons introduce no extra parameters.

Higgs mechanism

The Lagrangian for the Higgs includes the most general renormalizable self interaction:

S_{\mathrm {Higgs} }=\int d^{4}x\left[(D_{\mu }H)^{*}(D^{\mu }H)+\lambda (|H|^{2}-v^{2})^{2}\right]

The parameter v² has dimensions of mass squared, and it gives the location where the classical Lagrangian is at a minimum. In order for the Higgs mechanism to work, v² must be a positive number. v has units of mass, and it is the only parameter in the standard model which is not dimensionless. It is also much smaller than the Planck scale, it is approximately equal to the Higgs mass and sets the scale for the mass of everything else. This is the only real fine-tuning to a small nonzero value in the standard model, and it is called the Hierarchy problem.

It is traditional to choose the SU(2) gauge so that the Higgs doublet in the vacuum has expectation value (v,0).

Masses and CKM matrix

The rest of the interactions are the most general spin-0 spin-1⁄2 Yukawa interactions, and there are many of these. These constitute most of the free parameters in the model. The Yukawa couplings generate the masses and mixings once the Higgs gets its vacuum expectation value.

The terms L^*HR^{[clarification needed]} generate a mass term for each of the three generations of leptons. There are 9 of these terms, but by relabeling L and R, the matrix can be diagonalized. Since only the upper component of H is nonzero, the upper SU(2) component of L mixes with R to make the electron, the muon, and the tauon, leaving over a lower massless component, the neutrino.

The terms QHU^{[clarification needed]} generate up masses, while QHD^{[clarification needed]} generate down masses. But since there is more than one right-handed singlet in each generation, it is not possible to diagonalize both with a good basis for the fields, and there is an extra CKM matrix.

Theoretical aspects

Construction of the Standard Model Lagrangian

Parameters of the Standard Model
Symbol	Description	Renormalization scheme (point)	Value
m_e	Electron mass		511 keV
m_μ	Muon mass		106 MeV
m_τ	Tauon mass		1.78 GeV
m_u	Up quark mass	μ_MS = 2 GeV	1.9 MeV
m_d	Down quark mass	μ_MS = 2 GeV	4.4 MeV
m_s	Strange quark mass	μ_MS = 2 GeV	87 MeV
m_c	Charm quark mass	μ_MS = m_c	1.32 GeV
m_b	Bottom quark mass	μ_MS = m_b	4.24 GeV
m_t	Top quark mass	On-shell scheme	172.7 GeV
θ₁₂	CKM 12-mixing angle		13.1°
θ₂₃	CKM 23-mixing angle		2.4°
θ₁₃	CKM 13-mixing angle		0.2°
δ	CKM CP-violating Phase		0.995
g₁	U(1) gauge coupling	μ_MS = m_Z	0.357
g₂	SU(2) gauge coupling	μ_MS = m_Z	0.652
g₃	SU(3) gauge coupling	μ_MS = m_Z	1.221
θ_QCD	QCD vacuum angle		~0
μ	Higgs quadratic coupling		Unknown
λ	Higgs self-coupling strength		Unknown

Technically, quantum field theory provides the mathematical framework for the standard model, in which a Lagrangian controls the dynamics and kinematics of the theory. Each kind of particle is described in terms of a dynamical field that pervades space-time. The construction of the standard model proceeds following the modern method of constructing most field theories: by first postulating a set of symmetries of the system, and then by writing down the most general renormalizable Lagrangian from its particle (field) content that observes these symmetries.

The global Poincaré symmetry is postulated for all relativistic quantum field theories. It consists of the familiar translational symmetry, rotational symmetry and the inertial reference frame invariance central to the theory of special relativity. The local SU(3)×SU(2)×U(1) gauge symmetry is an internal symmetry that essentially defines the standard model. Roughly, the three factors of the gauge symmetry give rise to the three fundamental interactions. The fields fall into different representations of the various symmetry groups of the Standard Model (see table). Upon writing the most general Lagrangian, one finds that the dynamics depend on 19 parameters, whose numerical values are established by experiment. The parameters are summarized in the table at right.

The QCD sector

The electroweak sector

The electroweak sector is a Yang–Mills gauge theory with the symmetry group U(1)×SU(2)_L,

{\mathcal {L}}_{\mathrm {EW} }=\sum _{\psi }{\bar {\psi }}\gamma ^{\mu }\left(i\partial _{\mu }-g^{\prime }{1 \over 2}Y_{\mathrm {W} }B_{\mu }-g{1 \over 2}{\vec {\tau }}_{\mathrm {L} }{\vec {W}}_{\mu }\right)\psi

where B_μ is the U(1) gauge field; Y_W is the weak hypercharge — the generator of the U(1) group; ${\vec {W}}_{\mu }$ is the three-component SU(2) gauge field; ${\vec {\tau }}_{\mathrm {L} }$ are the Pauli matrices — infinitesimal generators of the SU(2) group. The subscript L indicates that they only act on left fermions; g′ and g are coupling constants.

The Higgs sector

In the Standard Model, the Higgs field is a complex spinor of the group SU(2)_L:

\varphi ={1 \over {\sqrt {2}}}\left({\begin{array}{c}\varphi ^{+}\\\varphi ^{0}\end{array}}\right)\;,

where the indexes + and 0 indicate the electric charge (Q) of the components. The weak isospin (Y_W) of both components is 1.

Before symmetry breaking, the Higgs Lagrangian is:

{\mathcal {L}}_{\mathrm {H} }=\varphi ^{\dagger }\left({\partial _{\mu }}-{i \over 2}\left(g'Y_{\mathrm {W} }B_{\mu }+g{\vec {\tau }}{\vec {W}}_{\mu }\right)\right)\left(\partial _{\mu }+{i \over 2}\left(g'Y_{\mathrm {W} }B_{\mu }+g{\vec {\tau }}{\vec {W}}_{\mu }\right)\right)\varphi \ -\ {\lambda ^{2} \over 4}\left(\varphi ^{\dagger }\varphi -v^{2}\right)^{2}\;,

which can also be written as:

{\mathcal {L}}_{\mathrm {H} }=\left|\left(\partial _{\mu }+{i \over 2}\left(g'Y_{\mathrm {W} }B_{\mu }+g{\vec {\tau }}{\vec {W}}_{\mu }\right)\right)\varphi \right|^{2}\ -\ {\lambda ^{2} \over 4}\left(\varphi ^{\dagger }\varphi -v^{2}\right)^{2}\;.

Additional symmetries of the Standard Model

From the theoretical point of view, the Standard Model exhibits four additional global symmetries, not postulated at the outset of its construction, collectively denoted accidental symmetries, which are continuous U(1) global symmetries. The transformations leaving the Lagrangian invariant are:

\psi _{\text{q}}(x)\rightarrow e^{i\alpha /3}\psi _{\text{q}}

E_{L}\rightarrow e^{i\beta }E_{L}{\text{ and }}(e_{R})^{c}\rightarrow e^{i\beta }(e_{R})^{c}

M_{L}\rightarrow e^{i\beta }M_{L}{\text{ and }}(\mu _{R})^{c}\rightarrow e^{i\beta }(\mu _{R})^{c}

T_{L}\rightarrow e^{i\beta }T_{L}{\text{ and }}(\tau _{R})^{c}\rightarrow e^{i\beta }(\tau _{R})^{c}.

The first transformation rule is shorthand meaning that all quark fields for all generations must be rotated by an identical phase simultaneously. The fields $M_{L}$ , $T_{L}$ and $(\mu _{R})^{c}$ , $(\tau _{R})^{c}$ are the 2nd (muon) and 3rd (tauon) generation analogs of $E_{L}$ and $(e_{R})^{c}$ fields.

By Noether's theorem, each symmetry above has an associated conservation law: the conservation of baryon number, electron number, muon number, and tauon number. Each quark is assigned a baryon number of 1/3, while each antiquark is assigned a baryon number of -1/3. Conservation of baryon number implies that the number of quarks minus the number of antiquarks is a constant. Within experimental limits, no violation of this conservation law has been found.

Similarly, each electron and its associated neutrino is assigned an electron number of +1, while the antielectron and the associated antineutrino carry −1 electron number. Similarly, the muons and their neutrinos are assigned a muon number of +1 and the tau leptons are assigned a tau lepton number of +1. The Standard Model predicts that each of these three numbers should be conserved separately in a manner similar to the way baryon number is conserved. These numbers are collectively known as lepton family numbers (LF). Symmetry works differently for quarks than for leptons, mainly because the Standard Model predicts that neutrinos are massless. However, it was recently found that neutrinos have small masses and oscillate between flavors, signaling that the conservation of lepton family number is violated.

In addition to the accidental (but exact) symmetries described above, the Standard Model exhibits several approximate symmetries. These are the "SU(2) custodial symmetry" and the "SU(2) or SU(3) quark flavor symmetry."

Symmetries of the Standard Model and Associated Conservation Laws
Symmetry	Lie Group	Symmetry Type	Conservation Law
Poincaré	Translations ×SO(3,1)	Global symmetry	Energy, Momentum, Angular momentum
Gauge	SU(3)×SU(2)×U(1)	Local symmetry	Color charge, Weak isospin, Electric charge, Weak hypercharge
Baryon phase	U(1)	Accidental Global symmetry	Baryon number
Electron phase	U(1)	Accidental Global symmetry	Electron number
Muon phase	U(1)	Accidental Global symmetry	Muon number
Tauon phase	U(1)	Accidental Global symmetry	Tauon number

Field content of the Standard Model
Field (1st generation)		Spin	Gauge group Representation	Baryon Number	Electron Number
Left-handed quark	$Q_{\text{L}}\,$	$1/2\,$	( $\mathbf {3} \,$ , $\mathbf {2} \,$ , $+1/3\,$ )	$1/3\,$	$0\,$
Left-handed up antiquark	${\bar {u}}_{\text{L}}\equiv (u_{\text{R}})^{c}\,$	$1/2\,$	( ${\bar {\mathbf {3} }}\,$ , $\mathbf {1} \,$ , $-4/3\,$ )	$-1/3\,$	$0\,$
Left-handed down antiquark	${\bar {d}}_{\text{L}}\equiv (d_{\text{R}})^{c}\,$	$1/2\,$	( ${\bar {\mathbf {3} }}\,$ , $\mathbf {1} \,$ , $+2/3\,$ )	$-1/3\,$	$0\,$
Left-handed lepton	$L_{\text{L}}\,$	$1/2\,$	( $\mathbf {1} \,$ , $\mathbf {2} \,$ , $-1\,$ )	$0\,$	$1\,$
Left-handed antielectron	${\bar {e}}_{\text{L}}\equiv (e_{\text{R}})^{c}\,$	$1/2\,$	( $\mathbf {1} \,$ , $\mathbf {1} \,$ , $+2\,$ )	$0\,$	$-1\,$
Hypercharge gauge field	$B_{\mu }\,$	$1\,$	( $\mathbf {1} \,$ , $\mathbf {1} \,$ , $0\,$ )	$0\,$	$0\,$
Isospin gauge field	$W_{\mu }\,$	$1\,$	( $\mathbf {1} \,$ , $\mathbf {3} \,$ , $0\,$ )	$0\,$	$0\,$
Gluon field	$G_{\mu }\,$	$1\,$	( $\mathbf {8} \,$ , $\mathbf {1} \,$ , $0\,$ )	$0\,$	$0\,$
Higgs field	$H\,$	$0\,$	( $\mathbf {1} \,$ , $\mathbf {2} \,$ , $+1\,$ )	$0\,$	$0\,$

List of standard model fermions

This table is based in part on data gathered by the Particle Data Group (Template:PDFlink).

**Left-handed fermions in the Standard Model**
Generation 1
Fermion (left-handed)	Symbol	Electric charge	Weak isospin	Weak hypercharge	Color charge *	Mass **
Electron	$e^{-}\,$	$-1\,$	$-1/2\,$	$-1\,$	${\mathbf {1}}\,$	511 keV
Positron	$e^{+}\,$	$+1\,$	$0\,$	$+2\,$	${\mathbf {1}}\,$	511 keV
Electron neutrino	$\nu _{e}\,$	$0\,$	$+1/2\,$	$-1\,$	${\mathbf {1}}\,$	< 2 eV ****
Antielectron neutrino	${\bar {\nu }}_{e}\,$	$0\,$	$0\,$	$0\,$	${\mathbf {1}}\,$	< 2 eV ****
Up quark	$u\,$	$+2/3\,$	$+1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	~ 3 MeV ***
Up antiquark	${\bar {u}}\,$	$-2/3\,$	$0\,$	$-4/3\,$	${\mathbf {\bar {3}}}\,$	~ 3 MeV ***
Down quark	$d\,$	$-1/3\,$	$-1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	~ 6 MeV ***
Down antiquark	${\bar {d}}\,$	$+1/3\,$	$0\,$	$+2/3\,$	${\mathbf {\bar {3}}}\,$	~ 6 MeV ***

Generation 2
Fermion (left-handed)	Symbol	Electric charge	Weak isospin	Weak hypercharge	Color charge *	Mass **
Muon	$\mu ^{-}\,$	$-1\,$	$-1/2\,$	$-1\,$	${\mathbf {1}}\,$	106 MeV
Antimuon	$\mu ^{+}\,$	$+1\,$	$0\,$	$+2\,$	${\mathbf {1}}\,$	106 MeV
Muon neutrino	$\nu _{\mu }\,$	$0\,$	$+1/2\,$	$-1\,$	${\mathbf {1}}\,$	< 2 eV ****
Antimuon neutrino	${\bar {\nu }}_{\mu }\,$	$0\,$	$0\,$	$0\,$	${\mathbf {1}}\,$	< 2 eV ****
Charm quark	$c\,$	$+2/3\,$	$+1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	~ 1.337 GeV
Charm antiquark	${\bar {c}}\,$	$-2/3\,$	$0\,$	$-4/3\,$	${\mathbf {\bar {3}}}\,$	~ 1.3 GeV
Strange quark	$s\,$	$-1/3\,$	$-1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	~ 100 MeV
Strange antiquark	${\bar {s}}\,$	$+1/3\,$	$0\,$	$+2/3\,$	${\mathbf {\bar {3}}}\,$	~ 100 MeV

Generation 3
Fermion (left-handed)	Symbol	Electric charge	Weak isospin	Weak hypercharge	Color charge *	Mass **
Tauon	$\tau ^{-}\,$	$-1\,$	$-1/2\,$	$-1\,$	${\mathbf {1}}\,$	1.78 GeV
Antitauon	$\tau ^{+}\,$	$+1\,$	$0\,$	$+2\,$	${\mathbf {1}}\,$	1.78 GeV
Tauon neutrino	$\nu _{\tau }\,$	$0\,$	$+1/2\,$	$-1\,$	${\mathbf {1}}\,$	< 2 eV ****
Antitauon neutrino	${\bar {\nu }}_{\tau }\,$	$0\,$	$0\,$	$0\,$	${\mathbf {1}}\,$	< 2 eV ****
Top quark	$t\,$	$+2/3\,$	$+1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	171 GeV
Top antiquark	${\bar {t}}\,$	$-2/3\,$	$0\,$	$-4/3\,$	${\mathbf {\bar {3}}}\,$	171 GeV
Bottom quark	$b\,$	$-1/3\,$	$-1/2\,$	$+1/3\,$	${\mathbf {3}}\,$	~ 4.2 GeV
Bottom antiquark	${\bar {b}}\,$	$+1/3\,$	$0\,$	$+2/3\,$	${\mathbf {\bar {3}}}\,$	~ 4.2 GeV
Notes: * These are not ordinary abelian charges, which can be added together, but are labels of group representations of Lie groups. Mass is really a coupling between a left-handed fermion and a right-handed fermion. For example, the mass of an electron is really a coupling between a left-handed electron and a right-handed electron, which is the antiparticle of a left-handed positron. Also neutrinos show large mixings in their mass coupling, so it's not accurate to talk about neutrino masses in the flavor basis or to suggest a left-handed electron antineutrino. *** The masses of baryons and hadrons and various cross-sections are the experimentally measured quantities. Since quarks can't be isolated because of QCD confinement, the quantity here is supposed to be the mass of the quark at the renormalization scale of the QCD scale. ****** The Standard Model assumes that neutrinos are massless. However, several contemporary experiments prove that neutrinos oscillate between their flavour states, which could not happen if all were massless.^[12] It is straightforward to extend the model to fit these data but there are many possibilities, so the mass eigenstates are still open. See Neutrino#Mass.

Tests and predictions

The Standard Model (SM) predicted the existence of the W and Z bosons, gluon, and the top and charm quarks before these particles were observed. Their predicted properties were experimentally confirmed with good precision. To give an idea of the success of the SM, the following table compares the measured masses of the W and Z bosons with the masses predicted by the SM:

Quantity	Measured (GeV)	SM prediction (GeV)
Mass of W boson	80.398 ± 0.025	80.390 ± 0.018
Mass of Z boson	91.1876 ± 0.0021	91.1874 ± 0.0021

The SM also makes several predictions about the decay of Z bosons, which have been experimentally confirmed by the Large Electron-Positron Collider at CERN.

Challenges to the standard model

Unsolved problem in physics:

What gives rise to the Standard Model of particle physics?
Why do particle masses and coupling constants have the values that we measure?
Does the Higgs boson really exist?
Why are there three generations of particles?

(more unsolved problems in physics)

There is some experimental evidence consistent with neutrinos having mass, which the Standard Model does not allow. To accommodate such findings, the Standard Model can be modified by adding a non-renormalizable interaction of lepton fields with the square of the Higgs field. This is natural in certain grand unified theories, and if new physics appears at about 10¹⁶ GeV, the neutrino masses are of the right order of magnitude.

Currently, there is one elementary particle predicted by the Standard Model that has yet to be observed: the Higgs boson. A major reason for building the Large Hadron Collider is that the high energies of which it is capable are expected to make the Higgs observable. However, as of August 2008, there is only indirect empirical evidence for the existence of the Higgs boson, so that its discovery cannot be claimed.

A fair amount of theoretical and experimental research has attempted to extend the Standard Model into a Unified Field Theory, a complete theory explaining all physical phenomena. Inadequacies of the Standard Model that motivate such research include:

Does not attempt to explain gravitation, and there is no known way of adapting the quantum field theory of the sort the Standard Model employs freely, with general relativity, the canonical theory of gravitation. This means, among other things, that we have no good theory for the very early universe;
Seems rather ad-hoc and inelegant, requiring 19 numerical constants whose values are unrelated and arbitrary. Although the Standard Model, as it now stands, cannot explain why neutrinos have masses (and the specifics of neutrino mass are still unclear), it is believed that explaining neutrino mass will require an additional 7 or 8 constants;
Gives rise to the hierarchy problem, namely why the weak scale and Planck scale are so disparate;
Should be modified so as to be consistent with the emerging "standard model of cosmology." Specifically, a truly satisfactory theory of the elementary particles and of the fundamental interactions must explain the initial conditions of the universe that gave rise to certain observed properties of the present-day universe, properties such as the predominance of matter over antimatter (matter/antimatter asymmetry), and its isotropy and homogeneity over large distances.

Notes and references

Notes

^ Technically, there are nine such color–anticolor combinations. However there is one color symmetric combination that can be constructed out of a linear superposition of the nine combinations, reducing the count to eight.
^ The normalization Q = I₃ + Y is sometimes used instead.

References

^ Sheldon L. Glashow (1961). "Partial-symmetries of weak interactions". Nuclear Physics. 22: 579–588. doi:10.1016/0029-5582(61)90469-2.
^ Steven Weinberg (1967). "A Model of Leptons". Physical Review Letters. 19: 1264–1266. doi:10.1103/PhysRevLett.19.1264.
^ Abdus Salam (1968). Nils Svartholm (ed.). Elementary Particle Physics: Relativistic Groups and Analyticity. Eighth Nobel Symposium. Stockholm: Almquvist and Wiksell. p. 367. {{cite conference}}: Unknown parameter |booktitle= ignored (|book-title= suggested) (help)
^ F. Englert and R. Brout (1964). "Broken Symmetry and the Mass of Gauge Vector Mesons". Physical Review Letters. 13: 321–323. doi:10.1103/PhysRevLett.13.321.
^ Peter W. Higgs (1964). "Broken Symmetries and the Masses of Gauge Bosons". Physical Review Letters. 13: 508–509. doi:10.1103/PhysRevLett.13.508.
^ G. S. Guralnik, C. R. Hagen, and T. W. B. Kibble (1964). "Global Conservation Laws and Massless Particles". Physical Review Letters. 13: 585–587. doi:10.1103/PhysRevLett.13.585.{{cite journal}}: CS1 maint: multiple names: authors list (link)
^ F. J. Hasert; et al. (1973). "Search for elastic muon-neutrino electron scattering". Physics Letters B. 46: 121. doi:10.1016/0370-2693(73)90494-2. {{cite journal}}: Explicit use of et al. in: |author= (help)
^ F. J. Hasert; et al. (1973). "Observation of neutrino-like interactions without muon or electron in the gargamelle neutrino experiment". Physics Letters B. 46: 138. doi:10.1016/0370-2693(73)90499-1. {{cite journal}}: Explicit use of et al. in: |author= (help)
^ F. J. Hasert; et al. (1974). "Observation of neutrino-like interactions without muon or electron in the Gargamelle neutrino experiment". Nuclear Physics B. 73: 1. doi:10.1016/0550-3213(74)90038-8. {{cite journal}}: Explicit use of et al. in: |author= (help)
^ "The discovery of the weak neutral currents". CERN Courier. 4 October 2004. Retrieved 2008-05-08.
^ "Higgs Hiding in Plain Sight?". ScienceNOW. 23 January 2008. Retrieved 2008-05-08.
^ Particle Data Group (2006/2007). "Review of Particle Physics: Neutrino mass, mixing, and flavor change" (PDF). {{cite web}}: Check date values in: |year= (help)CS1 maint: year (link)

External links

"Standard Model may be found incomplete," New Scientist.
"Observation of the Top Quark" at Fermilab.
"The Standard Model Lagrangian." After electroweak symmetry breaking, with no explicit Higgs boson.
"Standard Model Lagrangian" with explicit Higgs terms. PDF, PostScript, and LaTeX versions.
"The particle adventure." Web tutorial.
Nobes, Matthew (2002) "Introduction to the Standard Model of Particle Physics" on Kuro5hin: Part 1, Part 2, Part 3a, Part 3b.

[11] Technically, there are nine such color–anticolor combinations. However there is one color symmetric combination that can be constructed out of a linear superposition of the nine combinations, reducing the count to eight.

[13] The normalization Q = I₃ + Y is sometimes used instead.

[1] Sheldon L. Glashow (1961). "Partial-symmetries of weak interactions". Nuclear Physics. 22: 579–588. doi:10.1016/0029-5582(61)90469-2.

[2] Steven Weinberg (1967). "A Model of Leptons". Physical Review Letters. 19: 1264–1266. doi:10.1103/PhysRevLett.19.1264.

[3] Abdus Salam (1968). Nils Svartholm (ed.). Elementary Particle Physics: Relativistic Groups and Analyticity. Eighth Nobel Symposium. Stockholm: Almquvist and Wiksell. p. 367. {{cite conference}}: Unknown parameter |booktitle= ignored (|book-title= suggested) (help)

[4] F. Englert and R. Brout (1964). "Broken Symmetry and the Mass of Gauge Vector Mesons". Physical Review Letters. 13: 321–323. doi:10.1103/PhysRevLett.13.321.

[5] Peter W. Higgs (1964). "Broken Symmetries and the Masses of Gauge Bosons". Physical Review Letters. 13: 508–509. doi:10.1103/PhysRevLett.13.508.

[6] G. S. Guralnik, C. R. Hagen, and T. W. B. Kibble (1964). "Global Conservation Laws and Massless Particles". Physical Review Letters. 13: 585–587. doi:10.1103/PhysRevLett.13.585.{{cite journal}}: CS1 maint: multiple names: authors list (link)

[7] F. J. Hasert; et al. (1973). "Search for elastic muon-neutrino electron scattering". Physics Letters B. 46: 121. doi:10.1016/0370-2693(73)90494-2. {{cite journal}}: Explicit use of et al. in: |author= (help)

[8] F. J. Hasert; et al. (1973). "Observation of neutrino-like interactions without muon or electron in the gargamelle neutrino experiment". Physics Letters B. 46: 138. doi:10.1016/0370-2693(73)90499-1. {{cite journal}}: Explicit use of et al. in: |author= (help)

[9] F. J. Hasert; et al. (1974). "Observation of neutrino-like interactions without muon or electron in the Gargamelle neutrino experiment". Nuclear Physics B. 73: 1. doi:10.1016/0550-3213(74)90038-8. {{cite journal}}: Explicit use of et al. in: |author= (help)

[10] "The discovery of the weak neutral currents". CERN Courier. 4 October 2004. Retrieved 2008-05-08.

[12] "Higgs Hiding in Plain Sight?". ScienceNOW. 23 January 2008. Retrieved 2008-05-08.

[14] Particle Data Group (2006/2007). "Review of Particle Physics: Neutrino mass, mixing, and flavor change" (PDF). {{cite web}}: Check date values in: |year= (help)CS1 maint: year (link)

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