This is a list of known and hypothesized particles.
Elementary particles are particles with no measurable internal structure; that is, it is unknown whether they are composed of other particles.[1] They are the fundamental objects of quantum field theory. Many families and sub-families of elementary particles exist. Elementary particles are classified according to their spin. Fermions have half-integer spin while bosons have integer spin. All the particles of the Standard Model have been experimentally observed, including the Higgs boson in 2012.[2][3] Many other hypothetical elementary particles, such as the graviton, have been proposed, but not observed experimentally.
Fermions are one of the two fundamental classes of particles, the other being bosons. Fermion particles are described by Fermi–Dirac statistics and have quantum numbers described by the Pauli exclusion principle. They include the quarks and leptons, as well as any composite particles consisting of an odd number of these, such as all baryons and many atoms and nuclei.
Fermions have half-integer spin; for all known elementary fermions this is 1⁄2. All known fermions except neutrinos, are also Dirac fermions; that is, each known fermion has its own distinct antiparticle. It is not known whether the neutrino is a Dirac fermion or a Majorana fermion.[4] Fermions are the basic building blocks of all matter. They are classified according to whether they interact via the strong interaction or not. In the Standard Model, there are 12 types of elementary fermions: six quarks and six leptons.
Quarks are the fundamental constituents of hadrons and interact via the strong force. Quarks are the only known carriers of fractional charge, but because they combine in groups of three quarks (baryons) or in pairs of one quark and one antiquark (mesons), only integer charge is observed in nature. Their respective antiparticles are the antiquarks, which are identical except that they carry the opposite electric charge (for example the up quark carries charge +2⁄3, while the up antiquark carries charge −2⁄3), color charge, and baryon number. There are six flavors of quarks; the three positively charged quarks are called "up-type quarks" while the three negatively charged quarks are called "down-type quarks".
| Generation | Name | Symbol | Antiparticle | Spin | Charge (e) |
Mass (MeV/c2) [5] |
|---|---|---|---|---|---|---|
| 1 | up | u | u |
1⁄2 | +2⁄3 | 2.2+0.6 −0.4 |
| down | d | d |
1⁄2 | −1⁄3 | 4.6+0.5 −0.4 | |
| 2 | charm | c | c |
1⁄2 | +2⁄3 | 1280±30 |
| strange | s | s |
1⁄2 | −1⁄3 | 96+8 −4 | |
| 3 | top | t | t |
1⁄2 | +2⁄3 | 173100±600 |
| bottom | b | b |
1⁄2 | −1⁄3 | 4180+40 −30 |
Leptons do not interact via the strong interaction. Their respective antiparticles are the antileptons, which are identical, except that they carry the opposite electric charge and lepton number. The antiparticle of an electron is an antielectron, which is almost always called a "positron" for historical reasons. There are six leptons in total; the three charged leptons are called "electron-like leptons", while the neutral leptons are called "neutrinos". Neutrinos are known to oscillate, so that neutrinos of definite flavor do not have definite mass: Instead, they exist in a superposition of mass eigenstates. The hypothetical heavy right-handed neutrino, called a "sterile neutrino", has been omitted.
| Generation | Name | Symbol | Antiparticle | Spin | Charge (e) |
Mass[5] (MeV/c2) |
|---|---|---|---|---|---|---|
| 1 | electron | e− |
e+ |
1 /2 | −1 | 0.511[note 1] |
| electron neutrino | ν e |
ν e |
1 /2 | 0 | < 0.0000022 | |
| 2 | muon | μ− |
μ+ |
1 /2 | −1 | 105.7[note 2] |
| muon neutrino | ν μ |
ν μ |
1 /2 | 0 | < 0.170 | |
| 3 | tau | τ− |
τ+ |
1 /2 | −1 | 1776.86±0.12 |
| tau neutrino | ν τ |
ν τ |
1 /2 | 0 | < 15.5 |
Bosons are one of the two fundamental particles having integral spinclasses of particles, the other being fermions. Bosons are characterized by Bose–Einstein statistics and all have integer spins. Bosons may be either elementary, like photons and gluons, or composite, like mesons.
According to the Standard Model, the elementary bosons are:
| Name | Symbol | Antiparticle | Spin | Charge (e) | Mass (GeV/c2) [5] | Interaction mediated | Observed |
|---|---|---|---|---|---|---|---|
| photon | γ | self | 1 | 0 | 0 | electromagnetism | Yes |
| W boson | W− |
W+ |
1 | ±1 | 80.385±0.015 | weak interaction | Yes |
| Z boson | Z |
self | 1 | 0 | 91.1875±0.0021 | weak interaction | Yes |
| gluon | g |
self | 1 | 0 | 0 | strong interaction | Yes |
| Higgs boson | H0 |
self | 0 | 0 | 125.09±0.24 | mass | Yes |
The Higgs boson is postulated by the electroweak theory primarily to explain the origin of particle masses. In a process known as the "Higgs mechanism", the Higgs boson and the other gauge bosons in the Standard Model acquire mass via spontaneous symmetry breaking of the SU(2) gauge symmetry. The Minimal Supersymmetric Standard Model (MSSM) predicts several Higgs bosons. On 4 July 2012, the discovery of a new particle with a mass between 125 and 127 GeV/c2 was announced; physicists suspected that it was the Higgs boson. Since then, the particle has been shown to behave, interact, and decay in many of the ways predicted for Higgs particles by the Standard Model, as well as having even parity and zero spin, two fundamental attributes of a Higgs boson. This also means it is the first elementary scalar particle discovered in nature.
Elementary bosons responsible for the four fundamental forces of nature are called force particles (gauge bosons). Strong interaction is mediated by the gluon, weak interaction is mediated by the W and Z bosons.
| Name | Symbol | Antiparticle | Spin | Charge (e) | Mass (GeV/c2) [5] | Interaction mediated | Observed |
|---|---|---|---|---|---|---|---|
| graviton | G | self | 2 | 0 | 0 | gravitation | No |
The graviton is a hypothetical particle that has been included in some extensions to the standard model to mediate the gravitational force. It is in a peculiar category between known and hypothetical particles: As an unobserved particle that is not predicted by, nor required for the Standard Model, it belongs in the table of hypothetical particles, below. But gravitational force itself is a certainty, and expressing that known force in the framework of a quantum field theory requires a boson to mediate it.
If it exists, the graviton is expected to be massless because the gravitational force has a very long range, and appears to propagate at the speed of light. The graviton must be a spin-2 boson because the source of gravitation is the stress–energy tensor, a second-order tensor (compared with electromagnetism's spin-1 photon, the source of which is the four-current, a first-order tensor). Additionally, it can be shown that any massless spin-2 field would give rise to a force indistinguishable from gravitation, because a massless spin-2 field would couple to the stress–energy tensor in the same way that gravitational interactions do. This result suggests that, if a massless spin-2 particle is discovered, it must be the graviton.[8]
Supersymmetric theories predict the existence of more particles, none of which have been confirmed experimentally.
| Superpartner | Spin | Notes | superpartner of: |
|---|---|---|---|
| chargino |
1 /2
|
The charginos are superpositions of the superpartners of charged Standard Model bosons: charged Higgs boson and W boson. The MSSM predicts two pairs of charginos. |
charged bosons |
| gluino |
1 /2
|
Eight gluons and eight gluinos. | gluon |
| gravitino |
3 /2
|
Predicted by supergravity (SUGRA). The graviton is hypothetical, too – see previous table. | graviton |
| Higgsino |
1/ 2
|
For supersymmetry there is a need for several Higgs bosons, neutral and charged, according with their superpartners. | Higgs boson |
| neutralino |
1 /2
|
The neutralinos are superpositions of the superpartners of neutral Standard Model bosons: neutral Higgs boson, Z boson and photon. The lightest neutralino is a leading candidate for dark matter. The MSSM predicts four neutralinos. |
neutral bosons |
| photino |
1 /2
|
Mixing with zino and neutral Higgsinos for neutralinos. | photon |
| sleptons |
0
|
The superpartners of the leptons (electron, muon, tau) and the neutrinos. | leptons |
| sneutrino |
0
|
Introduced by many extensions of the Standard Supermodel, and may be needed to explain the LSND results. A special role has the sterile sneutrino, the supersymmetric counterpart of the hypothetical right-handed neutrino, called the "sterile neutrino". |
neutrino |
| squarks |
0
|
The stop squark (superpartner of the top quark) is thought to have a low mass and is often the subject of experimental searches. | quarks |
| wino, zino |
1 /2
|
The charged wino mixing with the charged Higgsino for charginos, for the zino see line above. | W± and Z0 bosons |
Just as the photon, Z boson and W± bosons are superpositions of the B0, W0, W1, and W2 fields, the photino, zino, and wino± are superpositions of the bino0, wino0, wino1, and wino2. No matter if one uses the original gauginos or this superpositions as a basis, the only predicted physical particles are neutralinos and charginos as a superposition of them together with the Higgsinos.
Other theories predict the existence of additional elementary bosons and fermions, with some theories also postulating additional superpartners for these particles:
| Name | Spin | Notes |
|---|---|---|
| axion |
0
|
A pseudoscalar particle introduced in Peccei–Quinn theory to solve the strong-CP problem. |
| axino |
1 /2
|
Superpartner of the axion. Forms a supermultiplet, together with the saxion and axion, in supersymmetric extensions of Peccei–Quinn theory. |
| branon |
?
|
Predicted in brane world models. |
| digamma |
?
|
Proposed resonance of mass near 750 GeV that decays into two photons. |
| dilaton |
0
|
Predicted in some string theories. |
| dilatino |
1 /2
|
Superpartner of the dilaton. |
| dual graviton |
2
|
Has been hypothesized as dual of graviton under electric–magnetic dualityinsupergravity. |
| graviphoton |
1
|
Also known as "gravivector".[9] |
| graviscalar |
0
|
Also known as "radion". |
| inflaton |
0
|
Unidentified scalar force-carrier that is presumed to have physically caused cosmological “inflation” – the rapid expansion from 10−35 to 10−34 seconds after the Big Bang. |
| magnetic photon |
?
|
Predicted in 1966.[10] |
| majoron |
0
|
Predicted to understand neutrino masses by the seesaw mechanism. |
| majorana fermion | 1 /2; 3 /2 ? ... | gluino, neutralino, or other – is its own antiparticle. |
| saxion |
0
|
|
| X17 particle |
?
|
possible cause of anomalous measurement results near 17 MeV, and possible candidate for dark matter. |
| X and Y bosons |
1
|
These leptoquarks are predicted by GUT theories to be heavier equivalents of the W and Z. |
| W′ and Z′ bosons |
1
|
Composite particles are bound states of elementary particles.
Hadrons are defined as strongly interacting composite particles. Hadrons are either:
Quark models, first proposed in 1964 independently by Murray Gell-Mann and George Zweig (who called quarks "aces"), describe the known hadrons as composed of valence quarks and/or antiquarks, tightly bound by the color force, which is mediated by gluons. (The interaction between quarks and gluons is described by the theory of quantum chromodynamics.) A "sea" of virtual quark-antiquark pairs is also present in each hadron.
Ordinary baryons (composite fermions) contain three valence quarks or three valence antiquarks each.
Ordinary mesons are made up of a valence quark and a valence antiquark. Because mesons have integer spin (0 or 1) and are not themselves elementary particles, they are classified as “composite“ bosons, although being made of elementary fermions. Examples of mesons include the pion, kaon, and the J/ψ. In quantum hadrodynamics, mesons mediate the residual strong force between nucleons.
At one time or another, positive signatures have been reported for all of the following exotic mesons but their existences have yet to be confirmed.
Atomic nuclei typically consist of protons and neutrons, although exotic nuclei may consist of other baryons, such as hypertriton which contains a hyperon. These baryons (protons, neutrons, hyperons, etc.) which comprise the nucleus are called nucleons. Each type of nucleus is called a "nuclide", and each nuclide is defined by the specific number of each type of nucleon.
Atoms are the smallest neutral particles into which matter can be divided by chemical reactions. An atom consists of a small, heavy nucleus surrounded by a relatively large, light cloud of electrons. An atomic nucleus consists of 1 or more protons and 0 or more neutrons. Protons and neutrons are, in turn, made of quarks. Each type of atom corresponds to a specific chemical element. To date, 118 elements have been discovered or created.
Exotic atoms may be composed of particles in addition to or in place of protons, neutrons, and electrons, such as hyperons or muons. Examples include pionium (
π−
π+
) and quarkonium atoms.
Leptonic atoms, named using -onium, are exotic atoms constituted by the bound state of a lepton and an antilepton. Examples of such atoms include positronium (
e−
e+
), muonium (
e−
μ+
), and "true muonium" (
μ−
μ+
). Of these positronium and muonium have been experimentally observed, while "true muonium" remains only theoretical.
Molecules are the smallest particles into which a substance can be divided while maintaining the chemical properties of the substance. Each type of molecule corresponds to a specific chemical substance. A molecule is a composite of two or more atoms. Atoms are combined in a fixed proportion to form a molecule. Molecule is one of the most basic units of matter.
Ions are charged atoms (monatomic ions) or molecules (polyatomic ions). They include cations which have a net positive charge, and anions which have a net negative charge.
Quasiparticles are effective particles that exist in many particle systems. The field equations of condensed matter physics are remarkably similar to those of high energy particle physics. As a result, much of the theory of particle physics applies to condensed matter physics as well; in particular, there are a selection of field excitations, called quasi-particles, that can be created and explored. These include:
The following categories are not unique or distinct: For example, either a WIMP or a WISP is also a FIP.