Baryon

In particle physics, a baryon is a type of composite subatomic particle that contains an odd number of valence quarks, conventionally three. Protons and neutrons are examples of baryons; because baryons are composed of quarks, they belong to the hadron family of particles. Baryons are also classified as fermions because they have half-integer spin.
The name "baryon", introduced by Abraham Pais, comes from the Greek word for "heavy", because, at the time of their naming, most known elementary particles had lower masses than the baryons. Each baryon has a corresponding antiparticle where their corresponding antiquarks replace quarks. For example, a proton is made of two up quarks and one down quark; and its corresponding antiparticle, the antiproton, is made of two up antiquarks and one down antiquark.
Baryons participate in the residual strong force, which is mediated by particles known as mesons. The most familiar baryons are protons and neutrons, both of which contain three quarks, and for this reason they are sometimes called triquarks. These particles make up most of the mass of the visible matter in the universe and compose the nucleus of every atom. Exotic baryons containing five quarks, called pentaquarks, have also been discovered and studied.
A census of the Universe's baryons indicates that 10% of them could be found inside galaxies, 50% to 60% in the circumgalactic medium, and the remaining 30% to 40% could be located in the warm–hot intergalactic medium.

Background

Baryons are strongly interacting fermions; that is, they are acted on by the strong nuclear force and are described by Fermi–Dirac statistics, which apply to all particles obeying the Pauli exclusion principle. This is in contrast to the bosons, which do not obey the exclusion principle.
Baryons, alongside mesons, are hadrons, composite particles composed of quarks. Quarks have baryon numbers of B = and antiquarks have baryon numbers of. The term "baryon" usually refers to triquarks—baryons made of three quarks.
Other exotic baryons have been proposed, such as pentaquarks—baryons made of four quarks and one antiquark, but their existence is not generally accepted. The particle physics community as a whole did not view their existence as likely in 2006, and in 2008, considered evidence to be overwhelmingly against the existence of the reported pentaquarks. However, in July 2015, the LHCb experiment observed two resonances consistent with pentaquark states in the decay, with a combined statistical significance of 15σ.
In theory, heptaquarks, nonaquarks, etc. could also exist.

Baryonic matter

Nearly all matter that may be encountered or experienced in everyday life is baryonic matter, which includes atoms of any sort, and provides them with the property of mass. Non-baryonic matter, as implied by the name, is any sort of matter that is not composed primarily of baryons. This might include neutrinos and free electrons, dark matter, supersymmetric particles, axions, and black holes.
The very existence of baryons is also a significant issue in cosmology because it is assumed that the Big Bang produced a state with equal amounts of baryons and antibaryons. The process by which baryons came to outnumber their antiparticles is called baryogenesis.

Baryogenesis

Experiments are consistent with the number of quarks in the universe being conserved alongside the total baryon number, with antibaryons being counted as negative quantities. Within the prevailing Standard Model of particle physics, the number of baryons may change in multiples of three due to the action of sphalerons, although this is rare and has not been observed under experiment. Some Grand Unified Theories of particle physics also predict that a single proton can decay, changing the baryon number by one; however, this has not yet been observed under experiment. The excess of baryons over antibaryons in the present universe is thought to be due to non-conservation of baryon number in the very early universe, though this is not well understood.

Properties

Isospin and charge

The concept of isospin was first proposed by Werner Heisenberg in 1932 to explain the similarities between protons and neutrons under the strong interaction. Although they had different electric charges, their masses were so similar that physicists believed they were the same particle. The different electric charges were explained as being the result of some unknown excitation similar to spin. This unknown excitation was later dubbed isospin by Eugene Wigner in 1937.
This belief lasted until Murray Gell-Mann proposed the quark model in 1964. The success of the isospin model is now understood to be the result of the similar masses of u and d quarks. Since u and d quarks have similar masses, particles made of the same number then also have similar masses. The exact specific u and d quark composition determines the charge, as u quarks carry charge + while d quarks carry charge −. For example, the four Deltas all have different charges, , , ), but have similar masses as they are each made of a combination of three u or d quarks. Under the isospin model, they were considered to be a single particle in different charged states.
The mathematics of isospin was modeled after that of spin. Isospin projections varied in increments of 1 just like those of spin, and to each projection was associated a "charged state". Since the "Delta particle" had four "charged states", it was said to be of isospin I = . Its "charged states",,, and, corresponded to the isospin projections I₃ = +, I₃ = +, I₃ = −, and I₃ = −, respectively. Another example is the "nucleon particle". As there were two nucleon "charged states", it was said to be of isospin. The positive nucleon was identified with I₃ = + and the neutral nucleon with I₃ = −. It was later noted that the isospin projections were related to the up and down quark content of particles by the relation:
where the n is the number of up and down quarks and antiquarks.
In the "isospin picture", the four Deltas and the two nucleons were thought to be the different states of two particles. However, in the quark model, Deltas are different states of nucleons. Isospin, although conveying an inaccurate picture of things, is still used to classify baryons, leading to unnatural and often confusing nomenclature.

Flavour quantum numbers

The strangeness flavour quantum number S was noticed to go up and down along with particle mass. The higher the mass, the lower the strangeness. Particles could be described with isospin projections and strangeness . As other quarks were discovered, new quantum numbers were made to have similar description of udc and udb octets and decuplets. Since only the u and d mass are similar, this description of particle mass and charge in terms of isospin and flavour quantum numbers works well only for octet and decuplet made of one u, one d, and one other quark, and breaks down for the other octets and decuplets. If the quarks all had the same mass, their behaviour would be called symmetric, as they would all behave in the same way to the strong interaction. Since quarks do not have the same mass, they do not interact in the same way, and the symmetry is said to be broken.
It was noted that charge was related to the isospin projection, the baryon number and flavour quantum numbers by the Gell-Mann–Nishijima formula:
where S, C, B′, and T represent the strangeness, charm, bottomness and topness flavour quantum numbers, respectively. They are related to the number of strange, charm, bottom, and top quarks and antiquark according to the relations:
meaning that the Gell-Mann–Nishijima formula is equivalent to the expression of charge in terms of quark content:

Spin, orbital angular momentum, and total angular momentum

is a vector quantity that represents the "intrinsic" angular momentum of a particle. It comes in increments of . The ħ is often dropped because it is the "fundamental" unit of spin, and it is implied that "spin 1" means. In some systems of natural units, ħ is chosen to be 1, and therefore does not appear anywhere.
Quarks are fermionic particles of spin . Because spin projections vary in increments of 1, a single quark has a spin vector of, and has two spin projections. Two quarks can have their spins aligned, in which case the two spin vectors add to make a vector of length and three spin projections. If two quarks have unaligned spins, the spin vectors add up to make a vector of length and has only one spin projection, etc. Since baryons are made of three quarks, their spin vectors can add to make a vector of length, which has four spin projections, or a vector of length with two spin projections.
There is another quantity of angular momentum, called the orbital angular momentum, that comes in increments of, which represent the angular moment due to quarks orbiting around each other. The total angular momentum of a particle is therefore the combination of intrinsic angular momentum and orbital angular momentum. It can take any value from to, in increments of 1.

Spin, S	Orbital angular momentum, L	Total angular momentum, J	Parity, P	Condensed notation, J^P
	0		+	⁺
	1	,	−	⁻, ⁻
	2	,	+	⁺, ⁺
	3	,	−	⁻, ⁻
	0		+	⁺
	1	,,	−	⁻, ⁻, ⁻
	2	,,,	+	⁺, ⁺, ⁺, ⁺
	3	,,,	−	⁻, ⁻, ⁻, ⁻

Particle physicists are most interested in baryons with no orbital angular momentum, as they correspond to ground states—states of minimal energy. Therefore, the two groups of baryons most studied are the S = ; L = 0 and S = ; L = 0, which corresponds to J = ⁺ and J = ⁺, respectively, although they are not the only ones. It is also possible to obtain J = ⁺ particles from S = and L = 2, as well as S = and L = 2. This phenomenon of having multiple particles in the same total angular momentum configuration is called degeneracy. How to distinguish between these degenerate baryons is an active area of research in baryon spectroscopy.