In physics, the **eightfold way** is an organizational scheme for a class of subatomic particles known as hadrons that led to the development of the quark model. Working alone, both the American physicist Murray Gell-Mann and the Israeli physicist Yuval Ne'eman proposed the idea in 1961.^{[1]}^{[2]}^{[a]}
The name comes from Gell-Mann's (1961) paper and is an allusion to the Noble Eightfold Path of Buddhism.^{[3]}

By 1947, physicists believed that they had a good understanding of what the smallest bits of matter were. There were electrons, protons, neutrons, and photons (the components that make up the vast part of everyday experience such as atoms and light) along with a handful of unstable (i.e., they undergo radioactive decay) exotic particles needed to explain cosmic rays observations such as pions, muons and hypothesized neutrino. In addition, the discovery of the positron suggested there could be anti-particles for each of them. It was known a "strong interaction" must exist to overcome electrostatic repulsion in atomic nuclei. Not all particles are influenced by this strong force but those that are, are dubbed "hadrons", which are now further classified as mesons (middle mass) and baryons (heavy weight).

But the discovery of the (neutral) kaon in late 1947 and the subsequent discovery of a positively charged kaon in 1949 extended the meson family in an unexpected way and in 1950 the lambda particle did the same thing for the baryon family. These particles decay much more slowly than they are produced, a hint that there are two different physical processes involved. This was first suggested by Abraham Pais in 1952. In 1953, M. Gell Mann and a collaboration in Japan, Tadao Nakano with Kazuhiko Nishijima, independently suggested a new conserved value now known as "strangeness" during their attempts to understand the growing collection of known particles.^{[4]}^{[5]}^{[b]}
The trend of discovering new mesons and baryons would continue through the 1950s as the number of known "elementary" particles ballooned. Physicists were interested in understanding hadron-hadron interactions via the strong interaction. The concept of isospin, introduced in 1932 by Werner Heisenberg shortly after the discovery of the neutron, was used to group some hadrons together into "multiplets" but no successful scientific theory as yet covered the hadrons as a whole. This was the beginning of a chaotic period in particle physics that has become known as the "particle zoo" era. The eightfold way represented a step out of this confusion and towards the quark model, which proved to be the solution.

Group representation theory is the mathematical underpinning behind the eightfold way but this rather technical mathematics is not needed to understand how it helps organize particles. Particles are sorted into groups as mesons or baryons. Within each group, they are further separated by their spin angular momentum. Symmetrical patterns appear when these groups of particles have their strangeness plotted against their electric charge. (This is the most common way to make these plots today but originally physicists used an equivalent pair of properties called *hypercharge* and *isotopic spin*, the latter of which is now known as *isospin*.) The symmetry in these patterns is a hint of the underlying symmetry of the strong interaction between the particles themselves. In the plots below, points representing particles that lie along the same horizontal line share the same strangeness, s, while those on the same left-leaning diagonals share the same electric charge, q (given as multiples of the elementary charge).

In the original eightfold way, the mesons were organized into octets and singlets. This is one of the finer points of differences between the eightfold way and the quark model it inspired, which suggests the mesons should be grouped into nonets (groups of nine).

The eightfold way organizes eight of the lowest spin-0 mesons into an octet.^{[1]}^{[6]} They are:

^{}_{}K^{0}_{},^{}_{}K^{+}_{},^{}_{}K^{−}_{}and^{}_{}K^{0}_{}kaons^{}_{}π^{+}_{},^{}_{}π^{0}_{}, and^{}_{}π^{−}_{}pions^{}_{}η^{}_{}

Diametrically opposite particles in the diagram are anti-particles of one-another while particles in the center are their own anti-particle.

The chargeless, strangeless eta prime meson was originally classified by itself as a singlet:

Under the quark model later developed, it is better viewed as part of a meson nonet, as previously mentioned.

The eightfold way organizes the spin-1/ 2 baryons into an octet. They consist of

- neutron (n) and proton (p)
^{}_{}Σ^{−}_{},^{}_{}Σ^{0}_{}, and^{}_{}Σ^{+}_{}sigma baryons^{}_{}Λ^{0}_{}, the strange lambda baryon^{}_{}Ξ^{−}_{}and^{}_{}Ξ^{0}_{}xi baryons

The organizational principles of the eightfold way also apply to the spin-3/ 2 baryons, forming a decuplet.

^{}_{}Δ^{−}_{},^{}_{}Δ^{0}_{},^{}_{}Δ^{+}_{}, and^{}_{}Δ^{++}_{}delta baryons^{}_{}Σ^{∗−}_{},^{}_{}Σ^{∗0}_{}, and^{}_{}Σ^{∗+}_{}sigma baryons^{}_{}Ξ^{∗−}_{}and^{}_{}Ξ^{∗0}_{}xi baryons^{}_{}Ω^{−}_{}omega baryon

However, one of the particles of this decuplet had never been previously observed when the eightfold way was proposed. Gell-Mann called this particle the ^{}_{}Ω^{−}_{} and predicted in 1962 that it would have a strangeness −3, electric charge −1 and a mass near 1680 MeV/*c*^{2}. In 1964, a particle closely matching these predictions was discovered^{[7]} by a particle accelerator group at Brookhaven. Gell-Mann received the 1969 Nobel Prize in Physics for his work on the theory of elementary particles.

Historically, quarks were motivated by an understanding of flavour symmetry. First, it was noticed (1961) that groups of particles were related to each other in a way that matched the representation theory of SU(3). From that, it was inferred that there is an approximate symmetry of the universe which is parametrized by the group SU(3). Finally (1964), this led to the discovery of three light quarks (up, down, and strange) interchanged by these SU(3) transformations.

The eightfold way may be understood in modern terms as a consequence of flavor symmetries between various kinds of quarks. Since the strong nuclear force affects quarks the same way regardless of their flavor, replacing one flavor of quark with another in a hadron should not alter its mass very much, provided the respective quark masses are smaller than the strong interaction scale—which holds for the three light quarks. Mathematically, this replacement may be described by elements of the SU(3) group. The octets and other hadron arrangements are representations of this group.

Main article: Flavour (particle physics) |

There is an abstract three-dimensional vector space:

and the laws of physics are *approximately* invariant under applying a determinant-1 unitary transformation to this space (sometimes called a *flavour rotation*):

Here, SU(3) refers to the Lie group of **3×3 unitary matrices with determinant 1** (special unitary group). For example, the flavour rotation

is a transformation that simultaneously turns all the up quarks in the universe into down quarks and vice versa. More specifically, these flavour rotations are exact symmetries if *only* strong force interactions are looked at, but they are not truly exact symmetries of the universe because the three quarks have different masses and different electroweak interactions.

This approximate symmetry is called *flavour symmetry*, or more specifically *flavour SU(3) symmetry*.

See also: Clebsch–Gordan coefficients for SU(3) § Representations of the SU(3) group |

Main article: Particle physics and representation theory |

See also: Compact group § Representation theory of a connected compact Lie group |

Assume we have a certain particle—for example, a proton—in a quantum state . If we apply one of the flavour rotations *A* to our particle, it enters a new quantum state which we can call . Depending on *A*, this new state might be a proton, or a neutron, or a superposition of a proton and a neutron, or various other possibilities. The set of all possible quantum states spans a vector space.

Representation theory is a mathematical theory that describes the situation where elements of a group (here, the flavour rotations *A* in the group SU(3)) are automorphisms of a vector space (here, the set of all possible quantum states that you get from flavour-rotating a proton). Therefore, by studying the representation theory of SU(3), we can learn the possibilities for what the vector space is and how it is affected by flavour symmetry.

Since the flavour rotations *A* are approximate, not exact, symmetries, each orthogonal state in the vector space corresponds to a different particle species. In the example above, when a proton is transformed by every possible flavour rotation *A*, it turns out that it moves around an 8 dimensional vector space. Those 8 dimensions correspond to the 8 particles in the so-called "baryon octet" (proton, neutron, ^{}_{}Σ^{+}_{}, ^{}_{}Σ^{0}_{}, ^{}_{}Σ^{−}_{}, ^{}_{}Ξ^{−}_{}, ^{}_{}Ξ^{0}_{}, ^{}_{}Λ^{}_{}). This corresponds to an 8-dimensional ("octet") representation of the group SU(3). Since *A* is an approximate symmetry, all the particles in this octet have similar mass.^{[8]}

Every Lie group has a corresponding Lie algebra, and each group representation of the Lie group can be mapped to a corresponding Lie algebra representation on the same vector space. The Lie algebra (3) can be written as the set of 3×3 traceless Hermitian matrices. Physicists generally discuss the representation theory of the Lie algebra (3) instead of the Lie group SU(3), since the former is simpler and the two are ultimately equivalent.