In particle physics, the baryons are a family of subatomic particles including the proton and the neutron (collectively called nucleons), as well as a number of unstable, heavier particles (called hyperons). The term "baryon" is derived from the Greek barys, meaning "heavy," as they are heavier than the other main groups of particles.
Baryons are strongly interacting fermions — that is, they experience 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, along with mesons, belong to the family of particles known as hadrons, meaning they are composed of quarks. Baryons are fermions composed of three quarks, while mesons are bosons composed of a quark and an antiquark.
In addition to the nucleons (protons and neutrons), other members of the baryon family include the Δ, Λ, Σ, Ξ and Ω particles.
Delta baryons (Δ++, Δ+, Δ0, Δ−) are composed of a combination of up and down quarks, and decay into a pion and either a proton or neutron.
Lambda baryons (Λ0, Λ+c) are composed of one up, one down, and either a charm or a strange quark. The neutral lambda provided the first observational evidence of the strange quark.
Sigma baryons (Σ+, Σ0, Σ−), are composed of one strange quark and a combination of up and down quarks. The neutral sigma has the same quark composition as the neutral lambda (up, down, strange), and so decays much faster than either Σ+ (up, up, strange) or Σ− (down, down, strange).
Xi baryons, (Ξ0, Ξ−), are composed of two strange quarks and either an up or down quark. The neutral xi, Ξ0, composed of an up and two strange quarks, decays into a neutral lambda and a neutral pion, which itself rapidly decays into an electron and a positron; these immediately annihilate, and so it appears that the xi's product is a lambda that is emitting gamma rays.
The omega minus baryon (Ω−) is composed of three strange quarks. Its discovery was a great triumph in the study of quark processes, since it was found only after its existence, mass, and decay products had already been predicted.
Baryonic matter
Baryonic matter is matter composed mostly of baryons (by mass), and is what is familiar to us, in everyday life. Non-baryonic matter, essentially different in kind, is a subject of speculation in cosmology, in attempts to balance the books for observations of the universe's matter, taken as a whole. See dark matter.
A table of baryons
Baryons
| Particle |
Symbol |
Makeup |
Rest mass
MeV/c2
|
B
|
S
|
C
|
Mean lifetime
s
|
|
Proton
|
p |
uud |
938.3 |
+1 |
0 |
0 |
Stable1 |
|
Neutron
|
n |
ddu |
939.6 |
+1 |
0 |
0 |
9202 |
|
Delta
|
Δ++ |
uuu |
1232 |
+1 |
0 |
0 |
6×10-24 |
|
Delta
|
Δ+ |
uud |
1232 |
+1 |
0 |
0 |
6×10-24 |
|
Delta
|
Δ0 |
udd |
1232 |
+1 |
0 |
0 |
6×10-24 |
|
Delta
|
Δ- |
ddd |
1232 |
+1 |
0 |
0 |
6×10-24 |
|
Lambda
|
Λ0 |
uds |
1115.7 |
+1 |
-1 |
0 |
2.60×10-10 |
|
Lambda
|
Λ+c |
udc |
2285 |
+1 |
0 |
1 |
2.0×10-13 |
|
Sigma
|
Σ+ |
uus |
1189.4 |
+1 |
-1 |
0 |
0.8×10-10 |
|
Sigma
|
Σ0 |
uds |
1192.5 |
+1 |
-1 |
0 |
6×10-20 |
|
Sigma
|
Σ- |
dds |
1197.4 |
+1 |
-1 |
0 |
1.5×10-10 |
|
Xi
|
Ξ0 |
uss |
1315 |
+1 |
-2 |
0 |
2.9×10-10 |
|
Xi
|
Ξ- |
dss |
1321 |
+1 |
-2 |
0 |
1.6×10-10 |
|
Omega
|
Ω- |
sss |
1672 |
+1 |
-3 |
0 |
0.82×10-10 |
1at least 1035 years. See Proton decay.
2for free neutrons; in most common nuclei, neutrons are stable.
See also
