Free neutron decay
When embedded in an atomic nucleus, neutrons are (usually) stable particles. Outside the nucleus, free neutrons are unstable and have a mean lifetime of 879.6±0.8 s (about 14 min, 39.6 s). Therefore, the half-life for this process (which differs from the mean lifetime by a factor of ln(2) ≈ 0.693) is 611±1 s (about 10 min, 11 s). (An article published in October 2021, arrives at 877.75+0.50−0.44 s for the mean lifetime). The beta decay of the neutron described in this article can be notated at four slightly different levels of detail, as shown in four layers of Feynman diagrams in a . n0 → p+ + e− + νe The hard-to-observe W− quickly decays into an electron and its matching antineutrino. The subatomic reaction shown immediately above depicts the process as it was first understood, in the first half of the 20th century. The boson ( W− ) vanished so quickly that it was not detected until much later.Later, beta decay was understood to occur by the emission of a weak boson ( W± ), sometimes called a charged weak current. Beta decay specifically involves the emission of a W− boson from one of the down quarks hidden within the neutron, thereby converting the down quark into an up quark and consequently the neutron into a proton. The following diagram gives a summary sketch of the beta decay process according to the present level of understanding. The down quark shown in bold (d) is nominally the one emitting the boson ( W− ) and thereby changing into an up quark (u), also in bold. The ud quark pair not shown in bold are inert bystanders to the whole event. For diagrams at several levels of detail, see , below. (Wikipedia).
