Neutron activation is the process in which neutron radiation induces radioactivity in materials, and occurs when atomic nuclei capture free neutrons, becoming heavier and entering excited states. The excited nucleus decays immediately by emitting gamma rays, or particles such as beta particles, alpha particles, fission products, and neutrons (in nuclear fission). Thus, the process of neutron capture, even after any intermediate decay, often results in the formation of an unstable activation product. Such radioactive nuclei can exhibit half-lives ranging from small fractions of a second to many years.

Neutron activation is the only common way that a stable material can be made radioactive. All naturally occurring materials, including air, water, and soil, can be induced (activated) by neutron capture into some amount of radioactivity in varying degrees, as a result of the production of neutron-rich radioisotopes.^{[citation needed]} Some atoms require more than one neutron to become unstable, which makes them harder to activate because a double or triple capture by a nucleus is less likely than a single capture. Water, for example, is made up of hydrogen and oxygen. Hydrogen (most common isotope, ¹H) requires two captures to attain instability as tritium (hydrogen-3), while oxygen (most common isotope, ¹⁶O) requires three captures to become unstable oxygen-19. Thus, water is difficult to activate, unlike sodium chloride (NaCl), in which both sodium and chlorine become unstable with one capture each (see Isotopes of sodium; Isotopes of chlorine). These facts were experienced at the Operation Crossroads atomic test series in 1946.

This kind of nuclear reaction occurs in the production of cobalt-60 (⁶⁰Co) in a nuclear reactor. ⁶⁰Co (half-life about 5.27 years) then decays into nickel-60, emitting a beta particle plus gamma rays. Due to the availability of cobalt-59 (natural abundance 100%), this neutron bombarded isotope of cobalt is a valuable source of nuclear radiation (namely gamma radiation) for radiotherapy.

In other cases, and depending on the kinetic energy of the neutron, the capture of a neutron can cause nuclear fission—the splitting of the atomic nucleus into two smaller nuclei. If the fission requires an input of energy, that comes from the kinetic energy of the neutron. An example of this kind of fission in a light element can occur when the stable isotope of lithium, lithium-7, is bombarded with fast neutrons and undergoes the following nuclear reaction:

In other words, the capture of a neutron by lithium-7 causes it to split into an energetic helium nucleus (alpha particle), a hydrogen-3 (tritium) nucleus and a free neutron. The Castle Bravo accident, in which the thermonuclear bomb test at Bikini Atoll in 1954 exploded with 2.5 times the expected yield, was caused by the unexpectedly high probability of this reaction.

In the area around a pressurized water reactor or boiling water reactor during normal operation, a significant amount of radiation is produced due to the fast neutron activation of coolant water oxygen via a (n,p) reaction. The activated oxygen-16 nucleus emits a proton (hydrogen nucleus), and transmutes to nitrogen-16, which has a very short life (7.13 seconds) before decaying back to oxygen-16 (emitting 10.4 MeV beta particles and 6.13 MeV gamma radiations).

This activation of the coolant water requires extra biological shielding around the nuclear reactor plant. It is the high energy gamma ray in the second reaction that causes the major concern. This is why water that has recently been inside a nuclear reactor core must be shielded until this radiation subsides. One to two minutes is generally sufficient.

In facilities that housed a cyclotron, the reinforced concrete foundation can become radioactive due to neutron activation. Six important long-lived radioisotopes (⁵⁴Mn, ⁵⁵Fe, ⁶⁰Co, ⁶⁵Zn, ¹³³Ba, and ¹⁵²Eu) can be found in concrete affected by neutrons. The residual radioactivity is predominantly due to trace elements present, and thus the amount of radioactivity derived from cyclotron activation is minuscule, i.e., pCi/g or Bq/g. The release limit for facilities with residual radioactivity is 25 mrem/year. An example of ⁵⁵Fe production from the activation of iron in reinforcement bars found in concrete is shown below: