Everything about Free Neutron totally explained
A
free neutron is a
neutron that exists outside of an
atomic nucleus. While neutrons can be stable when bound inside nuclei, free neutrons are unstable and
decay with a
lifetime of just under 15 minutes (885.7 ± 0.8 s). Because the neutron consists of three
quarks, the only possible decay mode without a change of
baryon number requires the
flavour changing of one of the quarks via the
weak nuclear force. The neutron consists of two
down quarks with charge -1/3 and one
up quark with charge +2/3, and the decay of one of the down quarks into a lighter up quark can be achieved by the emission of a
W boson. By this means the neutron decays into a
proton (which contains one down and two up quarks), an
electron, and an
electron antineutrino (
antineutrino), with the proton and electron potentially forming a
hydrogen atom:
Even though it isn't a
chemical element, the free neutron is often included in tables of nuclides. It is then considered to have an
atomic number of zero and a
mass number of one.
Production
Various
nuclides become more stable by expelling neutrons as a
decay mode; this is known as
neutron emission, and happens commonly during
spontaneous fission.
Cosmic radiation interacting the earth's atmosphere continuously generates neutrons that can be detected at the surface.
Nuclear fission reactors naturally produce free neutrons; their role is to sustain the energy-producing
chain reaction. The intense
neutron radiation can also be used to produce various radioisotopes through the process of
neutron activation, which is a type of
neutron capture.
Experimental
nuclear fusion reactors produce free neutrons as a waste product. However, it's these neutrons that possess most of the energy, and converting that energy to a useful form has proved a difficult engineering challenge to nuclear physicists. This also explains why this form of energy is likely to create around twice the amount of radioactive waste of a fission reactor, but with a short (50-100 years) decay period (as opposed to the 10,000 years for fission waste).
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Thermal neutron
A
thermal neutron is a
free neutron that's
Boltzmann distributed with kT = 0.024 eV (4.0×10
-21 J) at room temperature. This gives characteristic (not average, or median) speed of 2.2 km/s. The name 'thermal' comes from their energy being that of the room temperature gas or material they're permeating. (see
kinetic theory for energies and speeds of molecules). After a number of collisions (often in the range of 10–20) with nuclei,
neutrons arrive at this energy level, provided that they're not absorbed.
In many substances, thermal neutrons have a much larger effective cross-section than faster neutrons, and can therefore be absorbed more easily by any
atomic nuclei that they collide with, creating a heavier — and often
unstable —
isotope of the
chemical element as a result.
Most
fission reactors use a
neutron moderator to slow down, or
thermalize the neutrons that are emitted by
nuclear fission so that they're more easily captured, causing further fission. Others, called
fast breeder reactors, use fission energy neutrons directly.
Cold neutrons
These neutrons are thermal neutrons that have been equilibrated in a very cold substances such as liquid
deuterium. These are produced in
neutron scattering research facilities.
Ultracold neutrons
Ultracold neutrons are produced by equilibration in substances with a temperature of a few kelvins, such as solid
deuterium or superfluid
helium. An alternative production method is the mechanical deceleration of cold neutrons.
Fission energy neutron
A
fast neutron is a free neutron with a kinetic energy level close to 2
MeV (20
TJ/
kg), hence a speed of 28,000
km/
s. They are named
fission energy or
fast neutrons to distinguish them from lower-energy thermal neutrons, and high-energy neutrons produced in cosmic showers or accelerators. Fast neutrons are produced by nuclear processes such as
nuclear fission.
Fast neutrons can be made into thermal neutrons via a process called moderation. This is done with a
neutron moderator. In reactors, typically
heavy water,
light water, or
graphite are used to moderate neutrons.
Fusion neutrons can have higher energies such as 14.1 MeV for D-T fusion, or 2.45 MeV for D-D fusion to
3He. See
Nuclear fusion#Criteria and candidates for terrestrial reactions for a list.
Intermediate neutrons
A fission energy neutron that's slowing down is often said to have intermediate energy. There are not many non-elastic reactions in this energy region, so most of what happens is just slowing to thermal speeds before eventual capture. Intermediate energy neutrons are a hazard in reactors owing to the existence of a
resonance region in the
fission cross section of
fissile elements. Within this region there exist many local minima and local maxima of probability of causing fission; this means that a reactor operating with a significant population of intermediate neutrons in contact with fuel nuclei could exhibit dangerous
transient response. In such reactors, other mechanisms of inherent stability must be provided, such as large
hydrogen populations to provide
Doppler broadening.
High-energy neutrons
These neutrons have more energy than fission energy neutrons and generated in accelerators or in the atmosphere from cosmic particles. They can have energies as high as tens of joules per neutron.
Further Information
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