Neutron moderator

In nuclear engineering, a neutron moderator is a medium that reduces the speed of fast neutrons, ideally without capturing any, leaving them as thermal neutrons with only minimal (thermal) kinetic energy. These thermal neutrons are immensely more susceptible than fast neutrons to propagate a nuclear chain reaction of uranium-235 or other fissile isotope by colliding with their atomic nucleus. Water (sometimes called "light water" in this context) is the most commonly used moderator (roughly 75% of the world's reactors). Solid graphite (20% of reactors) and heavy water (5% of reactors) are the main alternatives. Beryllium has also been used in some experimental types, and hydrocarbons have been suggested as another possibility. Neutrons are normally bound into an atomic nucleus, and do not exist free for long in nature. The unbound neutron has a half-life of 10 minutes and 11 seconds. The release of neutrons from the nucleus requires exceeding the binding energy of the neutron, which is typically 7-9 MeV for most isotopes. Neutron sources generate free neutrons by a variety of nuclear reactions, including nuclear fission and nuclear fusion. Whatever the source of neutrons, they are released with energies of several MeV. According to the equipartition theorem, the average kinetic energy, , can be related to temperature, , via: where is the neutron mass, is the average squared neutron speed, and is the Boltzmann constant. The characteristic neutron temperature of several-MeV neutrons is several tens of billions kelvin. Moderation is the process of the reduction of the initial high speed (high kinetic energy) of the free neutron. Since energy is conserved, this reduction of the neutron speed takes place by transfer of energy to a material called a moderator. The probability of scattering of a neutron from a nucleus is given by the scattering cross section. The first few collisions with the moderator may be of sufficiently high energy to excite the nucleus of the moderator.

Innovative dud detection based on JET DT experience

High brightness neutron source optimized for very high pulsed magnetic field experiments

Demonstration of a sparse sensor placement technique to the limited diagnostic set in a fusion power plant

Innovative dud detection based on JET DT experience

High brightness neutron source optimized for very high pulsed magnetic field experiments

Demonstration of a sparse sensor placement technique to the limited diagnostic set in a fusion power plant