nuclear engineering, a neutron moderator is a medium that reduces the speed of fast neutrons, thereby turning them into thermal neutrons capable of sustaining a nuclear chain reaction involving uranium-235 or a similar fissile nuclide.
In
Commonly used moderators include regular (light) water (roughly 75% of the world's reactors), solid graphite (20% of reactors) and heavy water (5% of reactors).
Beryllium has also been used in some experimental types, and hydrocarbons have been suggested as another possibility.
Moderation
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 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 couple of collisions with the moderator may be of
sufficiently high energy to excite the nucleus of the moderator. Such a
collision is inelastic, since some of the kinetic energy is transformed to potential energy by exciting some of the internal degrees of freedom of the nucleus to form an excited state. As the energy of the neutron is lowered, the collisions become predominantly elastic, i.e., the total kinetic energy and momentum of the system (that of the neutron and the nucleus) is conserved.
Given the mathematics of elastic collisions,
as neutrons are very light compared to most nuclei, the most efficient
way of removing kinetic energy from the neutron is by choosing a
moderating nucleus that has near identical mass.
A collision of a neutron, which has mass of 1, with a 1H nucleus (a proton)
could result in the neutron losing virtually all of its energy in a
single head-on collision. More generally, it is necessary to take into
account both glancing and head-on collisions. The mean logarithmic reduction of neutron energy per collision, , depends only on the atomic mass, , of the nucleus and is given by:
.
This can be reasonably approximated to the very simple form . From this one can deduce ,
the expected number of collisions of the neutron with nuclei of a given
type that is required to reduce the kinetic energy of a neutron from to
- .
Choice of moderator materials
Some nuclei have larger absorption cross sections than others, which removes free neutrons from the flux. Therefore, a further criterion for an efficient moderator is one for which this parameter is small. The moderating efficiency gives the ratio of the macroscopic cross sections of scattering, , weighted by divided by that of absorption, : i.e., .
For a compound moderator composed of more than one element, such as
light or heavy water, it is necessary to take into account the
moderating and absorbing effect of both the hydrogen isotope and oxygen
atom to calculate . To bring a neutron from the fission energy of 2 MeV to an of 1 eV takes an expected of 16 and 29 collisions for H2O and D2O, respectively. Therefore, neutrons are more rapidly moderated by light water, as H has a far higher . However, it also has a far higher , so that the moderating efficiency is nearly 80 times higher for heavy water than for light water.
The ideal moderator is of low mass, high scattering cross section, and low absorption cross section.
Hydrogen | Deuterium | Beryllium | Carbon | Oxygen | Uranium | |
---|---|---|---|---|---|---|
Mass of kernels | 1 | 2 | 9 | 12 | 16 | 238 |
Energy decrement | 1 | 0.7261 | 0.2078 | 0.1589 | 0.1209 | 0.0084 |
Number of Collisions | 18 | 25 | 86 | 114 | 150 | 2172 |
Distribution of neutron velocities once moderated
After
sufficient impacts, the speed of the neutron will be comparable to the
speed of the nuclei given by thermal motion; this neutron is then called
a thermal neutron, and the process may also be termed thermalization.
Once at equilibrium at a given temperature the distribution of speeds
(energies) expected of rigid spheres scattering elastically is given by
the Maxwell–Boltzmann distribution.
This is only slightly modified in a real moderator due to the speed
(energy) dependence of the absorption cross-section of most materials,
so that low-speed neutrons are preferentially absorbed, so that the true neutron velocity distribution in the core would be slightly hotter than predicted.
Reactor moderators
In a thermal-neutron reactor, the nucleus of a heavy fuel element such as uranium absorbs a slow-moving free neutron, becomes unstable, and then splits ("fissions") into two smaller atoms ("fission products"). The fission process for 235U nuclei yields two fission products, two to three fast-moving free neutrons, plus an amount of energy
primarily manifested in the kinetic energy of the recoiling fission
products. The free neutrons are emitted with a kinetic energy of ~2 MeV
each. Because more free neutrons
are released from a uranium fission event than thermal neutrons are
required to initiate the event, the reaction can become self-sustaining —
a chain reaction — under controlled conditions, thus liberating a tremendous amount of energy.
The probability of further fission events is determined by the fission cross section,
which is dependent upon the speed (energy) of the incident neutrons.
For thermal reactors, high-energy neutrons in the MeV-range are much
less likely to cause further fission. (Note: It is not impossible for fast neutrons to cause fission, just much less likely.) The newly released fast neutrons, moving at roughly 10% of the speed of light,
must be slowed down or "moderated," typically to speeds of a few
kilometres per second, if they are to be likely to cause further fission
in neighbouring 235U
nuclei and hence continue the chain reaction. This speed happens to be
equivalent to temperatures in the few hundred Celsius range.
In all moderated reactors, some neutrons of all energy levels
will produce fission, including fast neutrons. Some reactors are more
fully thermalised than others; for example, in a CANDU reactor nearly all fission reactions are produced by thermal neutrons, while in a pressurized water reactor (PWR) a considerable portion of the fissions are produced by higher-energy neutrons. In the proposed water-cooled supercritical water reactor (SCWR), the proportion of fast fissions may exceed 50%, making it technically a fast neutron reactor.
A fast reactor
uses no moderator, but relies on fission produced by unmoderated fast
neutrons to sustain the chain reaction. In some fast reactor designs, up
to 20% of fissions can come from direct fast neutron fission of uranium-238, an isotope which is not fissile at all with thermal neutrons.
Moderators are also used in non-reactor neutron sources, such as plutonium-beryllium and spallation sources.
Form and location
The
form and location of the moderator can greatly influence the cost and
safety of a reactor. Classically, moderators were precision-machined
blocks of high purity graphite with embedded ducting to carry away heat. They were in the hottest part of the reactor, and therefore subject to corrosion and ablation. In some materials, including graphite, the impact of the neutrons with the moderator can cause the moderator to accumulate dangerous amounts of Wigner energy. This problem led to the infamous Windscale fire at the Windscale Piles, a nuclear reactor complex in the United Kingdom, in 1957.
Some pebble-bed reactors' moderators are not only simple, but also inexpensive: the nuclear fuel is embedded in spheres of reactor-grade pyrolytic carbon, roughly of the size of tennis balls.
The spaces between the balls serve as ducting. The reactor is
operated above the Wigner annealing temperature so that the graphite
does not accumulate dangerous amounts of Wigner energy.
In CANDU and PWR reactors, the moderator is liquid water (heavy water for CANDU, light water for PWR). In the event of a loss-of-coolant accident in a PWR, the moderator is also lost and the reaction will stop. This negative void coefficient
is an important safety feature of these reactors. In CANDU the
moderator is located in a separate heavy-water circuit, surrounding the
pressurized heavy-water coolant channels. This design gives CANDU
reactors a positive void coefficient,
although the slower neutron kinetics of heavy-water moderated systems
compensates for this, leading to comparable safety with PWRs."
Moderator impurities
Good moderators are also free of neutron-absorbing impurities such as boron.
In commercial nuclear power plants the moderator typically contains
dissolved boron. The boron concentration of the reactor coolant can be
changed by the operators by adding boric acid or by diluting with water
to manipulate reactor power. The Nazi Nuclear Program
suffered a substantial setback when its inexpensive graphite moderators
failed to work. At that time, most graphites were deposited on boron
electrodes, and the German commercial graphite contained too much boron.
Since the war-time German program never discovered this problem, they
were forced to use far more expensive heavy water moderators. In the U.S., Leó Szilárd, a former chemical engineer, discovered the problem.
Non-graphite moderators
Some moderators are quite expensive, for example beryllium,
and reactor-grade heavy water. Reactor-grade heavy water must be
99.75% pure to enable reactions with unenriched uranium. This is
difficult to prepare because heavy water and regular water form the same
chemical bonds in almost the same ways, at only slightly different speeds.
The much cheaper light water moderator (essentially very pure
regular water) absorbs too many neutrons to be used with unenriched
natural uranium, and therefore uranium enrichment or nuclear reprocessing
becomes necessary to operate such reactors, increasing overall costs.
Both enrichment and reprocessing are expensive and technologically
challenging processes, and additionally both enrichment and several
types of reprocessing can be used to create weapons-usable material,
causing proliferation concerns. Reprocessing schemes that are more
resistant to proliferation are currently under development.
The CANDU
reactor's moderator doubles as a safety feature. A large tank of
low-temperature, low-pressure heavy water moderates the neutrons and
also acts as a heat sink in extreme loss-of-coolant accident
conditions. It is separated from the fuel rods that actually generate
the heat. Heavy water is very effective at slowing down (moderating)
neutrons, giving CANDU reactors their important and defining
characteristic of high "neutron economy".
Nuclear weapon design
Early speculation about nuclear weapons assumed that an "atom bomb" would be a large amount of fissile material, moderated by a neutron moderator, similar in structure to a nuclear reactor or "pile". Only the Manhattan project embraced the idea of a chain reaction of fast neutrons in pure metallic uranium or plutonium. Other moderated designs were also considered by the Americans; proposals included using uranium deuteride as the fissile material. In 1943 Robert Oppenheimer and Niels Bohr considered the possibility of using a "pile" as a weapon. The motivation was that with a graphite moderator it would be possible to achieve the chain reaction without the use of any isotope separation. In August 1945, when information of the atomic bombing of Hiroshima was relayed to the scientists of the German nuclear program, interred at Farm Hall in England, chief scientist Werner Heisenberg
hypothesized that the device must have been "something like a nuclear
reactor, with the neutrons slowed by many collisions with a moderator".
After the success of the Manhattan project, all major nuclear weapons programs have relied on fast neutrons in their weapons designs. The notable exception is the Ruth and Ray test explosions of Operation Upshot–Knothole. The aim of the University of California Radiation Laboratory designs was the exploration of deuterated polyethylene charge containing uranium as a candidate thermonuclear fuel,
hoping that deuterium would fuse (becoming an active medium) if
compressed appropriately. If successful, the devices could also lead to a
compact primary containing minimal amount of fissile material, and
powerful enough to ignite RAMROD a thermonuclear weapon
designed by UCRL at the time. For a "hydride" primary, the degree of
compression would not make deuterium to fuse, but the design could be
subjected to boosting, raising the yield considerably. The cores consisted of a mix of uranium deuteride (UD3), and deuterated polyethylene. The core tested in Ray used uranium low enriched in U235, and in both shots deuterium acted as the neutron moderator. The predicted yield was 1.5 to 3 kt for Ruth (with a maximum potential yield of 20 kt) and 0.5-1 kt for Ray. The tests produced yields of 200 tons of TNT each; both tests were considered to be fizzles.
The main benefit of using a moderator in a nuclear explosive is that the amount of fissile material needed to reach criticality may be greatly reduced. Slowing of fast neutrons will increase the cross section for neutron absorption, reducing the critical mass.
A side effect is however that as the chain reaction progresses, the
moderator will be heated, thus losing its ability to cool the neutrons.
Another effect of moderation is that the time between subsequent
neutron generations is increased, slowing down the reaction. This makes
the containment of the explosion a problem; the inertia that is used to confine implosion type bombs will not be able to confine the reaction. The end result may be a fizzle instead of a bang.
The explosive power of a fully moderated explosion is thus
limited, at worst it may be equal to a chemical explosive of similar
mass. Again quoting Heisenberg: "One can never make an explosive with
slow neutrons, not even with the heavy water machine, as then the
neutrons only go with thermal speed, with the result that the reaction
is so slow that the thing explodes sooner, before the reaction is
complete."
While a nuclear bomb working on thermal neutrons may be impractical, modern weapons designs may still benefit from some level of moderation. A beryllium tamper used as a neutron reflector will also act as a moderator.
Materials used
- Hydrogen, as in ordinary "light water". Because protium also has a significant cross section for neutron capture
only limited moderation is possible without losing too many neutrons.
The less-moderated neutrons are relatively more likely to be captured by
uranium-238 and less likely to fission uranium-235, so light water reactors require enriched uranium to operate.
- There are also proposals to use the compound formed by the chemical reaction of metallic uranium and hydrogen (uranium hydride—UH3) as a combination fuel and moderator in a new type of reactor.
- Hydrogen is also used in the form of cryogenic liquid methane and sometimes liquid hydrogen as a cold neutron source in some research reactors: yielding a Maxwell–Boltzmann distribution for the neutrons whose maximum is shifted to much lower energies.
- Hydrogen combined with carbon as in paraffin wax was used in some early German experiments.
- Deuterium, in the form of heavy water, in heavy water reactors, e.g. CANDU. Reactors moderated with heavy water can use unenriched natural uranium.
- Carbon, in the form of reactor-grade graphite or pyrolytic carbon, used in e.g. RBMK and pebble-bed reactors, or in compounds, e.g. carbon dioxide . Lower-temperature reactors are susceptible to buildup of Wigner energy in the material. Like deuterium-moderated reactors, some of these reactors can use unenriched natural uranium.
- Graphite is also deliberately allowed to be heated to around 2000 K or higher in some research reactors to produce a hot neutron source: giving a Maxwell–Boltzmann distribution whose maximum is spread out to generate higher energy neutrons.
- Beryllium, in the form of metal. Beryllium is expensive and toxic, so its use is limited.
- Lithium-7, in the form of a lithium fluoride salt, typically in conjunction with beryllium fluoride salt (FLiBe). This is the most common type of moderator in a Molten Salt Reactor.
Other light-nuclei materials are unsuitable for various reasons. Helium is a gas and it requires special design to achieve sufficient density; lithium-6 and boron-10 absorb neutrons.
Moderator | Reactors | Design | Country |
---|---|---|---|
none (fast) | 1 | BN-600 | Russia (1) |
graphite | 25 | AGR, Magnox, RBMK | United Kingdom (14), Russia (11) |
heavy water | 29 | CANDU PHWR | Canada (17), South Korea (4), Romania (2), China (2), India (18), Argentina, Pakistan |
light water | 359 | PWR, BWR | 27 countries |