Many types of breeder reactor are possible: A "breeder" is simply a
nuclear reactor designed for very high
neutron economy with an associated conversion rate higher than 1.0. In principle, almost any reactor design could be tweaked to become a breeder. For example, the
light-water reactor, a heavily moderated thermal design, evolved into the
RMWR concept, using light water in a low-density
supercritical form to increase the neutron economy enough to allow breeding. Aside from water-cooled, there are many other types of breeder reactor currently envisioned as possible. These include
molten-salt cooled,
gas cooled, and
liquid-metal cooled designs in many variations. Almost any of these basic design types may be fueled by
uranium,
plutonium, many minor
actinides, or
thorium, and they may be designed for many different goals, such as creating more fissile fuel, long-term steady-state operation, or active burning of
nuclear wastes. Extant reactor designs are sometimes divided into two broad categories based upon their neutron spectrum, which generally separates those designed to use primarily uranium and
transuranics from those designed to use thorium and avoid transuranics. These designs are: •
Fast breeder reactors (FBRs) which use
'fast' (i.e. unmoderated) neutrons to breed fissile plutonium (and possibly higher transuranics) from fertile
uranium-238. The fast spectrum is flexible enough that it can also breed fissile
uranium-233 from thorium, if desired. •
Thermal breeder reactors which use 'thermal-spectrum' or 'slow' (i.e.
moderated) neutrons to breed fissile
uranium-233 from thorium. Due to the behavior of the various nuclear fuels, a thermal breeder is thought commercially feasible only with thorium fuel, which avoids the buildup of the heavier transuranics.
Fast breeder reactor , which served as the prototype for the Integral Fast Reactor As of 2026 all large-scale FBR
power stations are
sodium cooled
liquid metal fast breeder reactors (LMFBR) of one of the following two designs: •
Loop type, in which the primary coolant is circulated through primary heat exchangers outside the reactor tank (but inside the
biological shield due to radioactive {{chem2|^{24}Na|link=sodium-24}} in the primary coolant) •
Pool type, in which the primary heat exchangers and pumps are immersed in the reactor tank There are only two commercially operating breeder reactors : the
BN-600 reactor, at 560 MWe, and the
BN-800 reactor, at 880 MWe. Both are Russian sodium-cooled reactors. The designs use liquid metal as the primary coolant, to transfer heat from the core to steam used to power the electricity generating turbines. FBRs cooled by liquid metals other than sodium have been built, some early FBRs such as
Clementine used
mercury,
Lead-cooled fast reactor have also been constructed, as well as other experimental reactors using
Lead-bismuth eutectic, molten
tin, or NaK, a
sodium-potassium alloy. Mercury and NaK have the advantage that they are liquids at room temperature, which is convenient for experimental rigs but less important for pilot or full-scale power stations, where their chemical toxicity and cost respectively leave them as less attractive options.
Lead-cooled fast reactor as well as those utilizing
Lead-bismuth eutectic saw extensive use in the Soviet Union, with liquid
Lead seeing use in the
BREST (reactor) and
Lead-bismuth eutectic having a troubled career as a coolant in
Alfa-class submarine's OK-550 and
BM-40A reactors as well as the SVBR-100 reactor. Three of the proposed
generation IV reactor types are FBRs: •
Gas-cooled fast reactor cooled by
helium. •
Sodium-cooled fast reactor based on the existing LMFBR and
integral fast reactor designs. •
Lead-cooled fast reactor based on Soviet naval propulsion units. FBRs usually use a
mixed oxide fuel core of up to 20%
plutonium dioxide () and at least 80%
uranium dioxide (). Another fuel option is
metal alloys, typically a blend of uranium, plutonium, and
zirconium (used because it is "transparent" to neutrons).
Enriched uranium can be used on its own. Many designs surround the
reactor core in a blanket of tubes that contain non-fissile uranium-238, which, by capturing fast neutrons from the reaction in the core, converts to fissile
plutonium-239 (as is some of the uranium in the core), which is then reprocessed and used as nuclear fuel. Other FBR designs rely on the geometry of the fuel (which also contains uranium-238), arranged to attain sufficient fast neutron capture. The plutonium-239 (or the fissile uranium-235)
fissile cross-section is much smaller in a fast spectrum than in a thermal spectrum, as is the ratio between the 239Pu/235U fission cross-section and the 238U absorption cross-section. This increases the concentration of 239Pu/235U needed to sustain a
chain reaction, as well as the ratio of breeding to fission. The type of coolants, temperatures, and fast neutron spectrum puts the fuel cladding material (normally
austenitic stainless or ferritic-martensitic steels) under extreme conditions. The understanding of the radiation damage, coolant interactions, stresses, and temperatures are necessary for the safe operation of any reactor core. All materials used to date in sodium-cooled fast reactors have known limits.
Oxide dispersion-strengthened alloy steel is viewed as the long-term radiation resistant fuel-cladding material that can overcome the shortcomings of today's material choices.
Integral fast reactor One design of fast neutron reactor, specifically conceived to address the waste disposal and plutonium issues, was the
integral fast reactor (IFR, also known as an integral fast breeder reactor, although the original reactor was designed to not breed a net surplus of fissile material). To solve the waste disposal problem, the IFR had an on-site
electrowinning fuel-reprocessing unit that recycled the uranium and all the transuranics (not just plutonium) via
electroplating, leaving just short-
half-life fission products in the waste. Some of these fission products could later be separated for industrial or medical uses and the rest sent to a waste repository. The IFR pyroprocessing system uses molten
cadmium cathodes and electrorefiners to reprocess metallic fuel directly on-site at the reactor. Such systems co-mingle all the minor actinides with both uranium and plutonium. The systems are compact and self-contained, so that no plutonium-containing material needs to be transported away from the site of the breeder reactor. Breeder reactors incorporating such technology would most likely be designed with breeding ratios very close to 1.00, so that after an initial loading of enriched uranium and/or plutonium fuel, the reactor would then be refueled only with small deliveries of
natural uranium. A quantity of natural uranium equivalent to a block about the size of a milk crate delivered once per month would be all the fuel such a 1 gigawatt reactor would need. Such self-contained breeders are currently envisioned as the final self-contained and self-supporting ultimate goal of nuclear reactor designers.
Other fast reactors The first fast reactor built and operated was the Los Alamos Plutonium Fast Reactor ("
Clementine") in Los Alamos, NM. Clementine was fueled by Ga-stabilized delta-phase Pu and cooled with mercury. It contained a 'window' of Th-232 in anticipation of breeding experiments, but no reports were made available regarding this feature. Another proposed fast reactor is a fast
molten salt reactor, in which the molten salt's moderating properties are insignificant. This is typically achieved by replacing the light metal fluorides (e.g. LiF, ) in the salt carrier with heavier metal chlorides (e.g., KCl, RbCl, ). Several prototype FBRs have been built, ranging in electrical output from a few light bulbs' equivalent (
EBR-I, 1951) to over 1,000
MWe. As of 2006, the technology is not economically competitive to thermal reactor technology, but
India, Japan, China, South Korea, and Russia are all committing substantial research funds to further development of fast breeder reactors, anticipating that rising uranium prices will change this in the long term. Germany, in contrast, abandoned the technology due to safety concerns. The
SNR-300 fast breeder reactor was finished after 19 years despite cost overruns summing up to a total of 3.6 billion, only to then be abandoned.
Thermal breeder reactor The
advanced heavy-water reactor is one of the few proposed large-scale uses of thorium. India is developing this technology, motivated by substantial thorium reserves; almost a third of the world's thorium reserves are in India, which lacks significant uranium reserves. The third and final core of the
Shippingport Atomic Power Station 60 MWe reactor was a light water thorium breeder, which began operating in 1977. It used pellets made of
thorium dioxide and uranium-233 oxide; initially, the U-233 content of the pellets was 5–6% in the seed region, 1.5–3% in the blanket region, and none in the reflector region. It operated at 236 MWt, generating 60 MWe, and ultimately produced over 2.1 billion kilowatt hours of electricity. After five years, the core was removed and found to contain nearly 1.4% more fissile material than when it was installed, demonstrating that breeding from thorium had occurred. A
liquid fluoride thorium reactor is also planned as a thorium thermal breeder. Liquid-fluoride reactors may have attractive features, such as inherent safety, no need to manufacture fuel rods, and possibly simpler reprocessing of the liquid fuel. This concept was first investigated at the
Oak Ridge National Laboratory Molten-Salt Reactor Experiment in the 1960s. From 2012 it became the subject of renewed interest worldwide. == Fuel resources ==