A sodium-cooled fast reactor is a fast neutron reactor cooled by liquid sodium.
The initials SFR in particular refer to two Generation IV reactor proposals, one based on existing liquid metal cooled reactor (LMFR) technology using mixed oxide fuel (MOX), and one based on the metal-fueled integral fast reactor.
Several sodium-cooled fast reactors have been built and some are in current operation, particularly in Russia.[1] Others are in planning or under construction. For example, in 2022, in the US, TerraPower (using its Traveling Wave technology[2]) is planning to build its own reactors along with molten salt energy storage[2] in partnership with GEHitachi's PRISM integral fast reactor design, under the Natrium[3] appellation in Kemmerer, Wyoming.[4][5]
Aside from the Russian experience, Japan, India, China, France and the USA are investing in the technology.
The nuclear fuel cycle employs a full actinide recycle with two major options: One is an intermediate-size (150–600 MWe) sodium-cooled reactor with uranium-plutonium-minor-actinide-zirconium metal alloy fuel, supported by a fuel cycle based on pyrometallurgical reprocessing in facilities integrated with the reactor. The second is a medium to large (500–1,500 MWe) sodium-cooled reactor with mixed uranium-plutonium oxide fuel, supported by a fuel cycle based upon advanced aqueous processing at a central location serving multiple reactors. The outlet temperature is approximately 510–550 degrees C for both.
Liquid metallic sodium may be used to carry heat from the core. Sodium has only one stable isotope, sodium-23, which is a weak neutron absorber. When it does absorb a neutron it produces sodium-24, which has a half-life of 15 hours and decays to stable isotope magnesium-24.
The two main design approaches to sodium-cooled reactors are pool type and loop type.
In the pool type, the primary coolant is contained in the main reactor vessel, which therefore includes the reactor core and a heat exchanger. The US EBR-2, French Phénix and others used this approach, and it is used by India's Prototype Fast Breeder Reactor and China's CFR-600.
In the loop type, the heat exchangers are outside the reactor tank. The French Rapsodie, British Prototype Fast Reactor and others used this approach.
All fast reactors have several advantages over the current fleet of water based reactors in that the waste streams are significantly reduced. Crucially, when a reactor runs on fast neutrons, the plutonium isotopes are far more likely to fission upon absorbing a neutron. Thus, fast neutrons have a smaller chance of being captured by the uranium and plutonium, but when they are captured, have a much bigger chance of causing a fission. This means that the inventory of transuranic waste is non existent from fast reactors.
The primary advantage of liquid metal coolants, such as liquid sodium, is that metal atoms are weak neutron moderators. Water is a much stronger neutron moderator because the hydrogen atoms found in water are much lighter than metal atoms, and therefore neutrons lose more energy in collisions with hydrogen atoms. This makes it difficult to use water as a coolant for a fast reactor because the water tends to slow (moderate) the fast neutrons into thermal neutrons (although concepts for reduced moderation water reactors exist).
Another advantage of liquid sodium coolant is that sodium melts at 371K and boils / vaporizes at 1156K, a difference of 785K between solid / frozen and gas / vapor states. By comparison, the liquid temperature range of water (between ice and gas) is just 100K at normal, sea-level atmospheric pressure conditions. Despite sodium's low specific heat (as compared to water), this enables the absorption of significant heat in the liquid phase, while maintaining large safety margins. Moreover, the high thermal conductivity of sodium effectively creates a reservoir of heat capacity that provides thermal inertia against overheating.[6] Sodium need not be pressurized since its boiling point is much higher than the reactor's operating temperature, and sodium does not corrode steel reactor parts, and in fact, protects metals from corrosion.[6] The high temperatures reached by the coolant (the Phénix reactor outlet temperature was 560 C) permit a higher thermodynamic efficiency than in water cooled reactors.[7] The electrically conductive molten sodium can be moved by electromagnetic pumps.[7] The fact that the sodium is not pressurized implies that a much thinner reactor vessel can be used (e.g. 2 cm thick). Combined with the much higher temperatures achieved in the reactor, this means that the reactor in shutdown mode can be passively cooled. For example, air ducts can be engineered so that all the decay heat after shutdown is removed by natural convection, and no pumping action is required. Reactors of this type are self-controlling. If the temperature of the core increases, the core will expand slightly, which means that more neutrons will escape the core, slowing down the reaction.
A disadvantage of sodium is its chemical reactivity, which requires special precautions to prevent and suppress fires. If sodium comes into contact with water it reacts to produce sodium hydroxide and hydrogen, and the hydrogen burns in contact with air. This was the case at the Monju Nuclear Power Plant in a 1995 accident. In addition, neutron capture causes it to become radioactive; albeit with a half-life of only 15 hours.[6]
Another problem is leaks. Sodium at high temperatures ignites in contact with oxygen. Such sodium fires can be extinguished by powder, or by replacing the air with nitrogen. A Russian breeder reactor, the BN-600, reported 27 sodium leaks in a 17-year period, 14 of which led to sodium fires.[8]
Actinides and fission products by half-life
| ||||||||
---|---|---|---|---|---|---|---|---|
Actinides[9] by decay chain | Half-life range (y) |
Fission products of 235U by yield<ref>Specifically from thermal neutron fission of U-235, e.g. in a typical nuclear reactor.</ref> | ||||||
4n | 4n+1 | 4n+2 | 4n+3 | |||||
4.5–7% | 0.04–1.25% | <0.001% | ||||||
228Ra№ | 4–6 | † | 155Euþ | |||||
244Cmƒ | 241Puƒ | 250Cf | 227Ac№ | 10–29 | 90Sr | 85Kr | 113mCdþ | |
232Uƒ | 238Puƒ | 243Cmƒ | 29–97 | 137Cs | 151Smþ | 121mSn | ||
248Bk[10] | 249Cfƒ | 242mAmƒ | 141–351 |
No fission products | ||||
241Amƒ | 251Cfƒ[11] | 430–900 | ||||||
226Ra№ | 247Bk | 1.3 k – 1.6 k | ||||||
240Pu | 229Th | 246Cmƒ | 243Amƒ | 4.7 k – 7.4 k | ||||
245Cmƒ | 250Cm | 8.3 k – 8.5 k | ||||||
239Puƒ | 24.1 k | |||||||
230Th№ | 231Pa№ | 32 k – 76 k | ||||||
236Npƒ | 233Uƒ | 234U№ | 150 k – 250 k | ‡ | 99Tc₡ | 126Sn | ||
248Cm | 242Pu | 327 k – 375 k | 79Se₡ | |||||
1.53 M | 93Zr | |||||||
237Npƒ | 2.1 M – 6.5 M | 135Cs₡ | 107Pd | |||||
236U | 247Cmƒ | 15 M – 24 M | 129I₡ | |||||
244Pu | 80 M |
... nor beyond 15.7 M years[12] | ||||||
232Th№ | 238U№ | 235Uƒ№ | 0.7 G – 14.1 G | |||||
Legend for superscript symbols |
The operating temperature must not exceed the fuel's melting temperature. Fuel-to-cladding chemical interaction (FCCI) has to be accommodated. FCCI is eutectic melting between the fuel and the cladding; uranium, plutonium, and lanthanum (a fission product) inter-diffuse with the iron of the cladding. The alloy that forms has a low eutectic melting temperature. FCCI causes the cladding to reduce in strength and even rupture. The amount of transuranic transmutation is limited by the production of plutonium from uranium. One work-around is to have an inert matrix, using, e.g., magnesium oxide. Magnesium oxide has an order of magnitude lower probability of interacting with neutrons (thermal and fast) than elements such as iron.[13]
High-level wastes and, in particular, management of plutonium and other actinides must be handled. Safety features include a long thermal response time, a large margin to coolant boiling, a primary cooling system that operates near atmospheric pressure, and an intermediate sodium system between the radioactive sodium in the primary system and the water and steam in the power plant. Innovations can reduce capital cost, such as modular designs, removing a primary loop, integrating the pump and intermediate heat exchanger, and better materials.[14]
The SFR's fast spectrum makes it possible to use available fissile and fertile materials (including depleted uranium) considerably more efficiently than thermal spectrum reactors with once-through fuel cycles.
In 2020 Natrium received an $80M grant from the US Department of Energy for development of its SFR. The program plans to use High-Assay, Low Enriched Uranium fuel containing 5-20% uranium. The reactor was expected be sited underground and have gravity-inserted control rods. Because it operates at atmospheric pressure, a large containment shield is not necessary. Because of its large heat storage capacity, it was expected to be able to produce surge power of 500 MWe for 5+ hours, beyond its continuous power of 345 MWe.[15]
Sodium-cooled reactors have included:
Model | Country | Thermal power (MW) | Electric power (MW) | Year of commission | Year of decommission | Notes |
---|---|---|---|---|---|---|
BN-350 | Soviet Union | 350 | 1973 | 1999 | Was used to power a water de-salination plant. | |
BN-600 | Soviet Union | 600 | 1980 | Operational | Together with the BN-800, one of only two commercial fast reactors in the world. | |
BN-800 | Soviet Union/ Russia | 2100 | 880 | 2015 | Operational | Together with the BN-600, one of only two commercial fast reactors in the world. |
BN-1200 | Russia | 2900 | 1220 | 2036 | Not yet constructed | In development. Will be followed by BN-1200M as a model for export. |
CEFR | China | 65 | 20 | 2012 | Operational | |
CFR-600 | China | 1500 | 600 | 2023 | Under construction | Two reactors being constructed on Changbiao Island in Xiapu County. The second CFR-600 reactor will open in 2026.[16] |
CRBRP | United States | 1000 | 350 | Never built | ||
EBR-1 | United States | 1.4 | 0.2 | 1950 | 1964 | |
EBR-2 | United States | 62.5 | 20 | 1965 | 1994 | |
Fermi 1 | United States | 200 | 69 | 1963 | 1975 | |
Sodium Reactor Experiment | United States | 20 | 6.5 | 1957 | 1964 | |
S1G | United States | United States naval reactors | ||||
S2G | United States | United States naval reactors | ||||
Fast Flux Test Facility | United States | 400 | 1978 | 1993 | Not for power generation | |
PFR | United Kingdom | 500 | 250 | 1974 | 1994 | |
FBTR | India | 40 | 13.2 | 1985 | Operational | |
PFBR | India | 500 | 2024 | Under construction | ||
Monju | Japan | 714 | 280 | 1995/2010 | 2010 | Suspended for 15 years. Reactivated in 2010, then permanently closed |
Jōyō | Japan | 150 | 1971 | Operational | ||
SNR-300 | Germany | 327 | 1985 | 1991 | Never critical/operational | |
Rapsodie | France | 40 | 24 | 1967 | 1983 | |
Phénix | France | 590 | 250 | 1973 | 2010 | |
Superphénix | France | 3000 | 1242 | 1986 | 1997 | Largest SFR ever built. |
ASTRID | France | 600 | Never built | 2012-2019 €735 million spent |
Most of these were experimental plants that are no longer operational. On November 30, 2019, CTV reported that the Canadian provinces of New Brunswick, Ontario and Saskatchewan planned an announcement about a joint plan to cooperate on small sodium fast modular nuclear reactors from New Brunswick-based ARC Nuclear Canada.[17]
Original source: https://en.wikipedia.org/wiki/Sodium-cooled fast reactor.
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