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Integral fast reactor

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Experimental Breeder Reactor II, which served as the prototype for the integral fast reactor (IFR)

The integral fast reactor (IFR), originally the advanced liquid-metal reactor (ALMR), is a design for a nuclear reactor using fast neutrons and no neutron moderator (a "fast" reactor). IFRs can breed more fuel and are distinguished by a nuclear fuel cycle that uses reprocessing via electrorefining at the reactor site.

The U.S. Department of Energy (DOE) began designing an IFR in 1984 and built a prototype, the Experimental Breeder Reactor II. On April 3, 1986, two tests demonstrated the safety of the IFR concept. These tests simulated accidents involving loss of coolant flow. Even with its normal shutdown devices disabled, the reactor shut itself down safely without overheating anywhere in the system. The IFR project was canceled by the US Congress in 1994, three years before completion.[1]

The proposed Generation IV sodium-cooled fast reactor (SFR) is its closest surviving fast breeder reactor design. Other countries have also designed and operated fast reactors.

S-PRISM (from SuperPRISM), also called PRISM (power reactor innovative small module), is the name of a nuclear power plant design by GE Hitachi Nuclear Energy based on the IFR.[2] In 2022, GE Hitachi Nuclear Energy and TerraPower began exploring locating five Natrium SFR-based nuclear power plants in Kemmerer, Wyoming; the design incorporates a PRISM reactor plus TerraPower's Traveling Wave design with a molten salt storage system.[3][4]

History

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Research on IFR reactors began in 1984 at Argonne National Laboratory in Argonne, Illinois, as a part of the U.S. Department of Energy's national laboratory system, and currently operated on a contract by the University of Chicago.

The Experimental Breeder Reactor II (EBR II)

Argonne previously had a branch campus named "Argonne West" in Idaho Falls, Idaho, that is now part of the Idaho National Laboratory. In the past, at the branch campus, physicists from Argonne West built what was known as the Experimental Breeder Reactor II (EBR-II). In the meantime, physicists at Argonne designed the IFR concept, and it was decided that the EBR-II would be converted to an IFR. Charles Till, a Canadian physicist from Argonne, was the head of the IFR project, and Yoon Chang was the deputy head. Till was positioned in Idaho, while Chang was in Illinois.

Cancellation

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With the election of President Bill Clinton in 1992, and the appointment of Hazel O'Leary as the Secretary of Energy, there was pressure from the top to cancel the IFR.[5] Senator John Kerry (D-MA) and O'Leary led the opposition to the reactor, arguing that it would be a threat to non-proliferation efforts, and that it was a continuation of the Clinch River Breeder Reactor Project that had been canceled by Congress.[6]

Simultaneously, in 1994 Energy Secretary O'Leary awarded the lead IFR scientist with $10,000 and a gold medal, with the citation stating his work to develop IFR technology provided "improved safety, more efficient use of fuel and less radioactive waste".[7]

IFR opponents also presented a report[8] by the DOE's Office of Nuclear Safety regarding a former Argonne employee's allegations that Argonne had retaliated against him for raising concerns about safety, as well as about the quality of research done on the IFR program. The report received international attention, with a notable difference in the coverage it received from major scientific publications. The British journal Nature entitled its article "Report backs whistleblower", and also noted conflicts of interest on the part of a DOE panel that assessed IFR research.[9] In contrast, the article that appeared in Science was entitled "Was Argonne Whistleblower Really Blowing Smoke?".[10]

Despite support for the reactor by then-Rep. Dick Durbin (D-IL) and U.S. Senators Carol Moseley Braun (D-IL) and Paul Simon (D-IL), funding for the reactor was slashed, and it was ultimately canceled in 1994, at a greater cost than finishing it. When this was brought to President Clinton's attention, he said "I know; it's a symbol."[citation needed]

Since 2000

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In 2001, as part of the Generation IV roadmap, the DOE tasked a 242-person team of scientists from DOE, UC Berkeley, Massachusetts Institute of Technology (MIT), Stanford, ANL, Lawrence Livermore National Laboratory, Toshiba, Westinghouse, Duke, EPRI, and other institutions to evaluate 19 of the best reactor designs on 27 different criteria. The IFR ranked #1 in their study which was released April 9, 2002.[11]

At present, there are no integral fast reactors in commercial operation. However, the BN-800 reactor, a very similar fast reactor operated as a burner of plutonium stockpiles, became commercially operational in 2014.[citation needed]

Technical overview

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The IFR is cooled by liquid sodium and fueled by an alloy of uranium and plutonium. The fuel is contained in steel cladding with liquid sodium filling in the space between the fuel and the cladding. A void above the fuel allows helium and radioactive xenon to be collected safely[citation needed] without significantly increasing pressure inside the fuel element,[citation needed] and also allows the fuel to expand without breaching the cladding, making metal rather than oxide fuel practical.[citation needed] The advantages of liquid sodium coolant, as opposed to liquid metal lead, are that liquid sodium is far less dense and far less viscous (reduced pumping costs), is not corrosive (via dissolution) to common steels, and creates essentially no radioactive neutron activation byproducts. The disadvantage of sodium coolant, as opposed to lead coolant, is that sodium is chemically reactive, especially with water or air. Lead may be substituted for the eutectic alloy of lead and bismuth, as used as reactor coolant in Soviet Alfa-class submarines.

Basic design decisions

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Metallic fuel

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Metal fuel with a sodium-filled void inside the cladding to allow fuel expansion has been demonstrated in EBR-II. Metallic fuel makes pyroprocessing the reprocessing technology of choice.[citation needed]

Fabrication of metallic fuel is easier and cheaper than ceramic (oxide) fuel, especially under remote handling conditions.[12]

Metallic fuel has better heat conductivity and lower heat capacity than oxide, which has safety advantages.[12]

Sodium coolant

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The use of liquid metal coolant removes the need for a pressure vessel around the reactor. Sodium has excellent nuclear characteristics, a high heat capacity and heat transfer capacity, low density, low viscosity, a reasonably low melting point and a high boiling point, and excellent compatibility with other materials including structural materials and fuel.[citation needed] The high heat capacity of the coolant and the elimination of water from the reactor core increase the inherent safety of the core.[12]

Pool design rather than loop

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Containing all of the primary coolant in a pool produces several safety and reliability advantages.[12]

Onsite reprocessing using pyroprocessing

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Reprocessing is essential to achieve most of the benefits of a fast reactor, improving fuel usage and reducing radioactive waste by several orders of magnitude.[12]

Onsite processing is what makes the IFR "integral". This and the use of pyroprocessing both reduce proliferation risk.[12][13]

Pyroprocessing (using an electrorefiner) has been demonstrated at EBR-II as practical on the scale required. Compared to the PUREX aqueous process, it is economical in capital cost, and is unsuitable for the production of weapons material, again unlike PUREX which was developed for weapons programs.[citation needed]

Pyroprocessing makes metallic fuel the fuel of choice. The two decisions are complementary.[12]

Summary

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The four basic decisions of metallic fuel, sodium coolant, pool design, and onsite reprocessing by electrorefining, are complementary and produce a fuel cycle that is proliferation-resistant and efficient in fuel usage, and a reactor with a high level of inherent safety, while minimizing the production of high-level waste. The practicality of these decisions has been demonstrated over many years of operation of EBR-II.[12]

Advantages

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Breeder reactors (such as the IFR) could in principle extract almost all of the energy contained in uranium or thorium, decreasing fuel requirements by nearly two orders of magnitude compared to traditional once-through reactors, which extract less than 0.65% of the energy in mined uranium, and less than 5% of the enriched uranium with which they are fueled. This could greatly dampen concern about fuel supply or energy used in mining.

What is more important today is why fast reactors are fuel-efficient: because fast neutrons can fission or "burn out" all the transuranic waste components. Transuranic waste consists of actinidesreactor-grade plutonium and minor actinides – many of which last tens of thousands of years or longer and make conventional nuclear waste disposal so problematic. Most of the radioactive fission products produced by an IFR have much shorter half-lives: they are intensely radioactive in the short term but decay quickly. Through many cycles, the IFR ultimately causes 99.9% of the uranium and transuranium elements to undergo fission and produce power; so, its only waste is the nuclear fission products. These have much shorter half-lives; in 300 years, their radioactivity will fall below that of the original uranium ore.[14][15][unreliable source?][16][better source needed] The fact that 4th generation reactors are being designed to use the waste from 3rd generation plants could change the nuclear story fundamentally—potentially making the combination of 3rd and 4th generation plants a more attractive energy option than 3rd generation by itself would have been, both from the perspective of waste management and energy security.

"Integral" refers to on-site reprocessing by electrochemical pyroprocessing. This process separates spent fuel into 3 fractions: uranium, plutonium isotopes and other transuranium elements, and nuclear fission products. The uranium and transuranium elements are recycled into new fuel rods, and the fission products are eventually converted to glass and metal blocks for safer disposal. Because the combined transuranium elements and the fission products are highly radioactive, fuel-rod transfer and reprocessing operations use robotic or remote-controlled equipment. An additional claimed benefit of this is that since fissile material never leaves the facility (and would be lethal to handle if it did), this greatly reduces the proliferation potential of possible diversion of fissile material.

Safety

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In traditional light-water reactors (LWRs) the core must be maintained at a high pressure to keep the water liquid at high temperatures. In contrast, since the IFR is a liquid metal cooled reactor, the core could operate at close to ambient pressure, dramatically reducing the danger of a loss-of-coolant accident. The entire reactor core, heat exchangers, and primary cooling pumps are immersed in a pool of liquid sodium or lead, making a loss of primary coolant extremely unlikely. The coolant loops are designed to allow for cooling through natural convection, meaning that in the case of a power loss or unexpected reactor shutdown, the heat from the reactor core would be sufficient to keep the coolant circulating even if the primary cooling pumps were to fail.

The IFR also has passive safety advantages as compared with conventional LWRs. The fuel and cladding are designed such that when they expand due to increased temperatures, more neutrons would be able to escape the core, thus reducing the rate of the fission chain reaction. In other words, an increase in the core temperature acts as a feedback mechanism that decreases the core power. This attribute is known as a negative temperature coefficient of reactivity. Most LWRs also have negative reactivity coefficients; however, in an IFR, this effect is strong enough to stop the reactor from reaching core damage without external action from operators or safety systems. This was demonstrated in a series of safety tests on the prototype. Pete Planchon, the engineer who conducted the tests for an international audience, quipped "Back in 1986, we actually gave a small [20 MWe] prototype advanced fast reactor a couple of chances to melt down. It politely refused both times."[17]

Liquid sodium presents safety problems because it ignites spontaneously on contact with air and can cause explosions on contact with water. This was the case at the Monju Nuclear Power Plant in a 1995 accident and fire. To reduce the risk of explosions following a leak of water from the steam turbines, the IFR design (as with other sodium-cooled fast reactors) includes an intermediate liquid-metal coolant loop between the reactor and the steam turbines. The purpose of this loop is to ensure that any explosion following the accidental mixing of sodium and turbine water would be limited to the secondary heat exchanger and not pose a risk to the reactor itself. Alternative designs use lead instead of sodium as the primary coolant. The disadvantages of lead are its higher density and viscosity, which increases pumping costs, and radioactive activation products resulting from neutron absorption. A lead-bismuth eutectate, as used in some Russian submarine reactors, has lower viscosity and density, but the same activation product problems can occur.

Efficiency and fuel cycle

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t½
(year)
Yield
(%)
Q
(keV)
βγ
155Eu 4.76 0.0803 252 βγ
85Kr 10.76 0.2180 687 βγ
113mCd 14.1 0.0008 316 β
90Sr 28.9 4.505   2826 β
137Cs 30.23 6.337   1176 βγ
121mSn 43.9 0.00005 390 βγ
151Sm 94.6 0.5314 77 β

The goals of the IFR project were to increase the efficiency of uranium usage by breeding plutonium and to eliminate the need for transuranic isotopes to ever leave the site. The reactor was an unmoderated design running on fast neutrons, designed to allow any transuranic isotope to be consumed (and in some cases used as fuel).

Compared to current light-water reactors with a once-through fuel cycle that induces fission (and derives energy) from less than 1% of the uranium found in nature, a breeder reactor like the IFR has a very efficient fuel cycle (99.5% of uranium undergoes fission[citation needed]).[15] The basic scheme uses pyroelectric separation, a common method in other metallurgical processes, to remove transuranics and actinides from the wastes and concentrate them. These concentrated fuels are then reformed, on-site, into new fuel elements.

The available fuel metals are never separated from the plutonium isotopes nor from all the fission products,[13][better source needed] and are therefore relatively difficult to use in nuclear weapons. Also, as plutonium never has to leave the site, it is far less open to unauthorized diversion.[18]

Another important benefit of removing the long-half-life transuranics from the waste cycle is that the remaining waste becomes a much shorter-term hazard. After the actinides (reprocessed uranium, plutonium, and minor actinides) are recycled, the remaining radioactive waste isotopes are fission products – with half-lives of 90 years (Sm-151) and less, or 211,100 years (Tc-99) and more – plus any activation products from the non-fuel reactor components.

Comparisons to light-water reactors

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Transmutation flow between 238Pu and 244Cm in a LWR.[19] Current thermal-neutron fission reactors cannot fission actinide nuclides that have an even number of neutrons. Thus, these build up and are generally treated as transuranic waste after conventional reprocessing. An argument for fast reactors is that they can fission all actinides.

Nuclear waste

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Integral fast reactors (IFRs) can produce much less waste than light-water reactors (LWRs), and can even utilize other waste as fuel.

The primary argument for pursuing IFR-style technology today is that it provides the best solution to the existing nuclear waste problem because fast reactors can be fueled from the waste products of existing reactors as well as from the plutonium used in weapons, as is the case in the operating BN-800 reactor. Depleted uranium waste can also be used as fuel in fast reactors.

The waste products of IFR reactors either have a short half-life, which means that they decay quickly and become relatively safe, or a long half-life, which means that they are only slightly radioactive. Neither of the two forms of IFR waste produced contain plutonium or other actinides. Due to pyroprocessing, the total volume of true waste/fission products is 1/20th the volume of spent fuel produced by a light-water plant of the same power output, and is often considered to be all unusable waste. 70% of fission products are either stable or have half-lives under one year. Technetium-99 and iodine-129, which constitute 6% of fission products, have very long half-lives but can be transmuted to isotopes with very short half-lives (15.46 seconds and 12.36 hours) by neutron absorption within a reactor, effectively destroying them (see more: long-lived fission products). Zirconium-93, another 5% of fission products, could in principle be recycled into fuel-pin cladding, where it does not matter that it is radioactive. Excluding the contribution from transuranic waste (TRU) – which are isotopes produced when uranium-238 captures a slow thermal neutron in an LWR but does not fission – all high level waste/fission products remaining after reprocessing the TRU fuel is less radiotoxic (in sieverts) than natural uranium (in a gram-to-gram comparison) within 200–400 years, and continues to decline afterward.[20][21][15][unreliable source?][16][better source needed]

The on-site reprocessing of fuel means that the volume of high-level nuclear waste leaving the plant is tiny compared to LWR spent fuel.[note 1] In fact, in the U.S. most spent LWR fuel has remained in storage at the reactor site instead of being transported for reprocessing or placement in a geological repository. The smaller volumes of high level waste from reprocessing could stay at reactor sites for some time, but are intensely radioactive from medium-lived fission products (MLFPs) and need to be stored securely, like in dry cask storage vessels. In its first few decades of use, before the MLFPs decay to lower levels of heat production, geological repository capacity is constrained not by volume but by heat generation. This limits early repository emplacement. Decay heat generation of MLFPs from IFRs is about the same per unit power as from any kind of fission reactor.

The potential complete removal of plutonium from the waste stream of the reactor reduces the concern that now exists with spent nuclear fuel from most other reactors, namely that a spent fuel repository could be used as a plutonium mine at some future date.[22] Also, despite the million-fold reduction in radiotoxicity offered by this scheme,[note 2] there remain concerns about radioactive longevity:

[Some believe] that actinide removal would offer few if any significant advantages for disposal in a geologic repository because some of the fission product [sic] nuclides of greatest concern in scenarios such as groundwater leaching actually have longer half-lives than the radioactive actinides. The concern about a waste cannot end after hundreds of years even if all the actinides are removed when the remaining waste contains radioactive fission products such as technetium-99, iodine-129, and cesium-135 with the half-lives between 213,000 and 15.7 million years.[22]

However, these concerns do not consider the plan to store such materials in insoluble Synroc, and do not measure hazards in proportion to those from natural sources such as medical x-rays, cosmic rays, or naturally radioactive rocks (such as granite).[citation needed] Furthermore, some of the radioactive fission products are being targeted for transmutation, belaying even these comparatively low concerns. For example, the IFR's positive void coefficient could be reduced to an acceptable level by adding technetium to the core, helping destroy the long-lived fission product technetium-99 by nuclear transmutation in the process.[23]

Efficiency

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IFRs use virtually all of the energy content in the uranium fuel whereas a traditional light-water reactor uses less than 0.65% of the energy in mined uranium and less than 5% of the energy in enriched uranium.

Carbon dioxide

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Both IFRs and LWRs do not emit CO2 during operation, although construction and fuel processing result in CO2 emissions (if via energy sources which are not carbon neutral, such as fossil fuels) and CO2-emitting cements are used in the construction process.

A 2012 Yale University review analyzing CO2 life cycle assessment (LCA) emissions from nuclear power determined that:[24]

The collective LCA literature indicates that life cycle GHG [greenhouse gas] emissions from nuclear power are only a fraction of traditional fossil sources and comparable to renewable technologies.

Although the paper primarily dealt with data from Generation II reactors, and did not analyze the CO2 emissions by 2050 of the Generation III reactors presently under construction, it did summarize the LCA findings of in-development reactor technologies:

Theoretical FBRs [fast breeder reactors] have been evaluated in the LCA literature. The limited literature that evaluates this potential future technology reports median life cycle GHG emissions... similar to or lower than LWRs [light water reactors] and purports to consume little or no uranium ore.

Actinides[25] by decay chain Half-life
range (a)
Fission products of 235U by yield[26]
4n 4n + 1 4n + 2 4n + 3 4.5–7% 0.04–1.25% <0.001%
228Ra 4–6 a 155Euþ
248Bk[27] > 9 a
244Cmƒ 241Puƒ 250Cf 227Ac 10–29 a 90Sr 85Kr 113mCdþ
232Uƒ 238Puƒ 243Cmƒ 29–97 a 137Cs 151Smþ 121mSn
249Cfƒ 242mAmƒ 141–351 a

No fission products have a half-life
in the range of 100 a–210 ka ...

241Amƒ 251Cfƒ[28] 430–900 a
226Ra 247Bk 1.3–1.6 ka
240Pu 229Th 246Cmƒ 243Amƒ 4.7–7.4 ka
245Cmƒ 250Cm 8.3–8.5 ka
239Puƒ 24.1 ka
230Th 231Pa 32–76 ka
236Npƒ 233Uƒ 234U 150–250 ka 99Tc 126Sn
248Cm 242Pu 327–375 ka 79Se
1.33 Ma 135Cs
237Npƒ 1.61–6.5 Ma 93Zr 107Pd
236U 247Cmƒ 15–24 Ma 129I
244Pu 80 Ma

... nor beyond 15.7 Ma[29]

232Th 238U 235Uƒ№ 0.7–14.1 Ga

Fuel cycle

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Fast reactor fuel must be at least 20% fissile, greater than the low-enriched uranium used in LWRs. The fissile material can initially include highly enriched uranium or plutonium from LWR spent fuel, decommissioned nuclear weapons, or other sources. During operation, the reactor breeds more fissile material from fertile material – at most about 5% more from uranium and 1% more from thorium.

The fertile material in fast reactor fuel can be depleted uranium (mostly uranium-238), natural uranium, thorium, or reprocessed uranium from spent fuel from traditional LWRs,[15] and even include nonfissile isotopes of plutonium and minor actinide isotopes. Assuming no leakage of actinides to the waste stream during reprocessing, a 1 GWe IFR-style reactor would consume about 1 ton of fertile material per year and produce about 1 ton of fission products.

The IFR fuel cycle's reprocessing by pyroprocessing (in this case, electrorefining) does not need to produce pure plutonium, free of fission product radioactivity, as the PUREX process is designed to do. The purpose of reprocessing in the IFR fuel cycle is simply to reduce the level of those fission products that are neutron poisons; even these need not be completely removed. The electrorefined spent fuel is highly radioactive, but because new fuel need not be precisely fabricated like LWR fuel pellets but can simply be cast, remote fabrication can be used, reducing exposure to workers.

Like any fast reactor, by changing the material used in the blankets, the IFR can be operated over a spectrum from breeder to self-sufficient to burner. In breeder mode (using U-238 blankets) the reactor produces more fissile material than it consumes. This is useful for providing fissile material for starting up other plants. Using steel reflectors instead of U-238 blankets, the reactor operates in pure burner mode and is not a net creator of fissile material; on balance, it will consume fissile and fertile material and, assuming loss-free reprocessing, output no actinides but only fission products and activation products. The amount of fissile material needed could be a limiting factor to very widespread deployment of fast reactors if stocks of surplus weapons plutonium and LWR spent fuel plutonium are not sufficient. To maximize the rate at which fast reactors can be deployed, they can be operated in maximum breeding mode.

Because the current cost of enriched uranium is low compared to the expected cost of large-scale pyroprocessing and electrorefining equipment and the cost of building a secondary coolant loop, the higher fuel costs of a thermal reactor over the expected operating lifetime of the plant are offset by increased capital cost. (Currently, in the United States, utilities pay a flat rate of 1/10 of a cent per kilowatt hour to the Government for disposal of high-level radioactive waste by law under the Nuclear Waste Policy Act. If this charge were based on the longevity of the waste, closed fuel cycles might become more financially competitive. As the planned geological repository in the form of Yucca Mountain is not going ahead, this fund has collected over the years and presently $25 billion has piled up on the Government's doorstep for something they have not delivered, that is, reducing the hazard posed by the waste.[30])

Reprocessing nuclear fuel using pyroprocessing and electrorefining has not yet been demonstrated on a commercial scale, so investing in a large IFR-style plant may be a higher financial risk than a conventional LWR.

Passive safety

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IFR concept (color); an animation of the pyroprocessing cycle is also available.[31]
IFR concept (black and white with clearer text)

The IFR uses metal alloy fuel (uranium, plutonium, and/or zirconium), which is a good conductor of heat, unlike the uranium oxide used by LWRs (and even some fast breeder reactors), which is a poor conductor of heat and reaches high temperatures at the center of fuel pellets. The IFR also has a smaller volume of fuel, since the fissile material is diluted with fertile material by a ratio of 5 or less, compared to about 30 for LWR fuel. The IFR core requires more heat removal per core volume during operation than the LWR core; but on the other hand, after a shutdown, there is far less trapped heat that is still diffusing out and needs to be removed. However, decay heat generation from short-lived fission products and actinides is comparable in both cases, starting at a high level and decreasing with time elapsed after shutdown. The high volume of liquid sodium primary coolant in the pool configuration is designed to absorb decay heat without reaching fuel melting temperature. The primary sodium pumps are designed with flywheels so they will coast down slowly (90 seconds) if power is removed. This coast-down further aids core cooling upon shutdown. If the primary cooling loop were to be somehow suddenly stopped, or if the control rods were suddenly removed, the metal fuel can melt, as accidentally demonstrated in EBR-I; however, the melting fuel is then extruded up the steel fuel cladding tubes and out of the active core region leading to permanent reactor shutdown and no further fission heat generation or fuel melting.[32] With metal fuel, the cladding is not breached and no radioactivity is released even in extreme overpower transients.

Self-regulation of the IFR's power level depends mainly on thermal expansion of the fuel, which allows more neutrons to escape, damping the chain reaction. LWRs have less effect from thermal expansion of fuel (since much of the core is the neutron moderator) but have strong negative feedback from Doppler broadening (which acts on thermal and epithermal neutrons, not fast neutrons) and negative void coefficient from boiling of the water moderator/coolant; the less dense steam returns fewer and less-thermalized neutrons to the fuel, which are more likely to be captured by U-238 than induce fissions. However, the IFR's positive void coefficient could be reduced to an acceptable level by adding technetium to the core, helping destroy the long-lived fission product technetium-99 by nuclear transmutation in the process.[23]

IFRs are able to withstand both a loss of flow without SCRAM and loss of heat sink without SCRAM. In addition to the passive shutdown of the reactor, the convection current generated in the primary coolant system will prevent fuel damage (core meltdown). These capabilities were demonstrated in the EBR-II.[1] The ultimate goal is that no radioactivity is released under any circumstance.

The flammability of sodium is a risk to operators. Sodium burns easily in air and will ignite spontaneously on contact with water. The use of an intermediate coolant loop between the reactor and the turbines minimizes the risk of a sodium fire in the reactor core.

Under neutron bombardment, sodium-24 is produced. This is highly radioactive, emitting an energetic gamma ray of 2.7 MeV followed by a beta decay to form magnesium-24. Half-life is only 15 hours, so this isotope is not a long-term hazard. Nevertheless, the presence of sodium-24 further necessitates the use of the intermediate coolant loop between the reactor and the turbines.

Proliferation

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IFRs and light-water reactors (LWRs) both produce reactor grade plutonium – which even at high burnups remains weapons-usable[33] – but the IFR fuel cycle has some design features that make proliferation more difficult than the current PUREX recycling of spent LWR fuel. For one thing, it may operate at higher burnups and therefore increase the relative abundance of the non-fissile, but fertile, isotopes plutonium-238, plutonium-240, and plutonium-242.[34]

Unlike PUREX reprocessing, the IFR's electrolytic reprocessing of spent fuel does not separate out pure plutonium. Instead, it is left mixed with minor actinides and some rare earth fission products, which makes the theoretical ability to make a bomb directly out of it considerably dubious.[13][better source needed] Rather than being transported from a large centralized reprocessing plant to reactors at other locations – as is common now in France, from La Hague to its dispersed nuclear fleet of LWRs – the IFR pyroprocessed fuel would be much more resistant to unauthorized diversion.[18][better source needed] The material with the mix of plutonium isotopes in an IFR would stay at the reactor site and then be burnt up practically in-situ;[18][better source needed] alternatively, if operated as a breeder reactor, some of the pyroprocessed fuel could be consumed by the reactor (or other reactors located elsewhere). However, as is the case with conventional aqueous reprocessing, it would remain possible to chemically extract all the plutonium isotopes from the pyroprocessed fuel. In fact, it would be much easier to do so from the recycled product than from the original spent fuel. However, doing so would still be more difficult when compared to another conventional recycled nuclear fuel, MOX, as the IFR recycled fuel contains more fission products and, due to its higher burnup, more proliferation-resistant Pu-240 than MOX.

An advantage to the removal and burn up of actinides (include plutonium) from the IFR's spent fuel is the elimination of concerns about leaving spent fuel (or indeed conventional – and therefore comparatively lower burnup – spent fuel, which can contain weapons-usable plutonium isotope concentrations) in a geological repository or dry cask storage, which could be mined in the future for the purpose of making weapons.[22]

Because reactor-grade plutonium contains isotopes of plutonium with high spontaneous fission rates, and the ratios of these troublesome isotopes (from a weapons manufacturing point of view) only increases[clarification needed] as the fuel is burnt up for longer and longer, it is considerably more difficult to produce fission nuclear weapons of substantial yield from highly burnt up spent fuel than from (conventional) moderately burnt up LWR spent fuel.

Therefore, proliferation risks are considerably reduced with the IFR system by many metrics, but not entirely eliminated. The plutonium from advanced liquid metal reactor (ALMR) recycled fuel would have an isotopic composition similar to that obtained from other highly burnt up spent nuclear fuel sources. Although this makes the material less attractive for weapons production, it could nonetheless be used in less sophisticated weapons or with fusion boosting.

In 1962, the U.S. government detonated a nuclear device using then-defined "reactor-grade plutonium", although in more recent categorizations it would instead be considered as fuel-grade plutonium, typical of that produced by low burn up Magnox reactors.[35][36]

Plutonium produced in the fuel of a breeder reactor generally has a higher fraction of the isotope plutonium-240 than that produced in other reactors, making it less attractive for weapons use, particularly in first-generation nuclear weapon designs similar to Fat Man. This offers an intrinsic degree of proliferation resistance. However, if a blanket of uranium is used to surround the core during breeding, the plutonium made in the blanket is usually of a high Pu-239 quality, containing very little Pu-240, making it highly attractive for weapons use.[37]

If operated as a breeder instead of a burner, the IFR has proliferation potential:

Although some recent proposals for the future of the ALMR/IFR concept have focused more on its ability to transform and irreversibly use up plutonium, such as the conceptual PRISM (reactor) and the in operation (2014) BN-800 reactor in Russia, the developers of the IFR acknowledge that it is 'uncontested that the IFR can be configured as a net producer of plutonium'.[38] If instead of processing spent fuel, the ALMR system were used to reprocess irradiated fertile (breeding) material [that is, if a blanket of breeding U-238 was used] in the electrorefiner, the resulting plutonium would be a superior material, with a nearly ideal isotope composition for nuclear weapons manufacture.[39]

Reactor design and construction

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A commercial version of the IFR, S-PRISM, can be built in a factory and transported to the site. This small modular design (311 MWe modules) reduces costs and allows nuclear plants of various sizes (311 MWe and any integer multiple) to be economically constructed.

Cost assessments taking account of the complete life cycle show that fast reactors could be no more expensive than water-moderated water-cooled reactors, currently the most widely used reactors in the world.[40]

Liquid metal sodium coolant

[edit]

Unlike reactors that use relatively slow low energy (thermal) neutrons, fast-neutron reactors need nuclear reactor coolant that does not moderate or block neutrons (like water does in an LWR) so that they have sufficient energy to fission actinide isotopes that are fissionable but not fissile. The core must also be compact and contain the least amount of neutron-moderating material as possible. Metal sodium coolant in many ways has the most attractive combination of properties for this purpose. In addition to not being a neutron moderator, desirable physical characteristics include:

  • Low melting temperature
  • Low vapor pressure
  • High boiling temperature
  • Excellent thermal conductivity
  • Low viscosity
  • Light weight
  • Thermal and radiation stability

Additional benefits to using liquid sodium include:

  • Abundant and low-cost material
  • Cleaning with chlorine produces non-toxic table salt
  • Compatible with other materials used in the core (does not react or dissolve stainless steel), so no special corrosion protection measures are needed
  • Low pumping power (from lightweight and low viscosity)
  • Protects other components from corrosion by maintaining an oxygen- and water-free environment (sodium would react with any trace amounts to make sodium oxide or sodium hydroxide and hydrogen)
  • Lightweight (low density) improves resistance to seismic inertia events (earthquakes)

Significant drawbacks to using sodium are its extreme fire hazardousness in the presence of any significant amounts of air (oxygen) and its spontaneous combustion with water, rendering sodium leaks and flooding dangerous. This was the case at the Monju Nuclear Power Plant in a 1995 accident and fire. Reactions with water produce hydrogen which can be explosive. The sodium activation product (isotope) 24Na releases dangerous energetic photons when it decays (albeit having only short half-life of 15 hours). The reactor design keeps 24Na in the reactor pool and carries away heat for power production using a secondary sodium loop, but this adds costs to construction and maintenance.[41]

See also

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Notes

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  1. ^ Estimates from Argonne National Laboratory place the output of waste of a 1,000 MWe plant operating at 70% capacity at 1,700 pounds/year.[15]
  2. ^ Radioactivity and its associated dangers are roughly divided by an isotope's half-life. For example, given the 213,000-year half-life of technetium-99, combined with the IFR's 1/20 volume reduction, produces about 1/4,000,000 of the radiotoxicity of light-water reactor waste. The small size (about 1.5 tonnes per gigawatt-year) permits expensive disposal methods such as insoluble synthetic rock. The hazards are far less than those from fossil fuel wastes or dam failures.

References

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  1. ^ a b The IFR at Argonne National Laboratory, www.ne.anl.gov, accessed 1 November 2022
  2. ^ "GE Hitachi Nuclear Energy Encourages Congress to Support Development of Recycling Technology to Turn Used Nuclear Fuel into an Asset – GE Energy press release". Genewscenter.com. 2009-06-18. Archived from the original on 2013-12-03. Retrieved 2014-01-24.
  3. ^ "Natrium". NRC Web. Retrieved 2022-10-28.
  4. ^ Patel, Sonal (2022-10-27). "PacifiCorp, TerraPower Evaluating Deployment of Up to Five Additional Natrium Advanced Reactors". POWER Magazine. Retrieved 2022-10-27.
  5. ^ "Dr. Charles Till | Nuclear Reaction | FRONTLINE". PBS. 2014-01-16. Retrieved 2014-01-24.
  6. ^ "ENERGY AND WATER DEVELOPMENT APPROPRIATIONS ACT OF 1995 (Senate – June 30, 1994)". 103rd Congressional Record. Library of Congress. Archived from the original on 10 January 2016. Retrieved 16 December 2012.
  7. ^ "Ax Again Aimed at Argonne (Chicago Tribune – Feb 8, 1994)". Chicago Tribune. 8 February 1994. Retrieved 18 March 2015.
  8. ^ Report of investigation into allegations of retaliation for raising safety and quality of work issues regarding Argonne National Laboratory's Integral Fast Reactor Project, Report Number DOE/NS-0005P, 1991 Dec 01 OSTI Identifier OSTI ID: 6030509,
  9. ^ Report backs whistleblower, Nature 356, 469 (9 April 1992)
  10. ^ Science, Vol. 256, No. 5055, 17 April 1992
  11. ^ Generation IV roadmap. Evaluation Summaries. 2002 18 slides – some illegible
  12. ^ a b c d e f g h Till, Charles; Chang, Yoon Il (2011). Plentiful Energy: The Story of the Integral Fast Reactor, the Complex History of a Simple Reactor Technology, with Emphasis on Its Scientific Basis for Non-specialists. Charles E. Till and Yoon Il Chang. p. 114. ISBN 9781466384606.
  13. ^ a b c "Roger Blomquist of ANL (Argonne National Lab) on IFR (Integral Fast Reactor) @ TEAC6 . Stated at ~ 19–21 minutes". YouTube. 12 July 2014.
  14. ^ Nucleus-4-2007 pg 15 see SV/g chart, www.stralsakerhetsmyndigheten.se
  15. ^ a b c d e "An Introduction to Argonne National Laboratory's INTEGRAL FAST REACTOR (IFR) PROGRAM". 2007-10-09. Archived from the original on September 15, 2008. Retrieved 2014-01-24.
  16. ^ a b "Roger Blomquist of ANL (Argonne National Lab) on IFR (Integral Fast Reactor) @ TEAC6 . Stated at ~ 13 minutes". YouTube. 12 July 2014.
  17. ^ "Passively safe reactors rely on nature to keep them cool". Ne.anl.gov. 2013-12-13. Retrieved 2014-01-24.
  18. ^ a b c "Roger Blomquist of ANL (Argonne National Lab) on IFR (Integral Fast Reactor) @ TEAC6 . Stated at ~ 17:30". YouTube. 12 July 2014.
  19. ^ Sasahara, Akihiro; Matsumura, Tetsuo; Nicolaou, Giorgos; Papaioannou, Dimitri (April 2004). "Neutron and Gamma Ray Source Evaluation of LWR High Burn-up UO2 and MOX Spent Fuels". Journal of Nuclear Science and Technology. 41 (4): 448–456. doi:10.3327/jnst.41.448.
  20. ^ Professor David Ruzic (14 May 2019). "Dealing with the Used Fuel (Reprocessing)". YouTube. Archived from the original on 2021-12-12.
  21. ^ Janne Wallenius (2007-04-01). "Återanvändning av lång sluten bränslecykel möj" (PDF). Nucleus: 15. Archived from the original (PDF) on 2014-05-19.
  22. ^ a b c U.S. Congress (1994), p. 30.
  23. ^ a b Reduction of the Sodium-Void Coefficient of Reactivity by Using a Technetium Layer page 2
  24. ^ Warner, Ethan S.; Heath, Garvin A. Life Cycle Greenhouse Gas Emissions of Nuclear Electricity Generation: Systematic Review and Harmonization, Journal of Industrial Ecology, Yale University, published online April 17, 2012, doi:10.1111/j.1530-9290.2012.00472.x
  25. ^ Plus radium (element 88). While actually a sub-actinide, it immediately precedes actinium (89) and follows a three-element gap of instability after polonium (84) where no nuclides have half-lives of at least four years (the longest-lived nuclide in the gap is radon-222 with a half life of less than four days). Radium's longest lived isotope, at 1,600 years, thus merits the element's inclusion here.
  26. ^ Specifically from thermal neutron fission of uranium-235, e.g. in a typical nuclear reactor.
  27. ^ Milsted, J.; Friedman, A. M.; Stevens, C. M. (1965). "The alpha half-life of berkelium-247; a new long-lived isomer of berkelium-248". Nuclear Physics. 71 (2): 299. Bibcode:1965NucPh..71..299M. doi:10.1016/0029-5582(65)90719-4.
    "The isotopic analyses disclosed a species of mass 248 in constant abundance in three samples analysed over a period of about 10 months. This was ascribed to an isomer of Bk248 with a half-life greater than 9 [years]. No growth of Cf248 was detected, and a lower limit for the β half-life can be set at about 104 [years]. No alpha activity attributable to the new isomer has been detected; the alpha half-life is probably greater than 300 [years]."
  28. ^ This is the heaviest nuclide with a half-life of at least four years before the "sea of instability".
  29. ^ Excluding those "classically stable" nuclides with half-lives significantly in excess of 232Th; e.g., while 113mCd has a half-life of only fourteen years, that of 113Cd is eight quadrillion years.
  30. ^ Matthew L. Wald, Energy Dept. Told to Stop Collecting Nuclear Waste Fee, The New York Times, November 20, 2013, p. A20 (retrieved April 2, 2014)
  31. ^ "Historical video about the Integral Fast Reactor (IFR) concept. Uploaded by – Nuclear Engineering at Argonne". YouTube. 3 March 2014. Archived from the original on 2021-12-12.
  32. ^ Till and Chang, Charles E. and Yoon Il (2011). Plentiful Energy: The Story of the Integral Fast Reactor. CreateSpace. pp. 157–158. ISBN 978-1466384606. Archived from the original on 2011-06-05. Retrieved 2011-06-23.
  33. ^ Managing Military Uranium and Plutonium in the United States and the Former Soviet Union, Matthew Bunn and John P. Holdren, Annu. Rev. Energy Environ. 1997. 22:403–86
  34. ^ Categorization of Used Nuclear Fuel Inventory in Support of a Comprehensive National Nuclear Fuel Cycle Strategy. page 35 figure 21. Discharge isotopic composition of a pressurized water reactor fuel assembly with initial U-235 enrichment of 4.5 wt % that has accumulated 45 GWd/MTU burnup. Isotopic composition of used nuclear fuel as a function of burnup for a generic PWR fuel assembly.
  35. ^ WNA (March 2009). "Plutonium". World Nuclear Association. Archived from the original on 2010-03-30. Retrieved 2010-02-28.
  36. ^ U.S. Congress (1994), p. 34.
  37. ^ https://www.fas.org/nuke/intro/nuke/plutonium.htmBreeder reactors Archived 2013-07-01 at the Wayback Machine
  38. ^ U.S. Congress (1994), p. 32.
  39. ^ U.S. Congress (1994), p. 36.
  40. ^ Poplavskii, V. M.; Chebeskov, A. N.; Matveev, V. I. (2004-06-01). "BN-800 as a New Stage in the Development of Fast Sodium-Cooled Reactors". Atomic Energy. 96 (6): 386–390. doi:10.1023/B:ATEN.0000041204.70134.20. S2CID 96585192.
  41. ^ Fanning, Thomas H. (May 3, 2007). "Sodium as a Fast Reactor Coolant" (PDF). Ne.doe.gov. Office of Nuclear Energy | Department of Energy | University of Chicago, Argonne. Archived from the original (PDF) on 2013-01-13. Retrieved 2014-01-24.

Further reading

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