Nuclear power is the use of nuclear reactions to produce electricity. Nuclear power can be obtained from nuclear fission, nuclear decay and nuclear fusion reactions. Presently, the vast majority of electricity from nuclear power is produced by nuclear fission of uranium and plutonium in nuclear power plants. Nuclear decay processes are used in niche applications such as radioisotope thermoelectric generators in some space probes such as Voyager 2. Generating electricity from fusion power remains the focus of international research.
Civilian nuclear power supplied 2,586 terawatt hours (TWh) of electricity in 2019, equivalent to about 10% of global electricity generation, and was the second-largest low-carbon power source after hydroelectricity. As of January 2021,[update] there are 442 civilian fission reactors in the world, with a combined electrical capacity of 392 gigawatt (GW). There are also 53 nuclear power reactors under construction and 98 reactors planned, with a combined capacity of 60 GW and 103 GW, respectively. The United States has the largest fleet of nuclear reactors, generating over 800 TWh zero-emissions electricity per year with an average capacity factor of 92%. Most reactors under construction are generation III reactors in Asia.
Nuclear power has one of the lowest levels of fatalities per unit of energy generated compared to other energy sources. Coal, petroleum, natural gas and hydroelectricity each have caused more fatalities per unit of energy due to air pollution and accidents. Since its commercialization in the 1970s, nuclear power has prevented about 1.84 million air pollution-related deaths and the emission of about 64 billion tonnes of carbon dioxide equivalent that would have otherwise resulted from the burning of fossil fuels. Accidents in nuclear power plants include the Chernobyl disaster in the Soviet Union in 1986, the Fukushima Daiichi nuclear disaster in Japan in 2011, and the more contained Three Mile Island accident in the United States in 1979.
There is a debate about nuclear power. Proponents, such as the World Nuclear Association and Environmentalists for Nuclear Energy, contend that nuclear power is a safe, sustainable energy source that reduces carbon emissions. Nuclear power opponents, such as Greenpeace and NIRS, contend that nuclear power poses many threats to people and the environment.
The discovery of nuclear fission occurred in 1938 following over four decades of work on the science of radioactivity and the elaboration of new nuclear physics that described the components of atoms. Soon after the discovery of the fission process, it was realized that a fissioning nucleus can induce further nucleus fissions, thus inducing a self-sustaining chain reaction. Once this was experimentally confirmed in 1939, scientists in many countries petitioned their governments for support of nuclear fission research, just on the cusp of World War II, for the development of a nuclear weapon.
In the United States, these research efforts led to the creation of the first man-made nuclear reactor, the Chicago Pile-1, which achieved criticality on December 2, 1942. The reactor's development was part of the Manhattan Project, the Allied effort to create atomic bombs during World War II. It led to the building of larger single-purpose production reactors for the production of weapons-grade plutonium for use in the first nuclear weapons. The United States tested the first nuclear weapon in July 1945, the Trinity test, with the atomic bombings of Hiroshima and Nagasaki taking place one month later.
Despite the military nature of the first nuclear devices, the 1940s and 1950s were characterized by strong optimism for the potential of nuclear power to provide cheap and endless energy. Electricity was generated for the first time by a nuclear reactor on December 20, 1951, at the EBR-I experimental station near Arco, Idaho, which initially produced about 100 kW. In 1953, American President Dwight Eisenhower gave his "Atoms for Peace" speech at the United Nations, emphasizing the need to develop "peaceful" uses of nuclear power quickly. This was followed by the Atomic Energy Act of 1954 which allowed rapid declassification of U.S. reactor technology and encouraged development by the private sector.
First power generation
The first organization to develop practical nuclear power was the U.S. Navy, with the S1W reactor for the purpose of propelling submarines and aircraft carriers. The first nuclear-powered submarine, USS Nautilus, was put to sea in January 1954. The S1W reactor was a Pressurized Water Reactor. This design was chosen because it was simpler, more compact, and easier to operate compared to alternative designs, thus more suitable to be used in submarines. This decision would result in the PWR being the reactor of choice also for power generation, thus having a lasting impact on the civilian electricity market in the years to come.
On June 27, 1954, the Obninsk Nuclear Power Plant in the USSR became the world's first nuclear power plant to generate electricity for a power grid, producing around 5 megawatts of electric power. The world's first commercial nuclear power station, Calder Hall at Windscale, England was connected to the national power grid on 27 August 1956. In common with a number of other generation I reactors, the plant had the dual purpose of producing electricity and plutonium-239, the latter for the nascent nuclear weapons program in Britain.
The first major accident at a nuclear reactor occurred in 1961 at the SL-1, a U.S. Army experimental nuclear power reactor at the Idaho National Laboratory. An uncontrolled chain reaction resulted in a steam explosion which killed the three crew members and caused a meltdown. Another serious accident happened in 1968, when one of the two liquid-metal-cooled reactors on board the Soviet submarine K-27 underwent a fuel element failure, with the emission of gaseous fission products into the surrounding air, resulting in 9 crew fatalities and 83 injuries.
Expansion and first opposition
The total global installed nuclear capacity initially rose relatively quickly, rising from less than 1 gigawatt (GW) in 1960 to 100 GW in the late 1970s. During the 1970s and 1980s rising economic costs (related to extended construction times largely due to regulatory changes and pressure-group litigation) and falling fossil fuel prices made nuclear power plants then under construction less attractive. In the 1980s in the U.S. and 1990s in Europe, the flat electric grid growth and electricity liberalization also made the addition of large new baseload energy generators economically unattractive.
The 1973 oil crisis had a significant effect on countries, such as France and Japan, which had relied more heavily on oil for electric generation to invest in nuclear power. France would construct 25 nuclear power plants over the next 15 years, and as of 2019, 71% of French electricity was generated by nuclear power, the highest percentage by any nation in the world.
Some local opposition to nuclear power emerged in the United States in the early 1960s. In the late 1960s some members of the scientific community began to express pointed concerns. These anti-nuclear concerns related to nuclear accidents, nuclear proliferation, nuclear terrorism and radioactive waste disposal. In the early 1970s, there were large protests about a proposed nuclear power plant in Wyhl, Germany. The project was cancelled in 1975 the anti-nuclear success at Wyhl inspired opposition to nuclear power in other parts of Europe and North America.
By the mid-1970s anti-nuclear activism gained a wider appeal and influence, and nuclear power began to become an issue of major public protest. In some countries, the nuclear power conflict "reached an intensity unprecedented in the history of technology controversies". The increased public hostility to nuclear power led to a longer license procurement process, regulations and increased requirements for safety equipment, which made new construction much more expensive. In the United States, over 120 LWR reactor proposals were ultimately cancelled and the construction of new reactors ground to a halt. The 1979 accident at Three Mile Island with no fatalities, played a major part in the reduction in the number of new plant constructions in many countries.
Chernobyl and renaissance
During the 1980s one new nuclear reactor started up every 17 days on average. By the end of the decade, global installed nuclear capacity reached 300 GW. Since the late 1980s, new capacity additions slowed down significantly, with the installed nuclear capacity reaching 366 GW in 2005.
The 1986 Chernobyl disaster in the USSR, involving an RBMK reactor, altered the development of nuclear power and led to a greater focus on meeting international safety and regulatory standards. It is considered the worst nuclear disaster in history both in total casualties, with 56 direct deaths, and financially, with the cleanup and the cost estimated at 18 billion Soviet rubles (US$68 billion in 2019, adjusted for inflation). The international organization to promote safety awareness and the professional development of operators in nuclear facilities, the World Association of Nuclear Operators (WANO), was created as a direct outcome of the 1986 Chernobyl accident. The Chernobyl disaster played a major part in the reduction in the number of new plant constructions in the following years. Influenced by these events, Italy voted against nuclear power in a 1987 referendum, becoming the first country to completely phase out nuclear power in 1990.
In the early 2000s, nuclear energy was expecting a nuclear renaissance, an increase in the construction of new reactors, due to concerns about carbon dioxide emissions. During this period, newer generation III reactors, such as the EPR began construction, although encountering problems and delays, and going significantly over budget.
Net electrical generation by source and growth from 1980 to 2010. (Brown) – fossil fuels. (Red) – Fission. (Green) – "all renewables". In terms of energy generated between 1980 and 2010, the contribution from fission grew the fastest.
- Electricity production in France, showing the shift to nuclear power.thermofossilhydroelectricnuclearOther renewables
The rate of new reactor constructions essentially halted in the late 1980s. Increased capacity factor in existing reactors was primarily responsible for the continuing increase in electrical energy produced during this period.
Fukushima and current prospects
Plans for a nuclear renaissance were ended by another nuclear accident. The 2011 Fukushima Daiichi nuclear accident was caused by a large tsunami triggered by the Tōhoku earthquake, one of the largest earthquakes ever recorded. The Fukushima Daiichi Nuclear Power Plant suffered three core meltdowns due to failure of the emergency cooling system for lack of electricity supply. This resulted in the most serious nuclear accident since the Chernobyl disaster. The accident prompted a re-examination of nuclear safety and nuclear energy policy in many countries. Germany approved plans to close all its reactors by 2022, and many other countries reviewed their nuclear power programs. Following the disaster, Japan shut down all of its nuclear power reactors, some of them permanently, and in 2015 began a gradual process to restart the remaining 40 reactors, following safety checks and based on revised criteria for operations and public approval.
By 2015, the IAEA's outlook for nuclear energy had become more promising, recognizing the importance of low-carbon generation for mitigating climate change. As of 2015[update], the global trend was for new nuclear power stations coming online to be balanced by the number of old plants being retired. In 2016, the U.S. Energy Information Administration projected for its "base case" that world nuclear power generation would increase from 2,344 terawatt hours (TWh) in 2012 to 4,500 TWh in 2040. Most of the predicted increase was expected to be in Asia. As of 2018, there are over 150 nuclear reactors planned including 50 under construction. In January 2019, China had 45 reactors in operation, 13 under construction, and plans to build 43 more, which would make it the world's largest generator of nuclear electricity.
Nuclear power plants
Nuclear power plants are thermal power stations that generate electricity by harnessing the thermal energy released from nuclear fission. A fission nuclear power plant is generally composed of a nuclear reactor, in which the nuclear reactions generating heat take place; a cooling system, which removes the heat from inside the reactor; a steam turbine, which transforms the heat into mechanical energy; an electric generator, which transforms the mechanical energy into electrical energy.
When a neutron hits the nucleus of a uranium-235 or plutonium atom, it can split the nucleus into two smaller nuclei. The reaction is called nuclear fission. The fission reaction releases energy and neutrons. The released neutrons can hit other uranium or plutonium nuclei, causing new fission reactions, which release more energy and more neutrons. This is called a chain reaction. In most commercial reactors, the reaction rate is controlled by control rods that absorb excess neutrons. The controllability of nuclear reactors depends on the fact that a small fraction of neutrons resulting from fission are delayed. The time delay between the fission and the release of the neutrons slows down changes in reaction rates and gives time for moving the control rods to adjust the reaction rate.
Life cycle of nuclear fuel
The life cycle of nuclear fuel starts with uranium mining. The uranium ore is then converted into a compact ore concentrate form, known as yellowcake (U3O8), to facilitate transport. Fission reactors generally need uranium-235, a fissile isotope of uranium. The concentration of uranium-235 in natural uranium is very low, at about 0.7%. Some reactors can use this natural uranium as fuel, depending on their neutron economy. These reactors generally have graphite or heavy water moderators. For light water reactors, the most common type of reactor, this concentration is too low, and it must be increased by a process called uranium enrichment. In civilian light water reactors, uranium is typically enriched to 3.5-5% uranium-235. The uranium is then generally converted into uranium oxide (UO2), a ceramic, that is then compressively sintered into fuel pellets, a stack of which forms fuel rods of the proper composition and geometry for the particular reactor.
After some time in the reactor, the fuel will have reduced fissile material and increased fission products, until its use becomes impractical. At this point, the spent fuel will be moved to a spent fuel pool which provides cooling for the thermal heat and shielding for ionizing radiation. After several months or years, the spent fuel is radioactively and thermally cool enough to be moved to dry storage casks or reprocessed.
Uranium is a fairly common element in the Earth's crust: it is approximately as common as tin or germanium, and is about 40 times more common than silver. Uranium is present in trace concentrations in most rocks, dirt, and ocean water, but is generally economically extracted only where it is present in high concentrations. Uranium mining can be underground, open-pit, or in-situ leach mining. An increasing number of the highest output mines are remote underground operations, such as McArthur River uranium mine, in Canada, which by itself accounts for 13% of global production. As of 2011 the world's known resources of uranium, economically recoverable at the arbitrary price ceiling of US$130/kg, were enough to last for between 70 and 100 years. In 2007, the OECD estimated 670 years of economically recoverable uranium in total conventional resources and phosphate ores assuming the then-current use rate.
Light water reactors make relatively inefficient use of nuclear fuel, mostly using only the very rare uranium-235 isotope. Nuclear reprocessing can make this waste reusable, and newer reactors also achieve a more efficient use of the available resources than older ones. With a pure fast reactor fuel cycle with a burn up of all the uranium and actinides (which presently make up the most hazardous substances in nuclear waste), there is an estimated 160,000 years worth of Uranium in total conventional resources and phosphate ore at the price of 60–100 US$/kg.
Unconventional uranium resources also exist. Uranium is naturally present in seawater at a concentration of about 3 micrograms per liter, with 4.4 billion tons of uranium considered present in seawater at any time. In 2014 it was suggested that it would be economically competitive to produce nuclear fuel from seawater if the process was implemented at large scale. Over geological timescales, uranium extracted on an industrial scale from seawater would be replenished by both river erosion of rocks and the natural process of uranium dissolved from the surface area of the ocean floor, both of which maintain the solubility equilibria of seawater concentration at a stable level. Some commentators have argued that this strengthens the case for nuclear power to be considered a renewable energy.
The normal operation of nuclear power plants and facilities produce radioactive waste, or nuclear waste. This type of waste is also produced during plant decommissioning. There are two broad categories of nuclear waste: low-level waste and high-level waste. The first has low radioactivity and includes contaminated items such as clothing, which poses limited threat. High-level waste is mainly the spent fuel from nuclear reactors, which is very radioactive and must be cooled and then safely disposed of or reprocessed.
The most important waste stream from nuclear power reactors is spent nuclear fuel, which is considered high-level waste. For LWRs, spent fuel is typically composed of 95% uranium, 4% fission products, and about 1% transuranic actinides (mostly plutonium, neptunium and americium). The plutonium and other transuranics are responsible for the bulk of the long-term radioactivity, whereas the fission products are responsible for the bulk of the short-term radioactivity.
High-level waste requires treatment, management, and isolation from the environment. These operations present considerable challenges due to the extremely long periods these materials remain potentially hazardous to living organisms. This is due to long-lived fission products (LLFP), such as technetium-99 (half-life 220,000 years) and iodine-129 (half-life 15.7 million years). LLFP dominate the waste stream in terms of radioactivity, after the more intensely radioactive short-lived fission products (SLFPs) have decayed into stable elements, which takes approximately 300 years. After about 500 years, the waste becomes less radioactive than natural uranium ore. Commonly suggested methods to isolate LLFP waste from the biosphere include separation and transmutation, synroc treatments, or deep geological storage.
Thermal-neutron reactors, which presently constitute the majority of the world fleet, cannot burn up the reactor grade plutonium that is generated during the reactor operation. This limits the life of nuclear fuel to a few years. In some countries, such as the United States, spent fuel is classified in its entirety as a nuclear waste. In other countries, such as France, it is largely reprocessed to produce a partially recycled fuel, known as mixed oxide fuel or MOX. For spent fuel that does not undergo reprocessing, the most concerning isotopes are the medium-lived transuranic elements, which are led by reactor-grade plutonium (half-life 24,000 years). Some proposed reactor designs, such as the Integral Fast Reactor and molten salt reactors, can use as fuel the plutonium and other actinides in spent fuel from light water reactors, thanks to their fast fission spectrum. This offers a potentially more attractive alternative to deep geological disposal.
The thorium fuel cycle results in similar fission products, though creates a much smaller proportion of transuranic elements from neutron capture events within a reactor. Spent thorium fuel, although more difficult to handle than spent uranium fuel, may present somewhat lower proliferation risks.
The nuclear industry also produces a large volume of low-level waste, with low radioactivity, in the form of contaminated items like clothing, hand tools, water purifier resins, and (upon decommissioning) the materials of which the reactor itself is built. Low-level waste can be stored on-site until radiation levels are low enough to be disposed of as ordinary waste, or it can be sent to a low-level waste disposal site.
Waste relative to other types
In countries with nuclear power, radioactive wastes account for less than 1% of total industrial toxic wastes, much of which remains hazardous for long periods. Overall, nuclear power produces far less waste material by volume than fossil-fuel based power plants. Coal-burning plants, in particular, produce large amounts of toxic and mildly radioactive ash resulting from the concentration of naturally occurring radioactive materials in coal. A 2008 report from Oak Ridge National Laboratory concluded that coal power actually results in more radioactivity being released into the environment than nuclear power operation, and that the population effective dose equivalent from radiation from coal plants is 100 times that from the operation of nuclear plants. Although coal ash is much less radioactive than spent nuclear fuel by weight, coal ash is produced in much higher quantities per unit of energy generated. It is also released directly into the environment as fly ash, whereas nuclear plants use shielding to protect the environment from radioactive materials.
Nuclear waste volume is small compared to the energy produced. For example, at Yankee Rowe Nuclear Power Station, which generated 44 billion kilowatt hours of electricity when in service, its complete spent fuel inventory is contained within sixteen casks. It is estimated that to produce a lifetime supply of energy for a person at a western standard of living (approximately 3 GWh) would require on the order of the volume of a soda can of low enriched uranium, resulting in a similar volume of spent fuel generated.
Following interim storage in a spent fuel pool, the bundles of used fuel rod assemblies of a typical nuclear power station are often stored on site in dry cask storage vessels. Presently, waste is mainly stored at individual reactor sites and there are over 430 locations around the world where radioactive material continues to accumulate.
Disposal of nuclear waste is often considered the most politically divisive aspect in the lifecycle of a nuclear power facility. With the lack of movement of nuclear waste in the 2 billion year old natural nuclear fission reactors in Oklo, Gabon being cited as "a source of essential information today." Experts suggest that centralized underground repositories which are well-managed, guarded, and monitored, would be a vast improvement. There is an "international consensus on the advisability of storing nuclear waste in deep geological repositories". With the advent of new technologies, other methods including horizontal drillhole disposal into geologically inactive areas have been proposed.
There are no commercial scale purpose built underground high-level waste repositories in operation. However, in Finland the Onkalo spent nuclear fuel repository of the Olkiluoto Nuclear Power Plant is under construction as of 2015.
Most thermal-neutron reactors run on a once-through nuclear fuel cycle, mainly due to the low price of fresh uranium. However, many reactors are also fueled with recycled fissionable materials that remain in spent nuclear fuel. The most common fissionable material that is recycled is the reactor-grade plutonium (RGPu) that is extracted from spent fuel, it is mixed with uranium oxide and fabricated into mixed-oxide or MOX fuel. Because thermal LWRs remain the most common reactor worldwide, this type of recycling is the most common. It is considered to increase the sustainability of the nuclear fuel cycle, reduce the attractiveness of spent fuel to theft, and lower the volume of high level nuclear waste. Spent MOX fuel cannot generally be recycled for use in thermal-neutron reactors. This issue does not affect fast-neutron reactors, which are therefore preferred in order to achieve the full energy potential of the original uranium.
The main constituent of spent fuel from LWRs is slightly enriched uranium. This can be recycled into reprocessed uranium (RepU), which can be used in a fast reactor, used directly as fuel in CANDU reactors, or re-enriched for another cycle through an LWR. Re-enriching of reprocessed uranium is common in France and Russia. Reprocessed uranium is also safer in terms of nuclear proliferation potential.
Reprocessing has the potential to recover up to 95% of the uranium and plutonium fuel in spent nuclear fuel, as well as reduce long-term radioactivity within the remaining waste. However, reprocessing has been politically controversial because of the potential for nuclear proliferation and varied perceptions of increasing the vulnerability to nuclear terrorism. Reprocessing also leads to higher fuel cost compared to the once-through fuel cycle. While reprocessing reduces the volume of high-level waste, it does not reduce the fission products that are the primary causes of residual heat generation and radioactivity for the first few centuries outside the reactor. Thus, reprocessed waste still requires an almost identical treatment for the initial first few hundred years.
Reprocessing of civilian fuel from power reactors is currently done in France, the United Kingdom, Russia, Japan, and India. In the United States, spent nuclear fuel is currently not reprocessed. The La Hague reprocessing facility in France has operated commercially since 1976 and is responsible for half the world's reprocessing as of 2010. It produces MOX fuel from spent fuel derived from several countries. More than 32,000 tonnes of spent fuel had been reprocessed as of 2015, with the majority from France, 17% from Germany, and 9% from Japan.
Breeding is the process of converting non-fissile material into fissile material that can be used as nuclear fuel. The non-fissile material that can be used for this process is called fertile material, and constitute the vast majority of current nuclear waste. This breeding process occurs naturally in breeder reactors. As opposed to light water thermal-neutron reactors, which use uranium-235 (0.7% of all natural uranium), fast-neutron breeder reactors use uranium-238 (99.3% of all natural uranium) or thorium. A number of fuel cycles and breeder reactor combinations are considered to be sustainable or renewable sources of energy. In 2006 it was estimated that with seawater extraction, there was likely five billion years' worth of uranium resources for use in breeder reactors.
Breeder technology has been used in several reactors, but as of 2006, the high cost of reprocessing fuel safely requires uranium prices of more than US$200/kg before becoming justified economically. Breeder reactors are however being developed for their potential to burn up all of the actinides (the most active and dangerous components) in the present inventory of nuclear waste, while also producing power and creating additional quantities of fuel for more reactors via the breeding process. As of 2017, there are two breeders producing commercial power, BN-600 reactor and the BN-800 reactor, both in Russia. The Phénix breeder reactor in France was powered down in 2009 after 36 years of operation. Both China and India are building breeder reactors. The Indian 500 MWe Prototype Fast Breeder Reactor is in the commissioning phase, with plans to build more.
Another alternative to fast-neutron breeders are thermal-neutron breeder reactors that use uranium-233 bred from thorium as fission fuel in the thorium fuel cycle. Thorium is about 3.5 times more common than uranium in the Earth's crust, and has different geographic characteristics. India's three-stage nuclear power programme features the use of a thorium fuel cycle in the third stage, as it has abundant thorium reserves but little uranium.
Nuclear decommissioning is the process of dismantling a nuclear facility to the point that it no longer requires measures for radiation protection, returning the facility and its parts to a safe enough level to be entrusted for other uses. Due to the presence of radioactive materials, nuclear decommissioning presents technical and economic challenges. The costs of decommissioning are generally spread over the lifetime of a facility and saved in a decommissioning fund.
Installed capacity and electricity production
Civilian nuclear power supplied 2,586 terawatt hours (TWh) of electricity in 2019, equivalent to about 10% of global electricity generation, and was the second largest low-carbon power source after hydroelectricity. Since electricity accounts for about 25% of world energy consumption, nuclear power's contribution to global energy was about 2.5% in 2011. This is a little more than the combined global electricity production from wind, solar, biomass and geothermal power, which together provided 2% of global final energy consumption in 2014. Nuclear power's share of global electricity production has fallen from 16.5% in 1997, in large part because the economics of nuclear power have become more difficult.
As of January 2021,[update] there are 442 civilian fission reactors in the world, with a combined electrical capacity of 392 gigawatt (GW). There are also 53 nuclear power reactors under construction and 98 reactors planned, with a combined capacity of 60 GW and 103 GW, respectively. The United States has the largest fleet of nuclear reactors, generating over 800 TWh per year with an average capacity factor of 92%. Most reactors under construction are generation III reactors in Asia.
Regional differences in the use of nuclear power are large. The United States produces the most nuclear energy in the world, with nuclear power providing 20% of the electricity it consumes, while France produces the highest percentage of its electrical energy from nuclear reactors – 71% in 2019. In the European Union, nuclear power provides 26% of the electricity as of 2018. Nuclear power is the single largest low-carbon electricity source in the United States, and accounts for two-thirds of the European Union's low-carbon electricity.Nuclear energy policy differs among European Union countries, and some, such as Austria, Estonia, Ireland and Italy, have no active nuclear power stations.
In addition, there were approximately 140 naval vessels using nuclear propulsion in operation, powered by about 180 reactors. These include military and some civilian ships, such as nuclear-powered icebreakers.
International research is continuing into additional uses of process heat such as hydrogen production (in support of a hydrogen economy), for desalinating sea water, and for use in district heating systems.
The economics of new nuclear power plants is a controversial subject, since there are diverging views on this topic, and multibillion-dollar investments depend on the choice of an energy source. Nuclear power plants typically have high capital costs for building the plant, but low fuel costs. For this reason, comparison with other power generation methods is strongly dependent on assumptions about construction timescales and capital financing for nuclear plants. The high cost of construction is one of the biggest challenges for nuclear power plants. A new 1,100 MW plant is estimated to cost between $6 billion to $9 billion. Nuclear power cost trends show large disparity by nation, design, build rate and the establishment of familiarity in expertise. The only two nations for which data is available that saw cost decreases in the 2000s were India and South Korea.
Analysis of the economics of nuclear power must also take into account who bears the risks of future uncertainties. As of 2010, all operating nuclear power plants have been developed by state-owned or regulated electric utility monopolies. Many countries have since liberalized the electricity market where these risks, and the risk of cheaper competitors emerging before capital costs are recovered, are borne by plant suppliers and operators rather than consumers, which leads to a significantly different evaluation of the economics of new nuclear power plants.
The levelized cost of electricity from a new nuclear power plant is estimated to be 69 USD/MWh, according to an analysis by the International Energy Agency and the OECD Nuclear Energy Agency. This represents the median cost estimate for an nth-of-a-kind nuclear power plant to be completed in 2025, at a discount rate of 7%. Nuclear power was found to be the least-cost option among dispatchable technologies. Variable renewables can generate cheaper electricity: the median cost of onshore wind power was estimated to be 50 USD/MWh, and utility-scale solar power 56 USD/MWh. At the assumed CO2 emission cost of USD 30 per ton, power from coal (88 USD/MWh) and gas (71 USD/MWh) is more expensive than low-carbon technologies. Electricity from long-term operation of nuclear power plants by lifetime extension was found the be the least-cost option, at 32 USD/MWh. Measures to mitigate global warming, such as a carbon tax or carbon emissions trading, may favor the economics of nuclear power.
New small modular reactors, such as those developed by NuScale Power, are aimed at reducing the investment costs for new construction by making the reactors smaller and modular, so that they can be built in a factory.
Certain designs had considerable early positive economics, such as the CANDU, which realized much higher capacity factor and reliability when compared to generation II light water reactors up to the 1990s.
Nuclear power plants, though capable of some grid-load following, are typically run as much as possible to keep the cost of the generated electrical energy as low as possible, supplying mostly base-load electricity. Due to the on-line refueling reactor design, PHWRs (of which the CANDU design is a part) continue to hold many world record positions for longest continual electricity generation, often over 800 days. The specific record as of 2019 is held by a PHWR at Kaiga Atomic Power Station, generating electricity continuously for 962 days.
Use in space
The most common use of nuclear power in space is the use of radioisotope thermoelectric generators, which use radioactive decay to generate power. These power generators are relatively small scale (few kW), and they are mostly used to power space missions and experiments for long periods where solar power is not available in sufficient quantity, such as in the Voyager 2 space probe. A few space vehicles have been launched using nuclear reactors: 34 reactors belong to the Soviet RORSAT series and one was the American SNAP-10A.
Nuclear power plants have three unique characteristics that affect their safety, as compared to other power plants. Firstly, intensely radioactive materials are present in a nuclear reactor. Their release to the environment could be hazardous. Secondly, the fission products, which make up most of the intensely radioactive substances in the reactor, continue to generate a significant amount of decay heat even after the fission chain reaction has stopped. If the heat cannot be removed from the reactor, the fuel rods may overheat and release radioactive materials. Thirdly, a criticality accident (a rapid increase of the reactor power) is possible in certain reactor designs if the chain reaction cannot be controlled. These three characteristics have to be taken into account when designing nuclear reactors.
All modern reactors are designed so that an uncontrolled increase of the reactor power is prevented by natural feedback mechanisms, a concept known as negative void coefficient of reactivity. If the temperature or the amount of steam in the reactor increases, the fission rate inherently decreases. The chain reaction can also be manually stopped by inserting control rods into the reactor core. Emergency core cooling systems (ECCS) can remove the decay heat from the reactor if normal cooling systems fail. If the ECCS fails, multiple physical barriers limit the release of radioactive materials to the environment even in the case of an accident. The last physical barrier is the large containment building.
With a death rate of 0.07 per TWh, nuclear power is the safest energy source per unit of energy generated. Energy produced by coal, petroleum, natural gas and hydropower has caused more deaths per unit of energy generated due to air pollution and energy accidents. This is found when comparing the immediate deaths from other energy sources to both the immediate and the latent, or predicted, indirect cancer deaths from nuclear energy accidents. When the direct and indirect fatalities (including fatalities resulting from the mining and air pollution) from nuclear power and fossil fuels are compared, the use of nuclear power has been calculated to have prevented about 1.8 million deaths between 1971 and 2009, by reducing the proportion of energy that would otherwise have been generated by fossil fuels. Following the 2011 Fukushima nuclear disaster, it has been estimated that if Japan had never adopted nuclear power, accidents and pollution from coal or gas plants would have caused more lost years of life.
Serious impacts of nuclear accidents are often not directly attributable to radiation exposure, but rather social and psychological effects. Evacuation and long-term displacement of affected populations created problems for many people, especially the elderly and hospital patients. Forced evacuation from a nuclear accident may lead to social isolation, anxiety, depression, psychosomatic medical problems, reckless behavior, and suicide. A comprehensive 2005 study on the aftermath of the Chernobyl disaster concluded that the mental health impact is the largest public health problem caused by the accident.Frank N. von Hippel, an American scientist, commented that a disproportionate fear of ionizing radiation (radiophobia) could have long-term psychological effects on the population of contaminated areas following the Fukushima disaster. In January 2015, the number of Fukushima evacuees was around 119,000, compared with a peak of around 164,000 in June 2012.
Accidents and attacks
Some serious nuclear and radiation accidents have occurred. The severity of nuclear accidents is generally classified using the International Nuclear Event Scale (INES) introduced by the International Atomic Energy Agency (IAEA). The scale ranks anomalous events or accidents on a scale from 0 (a deviation from normal operation that poses no safety risk) to 7 (a major accident with widespread effects). There have been 3 accidents of level 5 or higher in the civilian nuclear power industry, two of which, the Chernobyl accident and the Fukushima accident, are ranked at level 7.
The Chernobyl accident in 1986 caused approximately 50 deaths from direct and indirect effects, and some temporary serious injuries from acute radiation syndrome. The future predicted mortality from increases in cancer rates is estimated at about 4000 in the decades to come. The Fukushima Daiichi nuclear accident was caused by the 2011 Tohoku earthquake and tsunami. The accident has not caused any radiation-related deaths but resulted in radioactive contamination of surrounding areas. The difficult cleanup operation is expected to cost tens of billions of dollars over 40 or more years. The Three Mile Island accident in 1979 was a smaller scale accident, rated at INES level 5. There were no direct or indirect deaths caused by the accident.
The impact of nuclear accidents is controversial. According to Benjamin K. Sovacool, fission energy accidents ranked first among energy sources in terms of their total economic cost, accounting for 41 percent of all property damage attributed to energy accidents. Another analysis found that coal, oil, liquid petroleum gas and hydroelectric accidents (primarily due to the Banqiao Dam disaster) have resulted in greater economic impacts than nuclear power accidents. The study compares latent cancer deaths attributable to nuclear with immediate deaths from other energy sources per unit of energy generated, and does not include fossil fuel related cancer and other indirect deaths created by the use of fossil fuel consumption in its "severe accident" (an accident with more than 5 fatalities) classification.
Nuclear power works under an insurance framework that limits or structures accident liabilities in accordance with national and international conventions. It is often argued that this potential shortfall in liability represents an external cost not included in the cost of nuclear electricity. This cost is small, amounting to about 0.1% of the levelized cost of electricity, according to a study by the Congressional Budget Office in the United States. These beyond-regular insurance costs for worst-case scenarios are not unique to nuclear power. Hydroelectric power plants are similarly not fully insured against a catastrophic event such as dam failures. For example, the failure of the Banqiao Dam caused the death of an estimated 30,000 to 200,000 people, and 11 million people lost their homes. As private insurers base dam insurance premiums on limited scenarios, major disaster insurance in this sector is likewise provided by the state.
Attacks and sabotage
Terrorists could target nuclear power plants in an attempt to release radioactive contamination into the community. The United States 9/11 Commission has said that nuclear power plants were potential targets originally considered for the September 11, 2001 attacks. An attack on a reactor's spent fuel pool could also be serious, as these pools are less protected than the reactor core. The release of radioactivity could lead to thousands of near-term deaths and greater numbers of long-term fatalities.
In the United States, the NRC carries out "Force on Force" (FOF) exercises at all nuclear power plant sites at least once every three years. In the United States, plants are surrounded by a double row of tall fences which are electronically monitored. The plant grounds are patrolled by a sizeable force of armed guards.
Insider sabotage is also a threat because insiders can observe and work around security measures. Successful insider crimes depended on the perpetrators' observation and knowledge of security vulnerabilities. A fire caused 5–10 million dollars worth of damage to New York's Indian Point Energy Center in 1971. The arsonist turned out to be a plant maintenance worker.
Nuclear proliferation is the spread of nuclear weapons, fissionable material, and weapons-related nuclear technology to states that do not already possess nuclear weapons. Many technologies and materials associated with the creation of a nuclear power program have a dual-use capability, in that they can also be used to make nuclear weapons. For this reason, nuclear power presents proliferation risks.
Nuclear power program can become a route leading to a nuclear weapon. An example of this is the concern over Iran's nuclear program. The re-purposing of civilian nuclear industries for military purposes would be a breach of the Non-proliferation treaty, to which 190 countries adhere. As of April 2012, there are thirty one countries that have civil nuclear power plants, of which nine have nuclear weapons. The vast majority of these nuclear weapons states have produced weapons before commercial nuclear power stations.
A fundamental goal for global security is to minimize the nuclear proliferation risks associated with the expansion of nuclear power. The Global Nuclear Energy Partnership was an international effort to create a distribution network in which developing countries in need of energy would receive nuclear fuel at a discounted rate, in exchange for that nation agreeing to forgo their own indigenous development of a uranium enrichment program. The France-based Eurodif/European Gaseous Diffusion Uranium Enrichment Consortium is a program that successfully implemented this concept, with Spain and other countries without enrichment facilities buying a share of the fuel produced at the French-controlled enrichment facility, but without a transfer of technology. Iran was an early participant from 1974 and remains a shareholder of Eurodif via Sofidif.
A 2009 United Nations report said that:
the revival of interest in nuclear power could result in the worldwide dissemination of uranium enrichment and spent fuel reprocessing technologies, which present obvious risks of proliferation as these technologies can produce fissile materials that are directly usable in nuclear weapons.
On the other hand, power reactors can also reduce nuclear weapons arsenals when military-grade nuclear materials are reprocessed to be used as fuel in nuclear power plants. The Megatons to Megawatts Program is considered the single most successful non-proliferation program to date. Up to 2005, the program had processed $8 billion of high enriched, weapons-grade uranium into low enriched uranium suitable as nuclear fuel for commercial fission reactors by diluting it with natural uranium. This corresponds to the elimination of 10,000 nuclear weapons. For approximately two decades, this material generated nearly 10 percent of all the electricity consumed in the United States, or about half of all U.S. nuclear electricity, with a total of around 7,000 TWh of electricity produced. In total it is estimated to have cost $17 billion, a "bargain for US ratepayers", with Russia profiting $12 billion from the deal. Much needed profit for the Russian nuclear oversight industry, which after the collapse of the Soviet economy, had difficulties paying for the maintenance and security of the Russian Federations highly enriched uranium and warheads. The Megatons to Megawatts Program was hailed as a major success by anti-nuclear weapon advocates as it has largely been the driving force behind the sharp reduction in the number of nuclear weapons worldwide since the cold war ended. However, without an increase in nuclear reactors and greater demand for fissile fuel, the cost of dismantling and down blending has dissuaded Russia from continuing their disarmament. As of 2013 Russia appears to not be interested in extending the program.
Nuclear power is one of the leading low carbon power generation methods of producing electricity, and in terms of total life-cycle greenhouse gas emissions per unit of energy generated, has emission values comparable to or lower than renewable energy.
A 2014 analysis of the carbon footprint literature by the Intergovernmental Panel on Climate Change (IPCC) reported that the embodied total life-cycle emission intensity of nuclear power has a median value of 12 g CO
2eq/kWh, which is the lowest among all commercial baseload energy sources. This is contrasted with coal and natural gas at 820 and 490 g CO
2 eq/kWh. From the beginning of its commercialization in the 1970s, nuclear power has prevented the emission of about 64 billion tonnes of carbon dioxide equivalent that would have otherwise resulted from the burning of fossil fuels in thermal power stations.
The average dose from natural background radiation is 2.4 millisievert per year (mSv/a) globally. It varies between 1 mSv/a and 13 mSv/a, depending mostly on the geology of the location. According to the United Nations (UNSCEAR), regular nuclear power plant operations, including the nuclear fuel cycle, increases this amount by 0.0002 mSv/a of public exposure as a global average. The average dose from operating nuclear power plants to the local populations around them is less than 0.0001 mSv/a. For comparison, the average dose to those living within 50 miles of a coal power plant is over three times this dose, at 0.0003 mSv/a.
Chernobyl resulted in the most affected surrounding populations and male recovery personnel receiving an average initial 50 to 100 mSv over a few hours to weeks, while the remaining global legacy of the worst nuclear power plant accident in average exposure is 0.002 mSv/a and is continually dropping at the decaying rate, from the initial high of 0.04 mSv per person averaged over the entire populace of the Northern Hemisphere in the year of the accident in 1986.
Debate on nuclear power
Proponents of nuclear energy regard it as a sustainable energy source that reduces carbon emissions and increases energy security by decreasing dependence on imported energy sources. M. King Hubbert, who popularized the concept of peak oil, saw oil as a resource that would run out and considered nuclear energy its replacement. Proponents also claim that the present quantity of nuclear waste is small and can be reduced through the latest technology of newer reactors and that the operational safety record of fission-electricity is unparalleled. Other commentators who have questioned the links between the anti-nuclear movement and the fossil fuel industry.
Kharecha and Hansen estimated that "global nuclear power has prevented an average of 1.84 million air pollution-related deaths and 64 gigatonnes of CO2-equivalent (GtCO2-eq) greenhouse gas (GHG) emissions that would have resulted from fossil fuel burning" and, if continued, it could prevent up to 7 million deaths and 240 GtCO2-eq emissions by 2050.
Opponents believe that nuclear power poses many threats to people and the environment such as the risk of nuclear weapons proliferation and terrorism. They also contend that reactors are complex machines where many things can and have gone wrong. In years past, they also argued that when all the energy-intensive stages of the nuclear fuel chain are considered, from uranium mining to nuclear decommissioning, nuclear power is neither a low-carbon nor an economical electricity source.
Arguments of economics and safety are used by both sides of the debate.
Comparison with renewable energy
Slowing global warming requires a transition to a low-carbon economy, mainly by burning far less fossil fuel. Limiting global warming to 1.5 degrees C is technically possible if no new fossil fuel power plants are built from 2019. This has generated considerable interest and dispute in determining the best path forward to rapidly replace fossil-based fuels in the global energy mix, with intense academic debate. Sometimes the IEA says that countries without nuclear should develop it as well as their renewable power.
Several studies suggest that it might be theoretically possible to cover a majority of world energy generation with new renewable sources. The Intergovernmental Panel on Climate Change (IPCC) has said that if governments were supportive, renewable energy supply could account for close to 80% of the world's energy use by 2050. While in developed nations the economically feasible geography for new hydropower is lacking, with every geographically suitable area largely already exploited, proponents of wind and solar energy claim these resources alone could eliminate the need for nuclear power.
Nuclear power is comparable to, and in some cases lower, than many renewable energy sources in terms of lives lost per unit of electricity delivered. Nuclear reactors also produce a much smaller volume of waste, although much more toxic. A nuclear plant also needs to be disassembled and removed and much of the disassembled nuclear plant needs to be stored as low-level nuclear waste for a few decades.
Speed of transition and investment needed
Analysis in 2015 by professor Barry W. Brook and colleagues found that nuclear energy could displace or remove fossil fuels from the electric grid completely within 10 years. This finding was based on the historically modest and proven rate at which nuclear energy was added in France and Sweden during their building programs in the 1980s.
In a similar analysis, Brook had earlier determined that 50% of all global energy, including transportation synthetic fuels etc., could be generated within approximately 30 years if the global nuclear fission build rate was identical to historical proven installation rates calculated in GW per year per unit of global GDP (GW/year/$). This is in contrast to the conceptual studies for 100% renewable energy systems, which would require an orders of magnitude more costly global investment per year, which has no historical precedent. These renewable scenarios would also need far greater land devoted to wind, wave and solar projects, and the inherent assumption that energy use will decrease in the future. As Brook notes, the "principal limitations on nuclear fission are not technical, economic or fuel-related, but are instead linked to complex issues of societal acceptance, fiscal and political inertia, and inadequate critical evaluation of the real-world constraints facing [the other] low-carbon alternatives."
Seasonal energy storage requirements
Some analysts argue that conventional renewable energy sources, wind and solar do not offer the scalability necessary for a large-scale decarbonization of the electric grid, mainly due to intermittency-related considerations. A 2018 analysis by MIT argued that, to be much more cost-effective as they approach deep decarbonization, electricity systems should integrate baseload low carbon resources, such as nuclear, with renewables, storage and demand response.
In some places which aim to phase out fossil fuels in favor of low carbon power, such as the United Kingdom, seasonal energy storage is difficult to provide, so having renewables supply over 60% of electricity might be expensive. As of 2019[update] whether interconnectors or new nuclear would be more expensive than taking renewables over 60% is still being researched and debated.
Nuclear power stations require approximately one square kilometer of land per typical reactor. Environmentalists and conservationists have begun to question the global renewable energy expansion proposals, as they are opposed to the frequently controversial use of once forested land to situate renewable energy systems. Seventy five academic conservationists signed a letter, suggesting a more effective policy to mitigate climate change involving the reforestation of this land proposed for renewable energy production, to its prior natural landscape, by means of the native trees that previously inhabited it, in tandem with the lower land use footprint of nuclear energy, as the path to assure both the commitment to carbon emission reductions and to succeed with landscape rewilding programs that are part of the global native species protection and re-introduction initiatives.
These scientists argue that government commitments to increase renewable energy usage while simultaneously making commitments to expand areas of biological conservation are two competing land-use outcomes, in opposition to one another, that are increasingly coming into conflict. With the existing protected areas for conservation at present regarded as insufficient to safeguard biodiversity "the conflict for space between energy production and habitat will remain one of the key future conservation issues to resolve."
Historic effect on carbon emissions
An analysis by Benjamin Sovacool of 123 countries over 25 years published in 2020 concluded that adoption of renewables tends to be associated with significantly lower carbon emissions while larger-scale national nuclear fission energy attachments is not. Tensions between these two national energy development strategies can reduce their effectiveness in terms of climate change mitigation due to factors such as different infrastructure requirements and negative association between the scales of national nuclear and renewables attachments. However, an analysis of the same data by another group of scientists came to a different conclusion: "nuclear power and renewable energy are both associated with lower per capita CO2 emissions with effects of similar magnitude". Societal allocation of resources to nuclear energy production-related efforts may compete with resource allocation for research, development, construction, expansion and improvement of renewables-related technologies and structures such as energy grid systems, energy conservation technology and methods, efficient energy use, energy efficiency, energy storage, load balancing, sustainable design, novel renewables technologies – such as of the hydrogen economy – and smart grids.
Advanced fission reactor designs
Current fission reactors in operation around the world are second or third generation systems, with most of the first-generation systems having been already retired. Research into advanced generation IV reactor types was officially started by the Generation IV International Forum (GIF) based on eight technology goals, including to improve economics, safety, proliferation resistance, natural resource utilization and the ability to consume existing nuclear waste in the production of electricity. Most of these reactors differ significantly from current operating light water reactors, and are expected to be available for commercial construction after 2030.
Hybrid nuclear fusion-fission
Hybrid nuclear power is a proposed means of generating power by the use of a combination of nuclear fusion and fission processes. The concept dates to the 1950s and was briefly advocated by Hans Bethe during the 1970s, but largely remained unexplored until a revival of interest in 2009, due to delays in the realization of pure fusion. When a sustained nuclear fusion power plant is built, it has the potential to be capable of extracting all the fission energy that remains in spent fission fuel, reducing the volume of nuclear waste by orders of magnitude, and more importantly, eliminating all actinides present in the spent fuel, substances which cause security concerns.
Nuclear fusion reactions have the potential to be safer and generate less radioactive waste than fission. These reactions appear potentially viable, though technically quite difficult and have yet to be created on a scale that could be used in a functional power plant. Fusion power has been under theoretical and experimental investigation since the 1950s.
Several experimental nuclear fusion reactors and facilities exist. The largest and most ambitious international nuclear fusion project currently in progress is ITER, a large tokamak under construction in France. ITER is planned to pave the way for commercial fusion power by demonstrating self-sustained nuclear fusion reactions with positive energy gain. Construction of the ITER facility began in 2007, but the project has run into many delays and budget overruns. The facility is now not expected to begin operations until the year 2027–11 years after initially anticipated. A follow on commercial nuclear fusion power station, DEMO, has been proposed. There are also suggestions for a power plant based upon a different fusion approach, that of an inertial fusion power plant.
Fusion-powered electricity generation was initially believed to be readily achievable, as fission-electric power had been. However, the extreme requirements for continuous reactions and plasma containment led to projections being extended by several decades. In 2010, more than 60 years after the first attempts, commercial power production was still believed to be unlikely before 2050.
- Dr. Elizabeth Ervin. "Nuclear Energy: Statistics" (PDF).
- "Reactors: Modern-Day Alchemy - Argonne's Nuclear Science and Technology Legacy". www.ne.anl.gov. Retrieved 24 March 2021.
- Wellerstein, Alex (2008). "Inside the atomic patent office". Bulletin of the Atomic Scientists. 64 (2): 26–31. Bibcode:2008BuAtS..64b..26W. doi:10.2968/064002008.
- "The Einstein Letter". Atomicarchive.com. Retrieved 2013-06-22.
- "Nautilus (SSN-571)". US Naval History and Heritage Command (US Navy).
- Wendt, Gerald; Geddes, Donald Porter (1945). The Atomic Age Opens. New York: Pocket Books.
- "Reactors Designed by Argonne National Laboratory: Fast Reactor Technology". U.S. Department of Energy, Argonne National Laboratory. 2012. Retrieved 2012-07-25.
- "Reactor Makes Electricity". Popular Mechanics. March 1952. p. 105.
- "50 Years of Nuclear Energy" (PDF). International Atomic Energy Agency. Retrieved 2006-11-09.
- "STR (Submarine Thermal Reactor) in "Reactors Designed by Argonne National Laboratory: Light Water Reactor Technology Development"". U.S. Department of Energy, Argonne National Laboratory. 2012. Retrieved 2012-07-25.
- Rockwell, Theodore (1992). The Rickover Effect. Naval Institute Press. p. 162. ISBN 978-1-55750-702-0.
- "From Obninsk Beyond: Nuclear Power Conference Looks to Future". International Atomic Energy Agency. 2004-06-23. Retrieved 2006-06-27.
- Hill, C. N. (2013). An atomic empire : a technical history of the rise and fall of the British atomic energy programme. London: Imperial College Press. ISBN 9781908977434.
- IDO-19313: Additional Analysis of the SL-1 Excursion Archived 2011-09-27 at the Wayback Machine Final Report of Progress July through October 1962, November 21, 1962, Flight Propulsion Laboratory Department, General Electric Company, Idaho Falls, Idaho, U.S. Atomic Energy Commission, Division of Technical Information.
- McKeown, William (2003). Idaho Falls: The Untold Story of America's First Nuclear Accident. Toronto: ECW Press. ISBN 978-1-55022-562-4.
- Johnston, Robert (2007-09-23). "Deadliest radiation accidents and other events causing radiation casualties". Database of Radiological Incidents and Related Events.
- Bernard L. Cohen (1990). The Nuclear Energy Option: An Alternative for the 90s. New York: Plenum Press. ISBN 978-0-306-43567-6.
- Sharon Beder (2006). "The Japanese Situation, English version of conclusion of Sharon Beder, "Power Play: The Fight to Control the World's Electricity"". Soshisha, Japan.
- Palfreman, Jon (1997). "Why the French Like Nuclear Energy". Frontline. Public Broadcasting Service. Retrieved 25 August 2007.
- Rene de Preneuf. "Nuclear Power in France – Why does it Work?". Archived from the original on 13 August 2007. Retrieved 25 August 2007.
- "Nuclear Share of Electricity Generation in 2019". Power Reactor Information System. International Atomic Energy Agency. Retrieved 2021-01-09.
- Garb Paula (1999). "Review of Critical Masses : Opposition to Nuclear Power in California, 1958-1978". Journal of Political Ecology. 6.
- Rüdig, Wolfgang, ed. (1990). Anti-nuclear Movements: A World Survey of Opposition to Nuclear Energy. Detroit, MI: Longman Current Affairs. p. 1. ISBN 978-0-8103-9000-3.
- Brian Martin (2007). "Opposing nuclear power: past and present". Social Alternatives. 26 (2): 43–47.
- Stephen Mills; Roger Williams (1986). Public acceptance of new technologies : an international review. London: Croom Helm. pp. 375–376. ISBN 9780709943198.
- Robert Gottlieb (2005). Forcing the Spring: The Transformation of the American Environmental Movement, Revised Edition, Island Press, p. 237.
- Falk, Jim (1982). Global Fission: The Battle Over Nuclear Power. Melbourne: Oxford University Press. pp. 95–96. ISBN 978-0-19-554315-5.
- Walker, J. Samuel (2004). Three Mile Island: A Nuclear Crisis in Historical Perspective (Berkeley: University of California Press), pp. 10–11.
- Herbert P. Kitschelt (1986). "Political Opportunity and Political Protest: Anti-Nuclear Movements in Four Democracies" (PDF). British Journal of Political Science. 16 (1): 57. doi:10.1017/s000712340000380x.
- Herbert P. Kitschelt (1986). "Political Opportunity and Political Protest: Anti-Nuclear Movements in Four Democracies" (PDF). British Journal of Political Science. 16 (1): 71. doi:10.1017/s000712340000380x.
- "Costs of Nuclear Power Plants – What Went Wrong?". www.phyast.pitt.edu.
- Vance Ginn; Elliott Raia (August 18, 2017). "nuclear energy may soon be free from its tangled regulatory web". Washington Examiner.
- "Nuclear Power: Outlook for New U.S. Reactors" (PDF). p. 3.
- Cook, James (1985-02-11). "Nuclear Follies". Forbes Magazine.
- Thorpe, M.S., Gary S. (2015). AP Environmental Science, 6th ed. Barrons Educational Series. ISBN 978-1-4380-6728-5. ISBN 1-4380-6728-3
- "Chernobyl Nuclear Accident". www.iaea.org. IAEA. 14 May 2014.
- "Chernobyl: Assessment of Radiological and Health Impact, 2002 update; Chapter II – The release, dispersion and deposition of radionuclides" (PDF). OECD-NEA. 2002. Archived (PDF) from the original on 22 June 2015. Retrieved 3 June 2015.
- Johnson, Thomas (author/director) (2006). The battle of Chernobyl. Play Film / Discovery Channel. (see 1996 interview with Mikhail Gorbachev)
- "Analysis: Nuclear renaissance could fizzle after Japan quake". Reuters. 2011-03-14. Retrieved 2011-03-14.
- "Areva's Finland reactor to start in 2019 after another delay". Reuters. 9 October 2017. Retrieved 3 August 2019.
- "Trend in Electricity Supplied". International Atomic Energy Agency. Retrieved 2021-01-09.
- "Analysis: The legacy of the Fukushima nuclear disaster". Carbon Brief. 10 March 2016. Retrieved 24 March 2021.
- Sylvia Westall & Fredrik Dahl (2011-06-24). "IAEA Head Sees Wide Support for Stricter Nuclear Plant Safety". Scientific American. Archived from the original on 2011-06-25.
- Jo Chandler (2011-03-19). "Is this the end of the nuclear revival?". The Sydney Morning Herald.
- Aubrey Belford (2011-03-17). "Indonesia to Continue Plans for Nuclear Power". The New York Times.
- Piers Morgan (2011-03-17). "Israel Prime Minister Netanyahu: Japan situation has "caused me to reconsider" nuclear power". CNN. Retrieved 2011-03-17.
- "Israeli PM cancels plan to build nuclear plant". xinhuanet.com. 2011-03-18. Retrieved 2011-03-17.
- "Startup of Sendai Nuclear Power Unit No.1". Kyushu Electric Power Company Inc. 2015-08-11. Archived from the original on 2017-05-25. Retrieved 2015-08-12.
- "January: Taking a fresh look at the future of nuclear power". www.iea.org.
- "Plans for New Reactors Worldwide". World Nuclear Association. October 2015.
- "International Energy outlook 2016". US Energy Information Administration. Retrieved 17 August 2016.
- "Plans for New Nuclear Reactors Worldwide". www.world-nuclear.org. World Nuclear Association. Retrieved 2018-09-29.
- "Can China become a scientific superpower? - The great experiment". The Economist. 12 January 2019. Retrieved 25 January 2019.
- "Nuclear Power Reactors in the World – 2015 Edition" (PDF). International Atomic Energy Agency (IAEA). Retrieved 26 October 2017.
- "How does a nuclear reactor make electricity?". www.world-nuclear.org. World Nuclear Association. Retrieved 24 August 2018.
- Spyrou, Artemis; Mittig, Wolfgang (2017-12-03). "Atomic age began 75 years ago with the first controlled nuclear chain reaction". Scientific American. Retrieved 2018-11-18.
- "Stages of the Nuclear Fuel Cycle". NRC Web. Nuclear Regulatory Commission. Retrieved 17 April 2021.
- "Nuclear Fuel Cycle Overview". www.world-nuclear.org. World Nuclear Association. Retrieved 17 April 2021.
- "uranium Facts, information, pictures | Encyclopedia.com articles about uranium". Encyclopedia.com. 2001-09-11. Retrieved 2013-06-14.
- "Second Thoughts About Nuclear Power" (PDF). A Policy Brief – Challenges Facing Asia. January 2011. Archived from the original (PDF) on January 16, 2013.
- "Uranium resources sufficient to meet projected nuclear energy requirements long into the future". Nuclear Energy Agency (NEA). 2008-06-03. Archived from the original on 2008-12-05. Retrieved 2008-06-16.
- Uranium 2007 – Resources, Production and Demand. Nuclear Energy Agency, Organisation for Economic Co-operation and Development. 2008. ISBN 978-92-64-04766-2. Archived from the original on 2009-01-30.
- "Energy Supply" (PDF). p. 271. Archived from the original (PDF) on 2007-12-15. and table 4.10.
- "Waste Management in the Nuclear Fuel Cycle". Information and Issue Briefs. World Nuclear Association. 2006. Retrieved 2006-11-09.
- "Energy Supply" (PDF). p.��271. Archived from the original (PDF) on 2007-12-15. and figure 4.10.
- Ferronsky, V.I.; Polyakov, V.A. (2012). Isotopes of the Earth's Hydrosphere. p. 399. ISBN 978-94-007-2856-1.
- "Toxicological profile for thorium" (PDF). Agency for Toxic Substances and Disease Registry. 1990. p. 76.
world average concentration in seawater is 0.05 μg/L (Harmsen and De Haan 1980)
- Huh, C.A.; Bacon, M.P. (2002). "Determination of thorium concentration in seawater by neutron activation analysis". Analytical Chemistry. 57 (11): 2138–2142. doi:10.1021/ac00288a030.
- Seko, Noriaki (July 29, 2013). "The current state of promising research into extraction of uranium from seawater – Utilization of Japan's plentiful seas". Global Energy Policy Research.
- Wang, Taiping; Khangaonkar, Tarang; Long, Wen; Gill, Gary (2014). "Development of a Kelp-Type Structure Module in a Coastal Ocean Model to Assess the Hydrodynamic Impact of Seawater Uranium Extraction Technology". Journal of Marine Science and Engineering. 2: 81–92. doi:10.3390/jmse2010081.
- Alexandratos SD, Kung S (April 20, 2016). "Uranium in Seawater". Industrial & Engineering Chemistry Research. 55 (15): 4101–4362. doi:10.1021/acs.iecr.6b01293.
- Finck, Philip. "Current Options for the Nuclear Fuel Cycle" (PDF). JAIF.
- "Backgrounder on Radioactive Waste". NRC. Nuclear Regulatory Commission. Retrieved 20 April 2021.
- "A fast reactor system to shorten the lifetime of long-lived fission products".
- "Radioactivity : Minor Actinides". www.radioactivity.eu.com.
- Ojovan, Michael I. (2014). An introduction to nuclear waste immobilisation, second edition (2nd ed.). Kidlington, Oxford, U.K.: Elsevier. ISBN 978-0-08-099392-8.
- "Environmental Surveillance, Education and Research Program". Idaho National Laboratory. Archived from the original on 2008-11-21. Retrieved 2009-01-05.
- John McCarthy. "Frequently Asked Questions About Nuclear Energy".
after 500 years, the fission products will be less radioactive than the uranium ore they are originally derived from
- Ojovan, M.I.; Lee, W.E. (2005). An Introduction to Nuclear Waste Immobilisation. Amsterdam: Elsevier Science Publishers. p. 315. ISBN 978-0-08-044462-8.
- National Research Council (1995). Technical Bases for Yucca Mountain Standards. Washington, DC: National Academy Press. p. 91. ISBN 978-0-309-05289-4.
- "The Status of Nuclear Waste Disposal". The American Physical Society. January 2006. Retrieved 2008-06-06.
- "Public Health and Environmental Radiation Protection Standards for Yucca Mountain, Nevada; Proposed Rule" (PDF). United States Environmental Protection Agency. 2005-08-22. Retrieved 2008-06-06.
- "CRS Report for Congress. Radioactive Waste Streams: Waste Classification for Disposal" (PDF).
The Nuclear Waste Policy Act of 1982 (NWPA) defined irradiated fuel as spent nuclear fuel, and the byproducts as high-level waste.
- Vandenbosch 2007, p. 21.
- Duncan Clark (2012-07-09). "Nuclear waste-burning reactor moves a step closer to reality | Environment | guardian.co.uk". Guardian. London. Retrieved 2013-06-14.
- George Monbiot. "A Waste of Waste". Monbiot.com. Retrieved 2013-06-14.
- "Energy From Thorium: A Nuclear Waste Burning Liquid Salt Thorium Reactor". YouTube. 2009-07-23. Retrieved 2013-06-14.
- "Role of Thorium to Supplement Fuel Cycles of Future Nuclear Energy Systems" (PDF). IAEA. 2012. Retrieved 7 April 2021.
Once irradiated in a reactor, the fuel of a thorium–uranium cycle contains an admixture of 232U (half-life 68.9 years) whose radioactive decay chain includes emitters (particularly 208Tl) of high energy gamma radiation (2.6 MeV). This makes spent thorium fuel treatment more difficult, requires remote handling/control during reprocessing and during further fuel fabrication, but on the other hand, may be considered as an additional non-proliferation barrier.
- "NRC: Low-Level Waste". www.nrc.gov. Retrieved 28 August 2018.
- "The Challenges of Nuclear Power".
- "Coal Ash Is More Radioactive than Nuclear Waste". Scientific American. 2007-12-13.
- Alex Gabbard (2008-02-05). "Coal Combustion: Nuclear Resource or Danger". Oak Ridge National Laboratory. Archived from the original on February 5, 2007. Retrieved 2008-01-31.
- "Coal ash is not more radioactive than nuclear waste". CE Journal. 2008-12-31. Archived from the original on 2009-08-27.
- "Yankee Nuclear Power Plant". Yankeerowe.com. Retrieved 2013-06-22.
- "Why nuclear energy". Generation Atomic.
- "NPR Nuclear Waste May Get A Second Life". NPR.
- "Hyperphysics Energy Consumption of the United States".
- "NRC: Dry Cask Storage". Nrc.gov. 2013-03-26. Retrieved 2013-06-22.
- Montgomery, Scott L. (2010). The Powers That Be, University of Chicago Press, p. 137.
- "international Journal of Environmental Studies, The Solutions for Nuclear waste, December 2005" (PDF). Retrieved 2013-06-22.
- "Oklo: Natural Nuclear Reactors". U.S. Department of Energy Office of Civilian Radioactive Waste Management, Yucca Mountain Project, DOE/YMP-0010. November 2004. Archived from the original on 2009-08-25. Retrieved 2009-09-15.
- Gore, Al (2009). Our Choice: A Plan to Solve the Climate Crisis. Emmaus, PA: Rodale. pp. 165–166. ISBN��978-1-59486-734-7.
- Muller, Richard A.; Finsterle, Stefan; Grimsich, John; Baltzer, Rod; Muller, Elizabeth A.; Rector, James W.; Payer, Joe; Apps, John (May 29, 2019). "Disposal of High-Level Nuclear Waste in Deep Horizontal Drillholes". Energies. 12 (11): 2052. doi:10.3390/en12112052.
- Mallants, Dirk; Travis, Karl; Chapman, Neil; Brady, Patrick V.; Griffiths, Hefin (February 14, 2020). "The State of the Science and Technology in Deep Borehole Disposal of Nuclear Waste". Energies. 13 (4): 833. doi:10.3390/en13040833.
- "A Nuclear Power Renaissance?". Scientific American. 2008-04-28. Archived from the original on 2017-05-25. Retrieved 2008-05-15.
- von Hippel, Frank N. (April 2008). "Nuclear Fuel Recycling: More Trouble Than It's Worth". Scientific American. Retrieved 2008-05-15.
- "Licence granted for Finnish used fuel repository". World Nuclear News. 2015-11-12. Retrieved 2018-11-18.
- Poinssot, Ch.; Bourg, S.; Ouvrier, N.; Combernoux, N.; Rostaing, C.; Vargas-Gonzalez, M.; Bruno, J. (May 2014). "Assessment of the environmental footprint of nuclear energy systems. Comparison between closed and open fuel cycles". Energy. 69: 199–211. doi:10.1016/j.energy.2014.02.069.
- R. Stephen Berry and George S. Tolley, Nuclear Fuel Reprocessing, The University of Chicago, 2013.
- Fairley, Peter (February 2007). "Nuclear Wasteland". IEEE Spectrum.
- "Processing of Used Nuclear Fuel". World Nuclear Association. 2018. Retrieved 2018-12-26.
- "Proliferation-resistant nuclear fuel cycles. [Spiking of plutonium with /sup 238/Pu]".
- Fedorov, M.I.; Dyachenko, A.I.; Balagurov, N.A.; Artisyuk, V.V. (2015). "Formation of proliferation-resistant nuclear fuel supplies based on reprocessed uranium for Russian nuclear technologies recipient countries". Nuclear Energy and Technology. 1 (2): 111–116. doi:10.1016/j.nucet.2015.11.023.
- Lloyd, Cody; Goddard, Braden (2018). "Proliferation resistant plutonium: An updated analysis". Nuclear Engineering and Design. 330: 297–302. doi:10.1016/j.nucengdes.2018.02.012.
- Harold Feiveson; et al. (2011). "Managing nuclear spent fuel: Policy lessons from a 10-country study". Bulletin of the Atomic Scientists.
- Kok, Kenneth D. (2010). Nuclear Engineering Handbook. CRC Press. p. 332. ISBN 978-1-4200-5391-3.
- Emmanuel Jarry (6 May 2015). "Crisis for Areva's plant as clients shun nuclear". Moneyweb. Reuters. Archived from the original on 23 July 2015. Retrieved 6 May 2015.
- David, S. (2005). "Future Scenarios for Fission Based Reactors". Nuclear Physics A. 751: 429–441. Bibcode:2005NuPhA.751..429D. doi:10.1016/j.nuclphysa.2005.02.014.
- Brundtland, Gro Harlem (20 March 1987). "Chapter 7: Energy: Choices for Environment and Development". Our Common Future: Report of the World Commission on Environment and Development. Oslo. Retrieved 27 March 2013.
Today's primary sources of energy are mainly non-renewable: natural gas, oil, coal, peat, and conventional nuclear power. There are also renewable sources, including wood, plants, dung, falling water, geothermal sources, solar, tidal, wind, and wave energy, as well as human and animal muscle-power. Nuclear reactors that produce their own fuel ('breeders') and eventually fusion reactors are also in this category
- John McCarthy (2006). "Facts From Cohen and Others". Progress and its Sustainability. Stanford. Archived from the original on 2007-04-10. Retrieved 2006-11-09. Citing: Cohen, Bernard L. (January 1983). "Breeder reactors: A renewable energy source". American Journal of Physics. 51 (1): 75–76. Bibcode:1983AmJPh..51...75C. doi:10.1119/1.13440. S2CID 119587950.
- "Advanced Nuclear Power Reactors". Information and Issue Briefs. World Nuclear Association. 2006. Retrieved 2006-11-09.
- "Synergy between Fast Reactors and Thermal Breeders for Safe, Clean, and Sustainable Nuclear Power" (PDF). World Energy Council. Archived from the original (PDF) on 2011-01-10.
- Rebecca Kessler. "Are Fast-Breeder Reactors A Nuclear Power Panacea? by Fred Pearce: Yale Environment 360". E360.yale.edu. Retrieved 2013-06-14.
- "Fast Neutron Reactors | FBR – World Nuclear Association". www.world-nuclear.org. Retrieved 7 October 2018.
- "Prototype fast breeder reactor to be commissioned in two months: IGCAR director". The Times of India. Retrieved 28 August 2018.
- "India's breeder reactor to be commissioned in 2013". Hindustan Times. Archived from the original on 2013-04-26. Retrieved 2013-06-14.
- "Thorium". Information and Issue Briefs. World Nuclear Association. 2006. Retrieved 2006-11-09.
- Invernizzi, Diletta Colette; Locatelli, Giorgio; Velenturf, Anne; Love, Peter ED.; Purnell, Phil; Brookes, Naomi J. (2020-09-01). "Developing policies for the end-of-life of energy infrastructure: Coming to terms with the challenges of decommissioning". Energy Policy. 144: 111677. doi:10.1016/j.enpol.2020.111677. ISSN 0301-4215.
- "Decommissioning of nuclear installations". www.iaea.org. 17 October 2016. Retrieved 19 April 2021.
- Invernizzi, Diletta Colette; Locatelli, Giorgio; Brookes, Naomi J. (2017-08-01). "How benchmarking can support the selection, planning and delivery of nuclear decommissioning projects" (PDF). Progress in Nuclear Energy. 99: 155–164. doi:10.1016/j.pnucene.2017.05.002.
- https://www.nrc.gov/reading-rm/doc-collections/fact-sheets/decommissioning.html Quote: Before a nuclear power plant begins operations, the licensee must establish or obtain a financial mechanism – such as a trust fund or a guarantee from its parent company – to ensure there will be sufficient money to pay for the ultimate decommissioning of the facility.
- "Share of electricity production from nuclear". Our World in Data. Retrieved 18 October 2020.
- "Electricity generation by source". International Energy Agency.
- "Steep decline in nuclear power would threaten energy security and climate goals". International Energy Agency. 2019-05-28. Retrieved 2019-07-08.
- Armaroli, Nicola; Balzani, Vincenzo (2011). "Towards an electricity-powered world". Energy and Environmental Science. 4 (9): 3193–3222 . doi:10.1039/c1ee01249e. S2CID 1752800.
- "REN 21. Renewables 2014 Global Status Report" (PDF).
- Butler, Nick (3 September 2018). "The challenge for nuclear is to recover its competitive edge". Financial Times. Retrieved 9 September 2018.
- "World Nuclear Power Reactors & Uranium Requirements". World Nuclear Association. Retrieved 2021-01-09.
- "What's the Lifespan for a Nuclear Reactor? Much Longer Than You Might Think". Energy.gov. Retrieved 2020-06-09.
- "Under Construction Reactors". International Atomic Energy Agency. Retrieved 2019-12-15.
- "EU energy in figures". European Commission. 2020. p. 94. Retrieved 2021-01-09.
- "Issues in Science & Technology Online; "Promoting Low-Carbon Electricity Production"".Archived 2013-09-27 at the Wayback Machine
- "The European Strategic Energy Technology Plan SET-Plan Towards a low-carbon future 2010" (PDF). p. 6. Archived 2014-02-11 at the Wayback Machine
- "What is Nuclear Power Plant – How Nuclear Power Plants work | What is Nuclear Power Reactor – Types of Nuclear Power Reactors". EngineersGarage. Archived from the original on 2013-10-04. Retrieved 2013-06-14.
- Magdi Ragheb. "Naval Nuclear Propulsion" (PDF). Archived from the original (PDF) on 2015-02-26. Retrieved 2015-06-04.
As of 2001, about 235 naval reactors had been built
- "Nuclear Icebreaker Lenin". Bellona. 2003-06-20. Archived from the original on October 15, 2007. Retrieved 2007-11-01.
- Non-electric Applications of Nuclear Power: Seawater Desalination, Hydrogen Production and other Industrial Applications. International Atomic Energy Agency. 2007. ISBN 978-92-0-108808-6. Retrieved 21 August 2018.
- "Synapse Energy |". www.synapse-energy.com. Retrieved 2020-12-29.
- Lovering, Jessica R.; Yip, Arthur; Nordhaus, Ted (2016). "Historical construction costs of global nuclear power reactors". Energy Policy. 91: 371–382. doi:10.1016/j.enpol.2016.01.011.
- Ed Crooks (2010-09-12). "Nuclear: New dawn now seems limited to the east". Financial Times. Retrieved 2010-09-12.
- The Future of Nuclear Power. Massachusetts Institute of Technology. 2003. ISBN 978-0-615-12420-9. Retrieved 2006-11-10.
- "Projected Costs of Generating Electricity 2020". International Energy Agency & OECD Nuclear Energy Agency. Retrieved 12 December 2020.
- Update of the MIT 2003 Future of Nuclear Power (PDF). Massachusetts Institute of Technology. 2009. Retrieved 21 August 2018.
- "Splitting the cost". The Economist. 12 November 2009. Retrieved 21 August 2018.
- "The Canadian Nuclear FAQ - Section A: CANDU Technology". Archived from the original on 2013-11-01. Retrieved 2019-08-05.
- A. Lokhov. "Load-following with nuclear power plants" (PDF).
- "Indian reactor breaks operating record". World Nuclear News. 25 October 2018.
- "Indian-Designed Nuclear Reactor Breaks Record for Continuous Operation". POWER Magazine. 1 February 2019. Retrieved 28 March 2019.
- "Nuclear Reactors for Space - World Nuclear Association". world-nuclear.org. Retrieved 17 April 2021.
- Patel, Prachi. "Nuclear-Powered Rockets Get a Second Look for Travel to Mars". IEEE Spectrum. Retrieved 17 April 2021.
- Deitrich, L.W. "Basic principles of nuclear safety" (PDF). International Atomic Energy Agency. Retrieved 2018-11-18.
- "Emergency core cooling systems (ECCS)". United States Nuclear Regulatory Commission. 2018-07-06. Retrieved 2018-12-10.
- "What are the safest sources of energy?". Our World in Data. Retrieved 2020-05-27.
- "Dr. MacKay Sustainable Energy without the hot air". Data from studies by the Paul Scherrer Institute including non EU data. p. 168. Retrieved 2012-09-15.
- Brendan Nicholson (2006-06-05). "Nuclear power 'cheaper, safer' than coal and gas". The Age. Melbourne. Retrieved 2008-01-18.
- Markandya, A.; Wilkinson, P. (2007). "Electricity generation and health". Lancet. 370 (9591): 979–990. doi:10.1016/S0140-6736(07)61253-7. PMID 17876910. S2CID 25504602.
Nuclear power has lower electricity related health risks than Coal, Oil, & gas. ...the health burdens are appreciably smaller for generation from natural gas, and lower still for nuclear power. This study includes the latent or indirect fatalities, for example those caused by the inhalation of fossil fuel created particulate matter, smog induced cardiopulmonary events, black lung etc. in its comparison.
- "Nuclear Power Prevents More Deaths Than It Causes | Chemical & Engineering News". Cen.acs.org. Retrieved 2014-01-24.
- Kharecha, Pushker A.; Hansen, James E. (2013). "Prevented Mortality and Greenhouse Gas Emissions from Historical and Projected Nuclear Power". Environmental Science & Technology. 47 (9): 4889–4895. Bibcode:2013EnST...47.4889K. doi:10.1021/es3051197. PMID 23495839.
- Dennis Normile (2012-07-27). "Is Nuclear Power Good for You?". Science. 337 (6093): 395. doi:10.1126/science.337.6093.395-b. Archived from the original on 2013-03-01.
- Hasegawa, Arifumi; Tanigawa, Koichi; Ohtsuru, Akira; Yabe, Hirooki; Maeda, Masaharu; Shigemura, Jun; Ohira, Tetsuya; Tominaga, Takako; Akashi, Makoto; Hirohashi, Nobuyuki; Ishikawa, Tetsuo; Kamiya, Kenji; Shibuya, Kenji; Yamashita, Shunichi; Chhem, Rethy K (August 2015). "Health effects of radiation and other health problems in the aftermath of nuclear accidents, with an emphasis on Fukushima". The Lancet. 386 (9992): 479–488. doi:10.1016/S0140-6736(15)61106-0. PMID 26251393. S2CID 19289052.
- Andrew C. Revkin (2012-03-10). "Nuclear Risk and Fear, from Hiroshima to Fukushima". The New York Times.
- Frank N. von Hippel (September–October 2011). "The radiological and psychological consequences of the Fukushima Daiichi accident". Bulletin of the Atomic Scientists. 67 (5): 27–36. Bibcode:2011BuAtS..67e..27V. doi:10.1177/0096340211421588.
- "The Fukushima Daiichi accident. Report by the Director General" (PDF). International Atomic Energy Agency. 2015. p. 158. Retrieved 2018-11-18.
- Tomoko Yamazaki & Shunichi Ozasa (2011-06-27). "Fukushima Retiree Leads Anti-Nuclear Shareholders at Tepco Annual Meeting". Bloomberg.
- Mari Saito (2011-05-07). "Japan anti-nuclear protesters rally after PM call to close plant". Reuters.
- "Chernobyl at 25th anniversary – Frequently Asked Questions" (PDF). World Health Organisation. 23 April 2011. Retrieved 14 April 2012.
- "Assessing the Chernobyl Consequences". International Atomic Energy Agency. Archived from the original on 30 August 2013.
- "UNSCEAR 2008 Report to the General Assembly, Annex D" (PDF). United Nations Scientific Committee on the Effects of Atomic Radiation. 2008.
- "UNSCEAR 2008 Report to the General Assembly" (PDF). United Nations Scientific Committee on the Effects of Atomic Radiation. 2008.
- Richard Schiffman (2013-03-12). "Two years on, America hasn't learned lessons of Fukushima nuclear disaster". The Guardian. London.
- Martin Fackler (2011-06-01). "Report Finds Japan Underestimated Tsunami Danger". The New York Times.
- Sovacool, B.K. (2008). "The costs of failure: A preliminary assessment of major energy accidents, 1907–2007". Energy Policy. 36 (5): 1802–1820. doi:10.1016/j.enpol.2008.01.040.
- Burgherr, Peter; Hirschberg, Stefan (10 October 2008). "A Comparative Analysis of Accident Risks in Fossil, Hydro, and Nuclear Energy Chains". Human and Ecological Risk Assessment. 14 (5): 947–973. doi:10.1080/10807030802387556. S2CID 110522982.
- "Publications: Vienna Convention on Civil Liability for Nuclear Damage". International Atomic Energy Agency.
- "Nuclear Power's Role in Generating Electricity" (PDF). Congressional Budget Office. May 2008.
- "Availability of Dam Insurance" (PDF). 1999. Archived 2016-01-08 at the Wayback Machine
- Charles D. Ferguson & Frank A. Settle (2012). "The Future of Nuclear Power in the United States" (PDF). Federation of American Scientists.
- "Nuclear Security – Five Years After 9/11". U.S. NRC. Retrieved 23 July 2007.
- Matthew Bunn & Scott Sagan (2014). "A Worst Practices Guide to Insider Threats: Lessons from Past Mistakes". The American Academy of Arts & Sciences.
- McFadden, Robert D. (1971-11-14). "Damage Is Put at Millions In Blaze at Con Ed Plant". The New York Times. ISSN 0362-4331. Retrieved 2020-01-15.
- Knight, Michael (1972-01-30). "Mechanic Seized in Indian Pt. Fire". The New York Times. ISSN 0362-4331. Retrieved 2020-01-15.
- "The Bulletin of atomic scientists support the megatons to megawatts program". 2008-10-23. Archived from the original on 2011-07-08. Retrieved 2012-09-15.
- "home". usec.com. 2013-05-24. Archived from the original on 2013-06-21. Retrieved 2013-06-14.
- Steven E. Miller & Scott D. Sagan (Fall 2009). "Nuclear power without nuclear proliferation?". Dædalus. 138 (4): 7. doi:10.1162/daed.2009.138.4.7. S2CID 57568427.
- "Nuclear Power in the World Today". World-nuclear.org. Retrieved 2013-06-22.
- "Uranium Enrichment". www.world-nuclear.org. World Nuclear Association.
- Sovacool, Benjamin (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy. Hackensack, NJ: World Scientific. p. 190. ISBN 978-981-4322-75-1.
- "Megatons to Megawatts Eliminates Equivalent of 10,000 Nuclear Warheads". Usec.com. 2005-09-21. Archived from the original on 2013-04-26. Retrieved 2013-06-22.
- Dawn Stover (2014-02-21). "More megatons to megawatts". The Bulletin.
- ’09, Anne-Marie Corley, SM. "Against Long Odds, MIT's Thomas Neff Hatched a Plan to Turn Russian Warheads into American Electricity".CS1 maint: numeric names: authors list (link)
- "Future Unclear For 'Megatons To Megawatts' Program". All Things Considered. NPR. 2009-12-05. Retrieved 2013-06-22.
- "IPCC Working Group III – Mitigation of Climate Change, Annex III: Technology–specific cost and performance parameters" (PDF). IPCC. 2014. table A.III.2. Retrieved 2019-01-19.
- National Renewable Energy Laboratory (NREL) (2013-01-24). "Nuclear Power Results – Life Cycle Assessment Harmonization". nrel.gov. Archived from the original on 2013-07-02. Retrieved 2013-06-22.
Collectively, life cycle assessment literature shows that nuclear power is similar to other renewable and much lower than fossil fuel in total life cycle GHG emissions.
- "Life Cycle Assessment Harmonization Results and Findings. Figure 1". NREL. Archived 2017-05-06 at the Wayback Machine
- "IPCC Working Group III – Mitigation of Climate Change, Annex II Metrics & Methodology" (PDF). IPCC. 2014. section A.II.9.3. Retrieved 2019-01-19.
- "UNSCEAR 2008 Report to the General Assembly" (PDF). United Nations Scientific Committee on the Effects of Atomic Radiation. 2008.
- "National Safety Council". Nsc.org. Archived from the original on 12 October 2009. Retrieved 18 June 2013.
- James J. MacKenzie (December 1977). "Review of The Nuclear Power Controversy by Arthur W. Murphy". The Quarterly Review of Biology. 52 (4): 467–468. JSTOR 2823429.
- "U.S. Energy Legislation May Be 'Renaissance' for Nuclear Power". Bloomberg. Archived 2009-06-26 at the Wayback Machine.
- Patterson, Thom (2013-11-03). "Climate change warriors: It's time to go nuclear". CNN.
- "Renewable Energy and Electricity". World Nuclear Association. June 2010. Retrieved 2010-07-04.
- M. King Hubbert (June 1956). "Nuclear Energy and the Fossil Fuels 'Drilling and Production Practice'" (PDF). API. p. 36. Archived from the original (PDF) on 2008-05-27. Retrieved 2008-04-18.
- "Academic: Fossil fuel back-ups 'may be the price to pay' for renewables".
- Spencer R. Weart (2012). The Rise of Nuclear Fear. Harvard University Press.
- Sturgis, Sue. "Investigation: Revelations about Three Mile Island disaster raise doubts over nuclear plant safety". Institute for Southern Studies. Archived from the original on 2010-04-18. Retrieved 2010-08-24.
- "Energy Revolution: A Sustainable World Energy Outlook" (PDF). Greenpeace International and European Renewable Energy Council. January 2007. p. 7. Archived 2009-08-06 at the Wayback Machine
- Giugni, Marco (2004). Social protest and policy change : ecology, antinuclear, and peace movements in comparative perspective. Lanham: Rowman & Littlefield. p. 44. ISBN 978-0742518261.
- Sovacool Benjamin K. (2008). "The costs of failure: A preliminary assessment of major energy accidents, 1907–2007". Energy Policy. 36 (5): 1802–1820. doi:10.1016/j.enpol.2008.01.040.
- Cooke, Stephanie (2009). In Mortal Hands: A Cautionary History of the Nuclear Age. New York: Bloomsbury. p. 280. ISBN 978-1-59691-617-3.
- Kurt Kleiner (October 2008). "Nuclear energy: assessing the emissions" (PDF). Nature Reports. 2: 130–131.
- Diesendorf, Mark (2007). Greenhouse Solutions with Sustainable Energy. Sydney, NSW: University of New South Wales Press. p. 252. ISBN 978-0-86840-973-3.
- Mark Diesendorf. "Is nuclear energy a possible solution to global warming?" (PDF). Archived July 22, 2012, at the Wayback Machine
- Smith; et al. (15 January 2019). "Current fossil fuel infrastructure does not yet commit us to 1.5 °C warming". Nature. 10 (1): 101. Bibcode:2019NatCo..10..101S. doi:10.1038/s41467-018-07999-w. PMC 6333788. PMID 30647408.
- Ross Koningstein; David Fork (18 November 2014). "What It Would Really Take to Reverse Climate Change". IEEE Spectrum.
- Nathanael Johnson (2018). "Agree to Agree Fights over renewable standards and nuclear power can be vicious. Here's a list of things that climate hawks agree on". Grist.
- "What's missing from the 100% renewable energy debate". Utility Dive.
- Deign, Jason (March 30, 2018). "Renewables or Nuclear? A New Front in the Academic War Over Decarbonization". gtm. Greentech Media.
- "Turkey may benefit from nuclear power in its bid for clean energy". DailySabah. Retrieved 2019-07-14.
- "2019 Key World Energy Statistics" (PDF). IEA. 2019.
- Fiona Harvey (2011-05-09). "Renewable energy can power the world, says landmark IPCC study". The Guardian. London.
- "Hydroelectric power water use". USGS.
- Dawn Stover (January 30, 2014). "Nuclear vs. renewables: Divided they fall". Bulletin of the Atomic Scientists.
- Nils Starfelt; Carl-Erik Wikdahl. "Economic Analysis of Various Options of Electricity Generation – Taking into Account Health and Environmental Effects" (PDF). Archived from the original (PDF) on 2007-09-27. Retrieved 2012-09-08.
- David Biello (2009-01-28). "Spent Nuclear Fuel: A Trash Heap Deadly for 250,000 Years or a Renewable Energy Source?". Scientific American. Retrieved 2014-01-24.
- "Closing and Decommissioning Nuclear Power Plants" (PDF). United Nations Environment Programme. 2012-03-07. Archived from the original (PDF) on 2016-05-18.
- Qvist, Staffan A.; Brook, Barry W. (13 May 2015). "Potential for Worldwide Displacement of Fossil-Fuel Electricity by Nuclear Energy in Three Decades Based on Extrapolation of Regional Deployment Data". PLOS ONE. 10 (5): e0124074. Bibcode:2015PLoSO..1024074Q. doi:10.1371/journal.pone.0124074. PMC 4429979. PMID 25970621.
- "Report: World can Rid Itself of Fossil Fuel Dependence in as little as 10 years". Discovery.
- Brook Barry W (2012). "Could nuclear fission energy, etc., solve the greenhouse problem? The affirmative case". Energy Policy. 42: 4–8. doi:10.1016/j.enpol.2011.11.041.
- Loftus, Peter J.; Cohen, Armond M.; Long, Jane C.S.; Jenkins, Jesse D. (January 2015). "A critical review of global decarbonization scenarios: what do they tell us about feasibility?" (PDF). WIREs Climate Change. 6 (1): 93–112. doi:10.1002/wcc.324.
- Kloor, Keith (2013-01-11). "The Pro-Nukes Environmental Movement". Slate.com "The Big Questions" Blog. The Slate Group. Retrieved 2013-03-11.
- Smil, Vaclav (2012-06-28). "A Skeptic Looks at Alternative Energy". IEEE Spectrum. 49 (7): 46–52. doi:10.1109/MSPEC.2012.6221082. S2CID 9842335. Archived from the original on 2019-03-20. Retrieved 2014-01-24.
- Heuberger, Clara Franziska; Mac Dowell, Niall (March 2018). "Real-World Challenges with a Rapid Transition to 100% Renewable Power Systems". Joule. 2 (3): 367–370. doi:10.1016/j.joule.2018.02.002.
- "The Future of Nuclear Energy in a Carbon-Constrained World" (PDF). Massachusetts Institute of Technology. 2018.
- "Does Hitachi decision mean the end of UK's nuclear ambitions?". The Guardian. 17 January 2019.
- "Land Needs for Wind, Solar Dwarf Nuclear Plant's Footprint". nei.org. NEI. July 9, 2015.
- "Quadrennial technology review concepts in integrated analysis" (PDF). September 2015. p. 388.
- "Eco-Blowback Mutiny in the Land of Wind Turbines". Der Spiegel.
- Heidi Vella. "Nuclear power – good for biodiversity?". Power Technology.
- "Is nuclear power key to biodiversity?". Conservation magazine.
- Brook, Barry W.; Bradshaw, Corey J. A. (June 2015). "Key role for nuclear energy in global biodiversity conservation". Conservation Biology. 29 (3): 702–712. doi:10.1111/cobi.12433. PMID 25490854. S2CID 3058957.
- George Monbiot. "Let's make Britain wild again and find ourselves in nature". The Guardian.
- "Two's a crowd: Nuclear and renewables don't mix". techxplore.com. Retrieved 6 October 2020.
- Sovacool, Benjamin K.; Schmid, Patrick; Stirling, Andy; Walter, Goetz; MacKerron, Gordon (5 October 2020). "Differences in carbon emissions reduction between countries pursuing renewable electricity versus nuclear power". Nature Energy. 5 (11): 928–935. Bibcode:2020NatEn...5..928S. doi:10.1038/s41560-020-00696-3. ISSN 2058-7546. Retrieved 6 October 2020.
- Fell, Harrison; Gilbert, Alexander; Jenkins, Jesse; Mildenberger, Matto (8 January 2021). "Reply to "Differences in carbon emissions reduction between countries pursuing renewable electricity versus nuclear power," by Sovacool et al. (2020)". SSRN. Elsevier. Retrieved 10 February 2021.
- Bointner, Raphael; Pezzutto, Simon; Sparber, Wolfram (2016). "Scenarios of public energy research and development expenditures: financing energy innovation in Europe". WIREs Energy and Environment. 5 (4): 470–488. doi:10.1002/wene.200. ISSN 2041-840X. Retrieved 5 December 2020.
Based on indications by the European Commission, nonnuclear energy and NE are both expected to have a budget of 5.9 billion EUR, which means 8% of Horizon’s 2020 R&D expenditures are devoted to nonnuclear energy and NE. [...] Thus, the nuclear share of the knowledge stock induced by the European Commission will peak in2016 with 66% followed by a decline to 55% in 2023 due to increased nonnuclear energy R&D expenditures and renewable energy technologies in particular. The European Commission’s strong focus on NE is justified by its key activities such as maintenance of nuclear security and safety, radioactive waste disposal, and nuclear fusion.
- Kiriyama, Eriko; Kajikawa, Yuya; Fujita, Katsuhide; Iwata, Shuichi (1 September 2013). "A lead for transvaluation of global nuclear energy research and funded projects in Japan". Applied Energy. 109: 145–153. doi:10.1016/j.apenergy.2013.03.045. ISSN 0306-2619. Retrieved 5 December 2020.
To borrow an argument from Nemet and Kammen who examined investments in R&D in the energy sector, large government R&D initiatives crowd out other R&D programs. It is straightforward to consider that it is politically difficult to regard such a huge investment made in the past as a sunk cost.
- Ramana, M. V. (2016). "Second Life or Half-Life? The Contested Future of Nuclear Power and Its Potential Role in a Sustainable Energy Transition". The Palgrave Handbook of the International Political Economy of Energy. Palgrave Macmillan UK: 363–396. doi:10.1057/978-1-137-55631-8_15. ISBN 978-1-137-55630-1. Retrieved 5 December 2020.
At the same time, a number of factors, including mounting costs and intense competition from other sources of electricity generation such as natural gas and renewable technologies, have propelled a decline in the share of nuclear energy in the world’s power production. [...] To the extent that nuclear power grows in these countries, it will likely be at the expense of renewable energy. In both kinds of countries, however, local communities contest the expansion of nuclear power, fiercely in some cases, and this factor, in addition to the high economic costs associated with nuclear reactors, acts as a brake on accelerated nuclear construction.
- Markard, Jochen; Bento, Nuno; Kittner, Noah; Nuñez-Jimenez, Alejandro (1 September 2020). "Destined for decline? Examining nuclear energy from a technological innovation systems perspective". Energy Research & Social Science. 67: 101512. doi:10.1016/j.erss.2020.101512. ISSN 2214-6296. Retrieved 5 December 2020.
Also, increasingly fierce competition from natural gas, solar PV, wind, and energy-storage technologies speaks against nuclear in the electricity sector.
- Khatib, Hisham; Difiglio, Carmine (1 September 2016). "Economics of nuclear and renewables". Energy Policy. 96: 740–750. doi:10.1016/j.enpol.2016.04.013. ISSN 0301-4215. Retrieved 5 December 2020.
Wider introduction of smart grids and the likely demise of nuclear in some OECD countries are bound to enhance the future prospects for new renewables.
- "4th Generation Nuclear Power – OSS Foundation". Ossfoundation.us. Retrieved 2014-01-24.
- Gerstner, E. (2009). "Nuclear energy: The hybrid returns" (PDF). Nature. 460 (7251): 25–28. doi:10.1038/460025a. PMID 19571861. S2CID 205047403.
- Roth, J. Reece (1986). Introduction to fusion energy. Charlottesville, Va.: Ibis Pub. ISBN 978-0935005073.
- T. Hamacher & A.M. Bradshaw (October 2001). "Fusion as a Future Power Source: Recent Achievements and Prospects" (PDF). World Energy Council. Archived from the original (PDF) on 2004-05-06.
- W Wayt Gibbs (2013-12-30). "Triple-threat method sparks hope for fusion". Nature. 505 (7481): 9–10. Bibcode:2014Natur.505....9G. doi:10.1038/505009a. PMID 24380935.
- "Beyond ITER". The ITER Project. Information Services, Princeton Plasma Physics Laboratory. Archived from the original on 2006-11-07. Retrieved 2011-02-05. – Projected fusion power timeline
- "Overview of EFDA Activities". www.efda.org. European Fusion Development Agreement. Archived from the original on 2006-10-01. Retrieved 2006-11-11.
|Wikiversity quizzes on nuclear power|
- AEC Atom Information Booklets, Both series, "Understanding the Atom" and "The World of the Atom". A total of 75 booklets published by the U.S. Atomic Energy Commission (AEC) in the 1960s and 1970s, Authored by scientists and taken together, the booklets comprise the history of nuclear science and its applications at the time.
- Armstrong, Robert C., Catherine Wolfram, Robert Gross, Nathan S. Lewis, and M.V. Ramana et al. The Frontiers of Energy, Nature Energy, Vol 1, 11 January 2016.
- Brown, Kate (2013). Plutopia: Nuclear Families, Atomic Cities, and the Great Soviet and American Plutonium Disasters, Oxford University Press.
- Clarfield, Gerald H. and William M. Wiecek (1984). Nuclear America: Military and Civilian Nuclear Power in the United States 1940–1980, Harper & Row.
- Cooke, Stephanie (2009). In Mortal Hands: A Cautionary History of the Nuclear Age, Black Inc.
- Cravens, Gwyneth (2007). Power to Save the World: the Truth about Nuclear Energy. New York: Knopf. ISBN 978-0-307-26656-9.
- Elliott, David (2007). Nuclear or Not? Does Nuclear Power Have a Place in a Sustainable Energy Future?, Palgrave.
- Ferguson, Charles D., (2007). Nuclear Energy: Balancing Benefits and Risks Council on Foreign Relations.
- Garwin, Richard L. and Charpak, Georges (2001) Megawatts and Megatons A Turning Point in the Nuclear Age?, Knopf.
- Herbst, Alan M. and George W. Hopley (2007). Nuclear Energy Now: Why the Time has come for the World's Most Misunderstood Energy Source, Wiley.
- Mahaffey, James (2015). Atomic accidents: a history of nuclear meltdowns and disasters : from the Ozark Mountains to Fukushima. Pegasus Books. ISBN 978-1-60598-680-7.
- Schneider, Mycle, Steve Thomas, Antony Froggatt, Doug Koplow (2016). The World Nuclear Industry Status Report: World Nuclear Industry Status as of 1 January 2016.
- Walker, J. Samuel (1992). Containing the Atom: Nuclear Regulation in a Changing Environment, 1993–1971, Berkeley: University of California Press.
- Weart, Spencer R. The Rise of Nuclear Fear. Cambridge, MA: Harvard University Press, 2012. ISBN 0-674-05233-1