Nuclear power

The Ikata Nuclear Power Plant, a pressurized water reactor that cools by secondary coolant exchange with the ocean.
The Susquehanna Steam Electric Station, a boiling water reactor. The reactors are located inside the rectangular containment buildings towards the front of the cooling towers.
Three nuclear powered ships, (top to bottom) nuclear cruisers USS Bainbridge and USS Long Beach with USS Enterprise the first nuclear powered aircraft carrier in 1964. Crew members are spelling out Einstein's mass-energy equivalence formula E=mc² on the flight deck.

Nuclear power is produced by controlled (i.e., non-explosive) nuclear reactions. Commercial and utility plants currently use nuclear fission reactions to heat water to produce steam, which is then used to generate electricity.

In 2009, 13-14% of the world's electricity came from nuclear power.[1] Also, more than 150 naval vessels using nuclear propulsion have been built.

Contents

Use

Historical and projected world energy use by energy source, 1980-2030, Source: International Energy Outlook 2007, EIA.
Nuclear power installed capacity and generation, 1980 to 2007 (EIA).
The status of nuclear power globally. Click image for legend.
The CANDU Bruce Nuclear Generating Station is the second largest nuclear power plant in the world.

As of 2005, nuclear power provided 6.3% of the world's energy and 15% of the world's electricity, with the U.S., France, and Japan together accounting for 56.5% of nuclear generated electricity.[2] In 2007, the IAEA reported there were 439 nuclear power reactors in operation in the world,[3] operating in 31 countries.[4] As of December 2009, the world had 436 reactors.[5] Since commercial nuclear energy began in the mid 1950s, 2008 was the first year that no new nuclear power plant was connected to the grid, although two were connected in 2009.[5][6]

Annual generation of nuclear power has been on a slight downward trend since 2007, decreasing 1.8% in 2009 to 2558 TWh with nuclear power meeting 13-14% of the world's electricity demand.[1] One factor in the nuclear power percentage decrease since 2007 has been the prolonged shutdown of large reactors at the Kashiwazaki-Kariwa Nuclear Power Plant in Japan following the Niigata-Chuetsu-Oki earthquake.[1]

The United States produces the most nuclear energy, with nuclear power providing 19%[7] of the electricity it consumes, while France produces the highest percentage of its electrical energy from nuclear reactors—80% as of 2006.[8] In the European Union as a whole, nuclear energy provides 30% of the electricity.[9] Nuclear energy policy differs between European Union countries, and some, such as Austria, Estonia, and Ireland, have no active nuclear power stations. In comparison, France has a large number of these plants, with 16 multi-unit stations in current use.

In the US, while the Coal and Gas Electricity industry is projected to be worth $85 billion by 2013, Nuclear Power generators are forecast to be worth $18 billion.[10]

Many military and some civilian (such as some icebreaker) ships use nuclear marine propulsion, a form of nuclear propulsion.[11] A few space vehicles have been launched using full-fledged nuclear reactors: the Soviet RORSAT series and the American SNAP-10A.

International research is continuing into safety improvements such as passively safe plants,[12] the use of nuclear fusion, and 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.

Nuclear fusion

Nuclear fusion reactions have the potential to be safer and generate less radioactive waste than fission.[13] 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 intense theoretical and experimental investigation since the 1950s.

Use in space

Both fission and fusion appear promising for space propulsion applications, generating higher mission velocities with less reaction mass. This is due to the much higher energy density of nuclear reactions: some 7 orders of magnitude (10,000,000 times) more energetic than the chemical reactions which power the current generation of rockets.

Radioactive decay has been used on a relatively small (few kW) scale, mostly to power space missions and experiments.

History

Origins

The pursuit of nuclear energy for electricity generation began soon after the discovery in the early 20th century that radioactive elements, such as radium, released immense amounts of energy, according to the principle of mass–energy equivalence. However, means of harnessing such energy was impractical, because intensely radioactive elements were, by their very nature, short-lived (high energy release is correlated with short half-lives). However, the dream of harnessing "atomic energy" was quite strong, even it was dismissed by such fathers of nuclear physics like Ernest Rutherford as "moonshine." This situation, however, changed in the late 1930s, with the discovery of nuclear fission.

In 1932, James Chadwick discovered the neutron, which was immediately recognized as a potential tool for nuclear experimentation because of its lack of an electric charge. Experimentation with bombardment of materials with neutrons led Frédéric and Irène Joliot-Curie to discover induced radioactivity in 1934, which allowed the creation of radium-like elements at much less the price of natural radium. Further work by Enrico Fermi in the 1930s focused on using slow neutrons to increase the effectiveness of induced radioactivity. Experiments bombarding uranium with neutrons led Fermi to believe he had created a new, transuranic element, which he dubbed Hesperium.

But in 1938, German chemists Otto Hahn[14] and Fritz Strassmann, along with Austrian physicist Lise Meitner[15] and Meitner's nephew, Otto Robert Frisch,[16] conducted experiments with the products of neutron-bombarded uranium, as a means of further investigating Fermi's claims. They determined that the relatively tiny neutron split the nucleus of the massive uranium atoms into two roughly equal pieces, contradicting Fermi. This was an extremely surprising result: all other forms of nuclear decay involved only small changes to the mass of the nucleus, whereas this process—dubbed "fission" as a reference to biology—involved a complete rupture of the nucleus. Numerous scientists, including Leo Szilard, who was one of the first, recognized that if fission reactions released additional neutrons, a self-sustaining nuclear chain reaction could result. Once this was experimentally confirmed and announced by Frédéric Joliot-Curie in 1939, scientists in many countries (including the United States, the United Kingdom, France, Germany, and the Soviet Union) petitioned their governments for support of nuclear fission research, just on the cusp of World War II.

Constructing the core of B-Reactor at Hanford Site during the Manhattan Project.

In the United States, where Fermi and Szilard had both emigrated, this led to the creation of the first man-made reactor, known as Chicago Pile-1, which achieved criticality on December 2, 1942. This work became part of the Manhattan Project, which built large reactors at the Hanford Site (formerly the town of Hanford, Washington) to breed plutonium for use in the first nuclear weapons, which were used on the cities of Hiroshima and Nagasaki. A parallel uranium enrichment effort also was pursued.

After World War II, the prospects of using "atomic energy" for good, rather than simply for war, were greatly advocated as a reason not to keep all nuclear research controlled by military organizations. However, most scientists agreed that civilian nuclear power would take at least a decade to master, and the fact that nuclear reactors also produced weapons-usable plutonium created a situation in which most national governments (such as those in the United States, the United Kingdom, Canada, and the USSR) attempted to keep reactor research under strict government control and classification. In the United States, reactor research was conducted by the U.S. Atomic Energy Commission, primarily at Oak Ridge, Tennessee, Hanford Site, and Argonne National Laboratory.

Work in the United States, United Kingdom, Canada, and USSR proceeded over the course of the late 1940s and early 1950s. 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. Work was also strongly researched in the US on nuclear marine propulsion, with a test reactor being developed by 1953. (Eventually, the USS Nautilus, the first nuclear-powered submarine, would launch in 1955.) In 1953, US 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 1954 Amendments to the Atomic Energy Act which allowed rapid declassification of U.S. reactor technology and encouraged development by the private sector.

Early years

Calder Hall nuclear power station in the United Kingdom was the world's first nuclear power station to produce electricity in commercial quantities.[17]
The Shippingport Atomic Power Station in Shippingport, Pennsylvania was the first commercial reactor in the USA and was opened in 1957.

On June 27, 1954, the USSR's Obninsk Nuclear Power Plant became the world's first nuclear power plant to generate electricity for a power grid, and produced around 5 megawatts of electric power.[18][19]

Later in 1954, Lewis Strauss, then chairman of the United States Atomic Energy Commission (U.S. AEC, forerunner of the U.S. Nuclear Regulatory Commission and the United States Department of Energy) spoke of electricity in the future being "too cheap to meter".[20] Strauss was referring to hydrogen fusion[21][22]- which was secretly being developed as part of Project Sherwood at the time - but Strauss's statement was interpreted as a promise of very cheap energy from nuclear fission. The U.S. AEC itself had issued far more conservative testimony regarding nuclear fission to the U.S. Congress only months before, projecting that "costs can be brought down... [to]... about the same as the cost of electricity from conventional sources..." Significant disappointment would develop later on, when the new nuclear plants did not provide energy "too cheap to meter."

In 1955 the United Nations' "First Geneva Conference", then the world's largest gathering of scientists and engineers, met to explore the technology. In 1957 EURATOM was launched alongside the European Economic Community (the latter is now the European Union). The same year also saw the launch of the International Atomic Energy Agency (IAEA).

The world's first commercial nuclear power station, Calder Hall in Sellafield, England was opened in 1956 with an initial capacity of 50 MW (later 200 MW).[17][23] The first commercial nuclear generator to become operational in the United States was the Shippingport Reactor (Pennsylvania, December 1957).

One of the first organizations to develop nuclear power was the U.S. Navy, for the purpose of propelling submarines and aircraft carriers. It has an unblemished record in nuclear safety, perhaps because of the stringent demands of Admiral Hyman G. Rickover, who was the driving force behind nuclear marine propulsion as well as the Shippingport Reactor (Alvin Radkowsky was chief scientist at the U.S. Navy nuclear propulsion division, and was involved with the latter). The U.S. Navy has operated more nuclear reactors than any other entity, including the Soviet Navy, with no publicly known major incidents. The first nuclear-powered submarine, USS Nautilus (SSN-571)), was put to sea in December 1954.[24] Two U.S. nuclear submarines, USS Scorpion and USS Thresher, have been lost at sea. These vessels were both lost due to malfunctions in systems not related to the reactor plants. The sites are monitored and no known leakage has occurred from the onboard reactors. The United States Army also had a nuclear power program, beginning in 1954. The SM-1 Nuclear Power Plant, at Ft. Belvoir, Virginia, was the first power reactor in the US to supply electrical energy to a commercial grid (VEPCO), in April 1957, before Shippingport.

Development

History of the use of nuclear power (top) and the number of active nuclear power plants (bottom).

Installed nuclear capacity initially rose relatively quickly, rising from less than 1 gigawatt (GW) in 1960 to 100 GW in the late 1970s, and 300 GW in the late 1980s. Since the late 1980s worldwide capacity has risen much more slowly, reaching 366 GW in 2005. Between around 1970 and 1990, more than 50 GW of capacity was under construction (peaking at over 150 GW in the late 70s and early 80s) — in 2005, around 25 GW of new capacity was planned. More than two-thirds of all nuclear plants ordered after January 1970 were eventually cancelled.[24] A total of 63 nuclear units were canceled in the USA between 1975 and 1980.[25]

Washington Public Power Supply System Nuclear Power Plants 3 and 5 were never completed.

During the 1970s and 1980s rising economic costs (related to extended construction times largely due to regulatory changes and pressure-group litigation)[26] and falling fossil fuel prices made nuclear power plants then under construction less attractive. In the 1980s (U.S.) and 1990s (Europe), flat load growth and electricity liberalization also made the addition of large new baseload capacity 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 (39% and 73% respectively) to invest in nuclear power.[27][28] Today, nuclear power supplies about 80% and 30% of the electricity in those countries, respectively.

A general movement against nuclear power arose during the last third of the 20th century, based on the fear of a possible nuclear accident as well as the history of accidents, fears of radiation as well as the history of radiation of the public, nuclear proliferation, and on the opposition to nuclear waste production, transport and lack of any final storage plans. Protest movements against nuclear power first emerged in the USA in the late 1970s and spread quickly to Europe and the rest of the world. Anti-nuclear power groups emerged in every country that has had a nuclear power programme. Some of these anti-nuclear power organisations are reported to have developed considerable expertise on nuclear power and energy issues.[29] In 1992, the chairman of the Nuclear Regulatory Commission said that "his agency had been pushed in the right direction on safety issues because of the pleas and protests of nuclear watchdog groups".[30]

Health and safety concerns, the 1979 accident at Three Mile Island, and the 1986 Chernobyl disaster played a part in stopping new plant construction in many countries,[31][32] although the public policy organization Brookings Institution suggests that new nuclear units have not been ordered in the U.S. because of soft demand for electricity, and cost overruns on nuclear plants due to regulatory issues and construction delays.[33]

Unlike the Three Mile Island accident, the much more serious Chernobyl accident did not increase regulations affecting Western reactors since the Chernobyl reactors were of the problematic RBMK design only used in the Soviet Union, for example lacking "robust" containment buildings.[34] Many of these reactors are still in use today. However, changes were made in both the reactors themselves (use of low enriched uranium) and in the control system (prevention of disabling safety systems) to reduce the possibility of a duplicate accident.

An international organization to promote safety awareness and professional development on operators in nuclear facilities was created: WANO; World Association of Nuclear Operators.

Opposition in Ireland and Poland prevented nuclear programs there, while Austria (1978), Sweden (1980) and Italy (1987) (influenced by Chernobyl) voted in referendums to oppose or phase out nuclear power. In July 2009, the Italian Parliament passed a law that canceled the results of an earlier referendum and allowed the immediate start of the Italian nuclear program.[35]

Nuclear reactor technology

Cattenom Nuclear Power Plant

Just as many conventional thermal power stations generate electricity by harnessing the thermal energy released from burning fossil fuels, nuclear power plants convert the energy released from the nucleus of an atom, typically via nuclear fission.

When a relatively large fissile atomic nucleus (usually uranium-235 or plutonium-239) absorbs a neutron, a fission of the atom often results. Fission splits the atom into two or more smaller nuclei with kinetic energy (known as fission products) and also releases gamma radiation and free neutrons.[36] A portion of these neutrons may later be absorbed by other fissile atoms and create more fissions, which release more neutrons, and so on.[37]

This nuclear chain reaction can be controlled by using neutron poisons and neutron moderators to change the portion of neutrons that will go on to cause more fissions.[37] Nuclear reactors generally have automatic and manual systems to shut the fission reaction down if unsafe conditions are detected.[38]

A cooling system removes heat from the reactor core and transports it to another area of the plant, where the thermal energy can be harnessed to produce electricity or to do other useful work. Typically the hot coolant will be used as a heat source for a boiler, and the pressurized steam from that boiler will power one or more steam turbine driven electrical generators.[39]

There are many different reactor designs, utilizing different fuels and coolants and incorporating different control schemes. Some of these designs have been engineered to meet a specific need. Reactors for nuclear submarines and large naval ships, for example, commonly use highly enriched uranium as a fuel. This fuel choice increases the reactor's power density and extends the usable life of the nuclear fuel load, but is more expensive and a greater risk to nuclear proliferation than some of the other nuclear fuels.[40]

A number of new designs for nuclear power generation, collectively known as the Generation IV reactors, are the subject of active research and may be used for practical power generation in the future. Many of these new designs specifically attempt to make fission reactors cleaner, safer and/or less of a risk to the proliferation of nuclear weapons. Passively safe plants (such as the ESBWR) are available to be built[41] and other designs that are believed to be nearly fool-proof are being pursued.[42] Fusion reactors, which may be viable in the future, diminish or eliminate many of the risks associated with nuclear fission.[43]

Flexibility of nuclear power plants

It is often claimed that nuclear stations are inflexible in their output, implying that other forms of energy would be required to meet peak demand. While that is true for certain reactors, this is no longer true of at least some modern designs.[44]

Nuclear plants are routinely used in load following mode on a large scale in France.[45]

Boiling water reactors normally have load-following capability, implemented by varying the recirculation water flow.

Life cycle

The nuclear fuel cycle begins when uranium is mined, enriched, and manufactured into nuclear fuel, (1) which is delivered to a nuclear power plant. After usage in the power plant, the spent fuel is delivered to a reprocessing plant (2) or to a final repository (3) for geological disposition. In reprocessing 95% of spent fuel can be recycled to be returned to usage in a power plant (4).

A nuclear reactor is only part of the life-cycle for nuclear power. The process starts with mining (see Uranium mining). Uranium mines are underground, open-pit, or in-situ leach mines. In any case, the uranium ore is extracted, usually converted into a stable and compact form such as yellowcake, and then transported to a processing facility. Here, the yellowcake is converted to uranium hexafluoride, which is then enriched using various techniques. At this point, the enriched uranium, containing more than the natural 0.7% U-235, is used to make rods of the proper composition and geometry for the particular reactor that the fuel is destined for. The fuel rods will spend about 3 operational cycles (typically 6 years total now) inside the reactor, generally until about 3% of their uranium has been fissioned, then they will be moved to a spent fuel pool where the short lived isotopes generated by fission can decay away. After about 5 years in a cooling pond, the spent fuel is radioactively and thermally cool enough to handle, and it can be moved to dry storage casks or reprocessed.

Conventional fuel resources

Uranium is a fairly common element in the Earth's crust. Uranium is approximately as common as tin or germanium in Earth's crust, and is about 35 times more common than silver. Uranium is a constituent of most rocks, dirt, and of the oceans. The fact that uranium is so spread out is a problem because mining uranium is only economically feasible where there is a large concentration. Still, the world's present measured resources of uranium, economically recoverable at a price of 130 USD/kg, are enough to last for "at least a century" at current consumption rates.[46][47] This represents a higher level of assured resources than is normal for most minerals. On the basis of analogies with other metallic minerals, a doubling of price from present levels could be expected to create about a tenfold increase in measured resources, over time. However, the cost of nuclear power lies for the most part in the construction of the power station. Therefore the fuel's contribution to the overall cost of the electricity produced is relatively small, so even a large fuel price escalation will have relatively little effect on final price. For instance, typically a doubling of the uranium market price would increase the fuel cost for a light water reactor by 26% and the electricity cost about 7%, whereas doubling the price of natural gas would typically add 70% to the price of electricity from that source. At high enough prices, eventually extraction from sources such as granite and seawater become economically feasible.[48][49]

Current light water reactors make relatively inefficient use of nuclear fuel, fissioning only the very rare uranium-235 isotope. Nuclear reprocessing can make this waste reusable and more efficient reactor designs allow better use of the available resources.[50]

Breeding

As opposed to current light water reactors which use uranium-235 (0.7% of all natural uranium), fast breeder reactors use uranium-238 (99.3% of all natural uranium). It has been estimated that there is up to five billion years’ worth of uranium-238 for use in these power plants.[51]

Breeder technology has been used in several reactors, but the high cost of reprocessing fuel safely requires uranium prices of more than 200 USD/kg before becoming justified economically.[52] As of December 2005, the only breeder reactor producing power is BN-600 in Beloyarsk, Russia. The electricity output of BN-600 is 600 MW — Russia has planned to build another unit, BN-800, at Beloyarsk nuclear power plant. Also, Japan's Monju reactor is planned for restart (having been shut down since 1995), and both China and India intend to build breeder reactors.

Another alternative would be to use uranium-233 bred from thorium as fission fuel in the thorium fuel cycle. Thorium is about 3.5 times as common as uranium in the Earth's crust, and has different geographic characteristics. This would extend the total practical fissionable resource base by 450%.[53] Unlike the breeding of U-238 into plutonium, fast breeder reactors are not necessary — it can be performed satisfactorily in more conventional plants. India has looked into this technology, as it has abundant thorium reserves but little uranium.

Fusion

Fusion power advocates commonly propose the use of deuterium, or tritium, both isotopes of hydrogen, as fuel and in many current designs also lithium and boron. Assuming a fusion energy output equal to the current global output and that this does not increase in the future, then the known current lithium reserves would last 3000 years, lithium from sea water would last 60 million years, and a more complicated fusion process using only deuterium from sea water would have fuel for 150 billion years.[54] Although this process has yet to be realized, many experts and civilians alike believe fusion to be a promising future energy source due to the short lived radioactivity of the produced waste, its low carbon emissions, and its prospective power output.

Solid waste

The most important waste stream from nuclear power plants is spent nuclear fuel. It is primarily composed of unconverted uranium as well as significant quantities of transuranic actinides (plutonium and curium, mostly). In addition, about 3% of it is fission products from nuclear reactions. The actinides (uranium, plutonium, and curium) are responsible for the bulk of the long-term radioactivity, whereas the fission products are responsible for the bulk of the short-term radioactivity.[55]

High-level radioactive waste

After about 5 percent of a nuclear fuel rod has reacted inside a nuclear reactor that rod is no longer able to be used as fuel (due to the build-up of fission products). Today, scientists are experimenting on how to recycle these rods so as to reduce waste and use the remaining actinides as fuel (large-scale reprocessing is being used in a number of countries).

A typical 1000-MWe nuclear reactor produces approximately 20 cubic meters (about 27 tonnes) of spent nuclear fuel each year (but only 3 cubic meters of vitrified volume if reprocessed).[56][57] All the spent fuel produced to date by all commercial nuclear power plants in the US would cover a football field to the depth of about one meter.[58]

Spent nuclear fuel is initially very highly radioactive and so must be handled with great care and forethought. However, it becomes significantly less radioactive over the course of thousands of years of time. After 40 years, the radiation flux is 99.9% lower than it was the moment the spent fuel was removed from operation, although the spent fuel is still dangerously radioactive at that time.[50] After 10,000 years of radioactive decay, according to United States Environmental Protection Agency standards the spent nuclear fuel will no longer pose a threat to public health and safety.

When first extracted, spent fuel rods are stored in shielded basins of water (spent fuel pools), usually located on-site. The water provides both cooling for the still-decaying fission products, and shielding from the continuing radioactivity. After a period of time (generally five years for US plants), the now cooler, less radioactive fuel is typically moved to a dry-storage facility or dry cask storage, where the fuel is stored in steel and concrete containers. Most U.S. waste is currently stored at the nuclear site where it is generated, while suitable permanent disposal methods are discussed.

As of 2007, the United States had accumulated more than 50,000 metric tons of spent nuclear fuel from nuclear reactors.[59] Permanent storage underground in U.S. had been proposed at the Yucca Mountain nuclear waste repository, but that project has now been effectively cancelled - the permanent disposal of the U.S.'s high-level waste is an as-yet unresolved political problem.[60]

The amount of high-level waste can be reduced in several ways, particularly Nuclear reprocessing. Even so, the remaining waste will be substantially radioactive for at least 300 years even if the actinides are removed, and for up to thousands of years if the actinides are left in. Even with separation of all actinides, and using fast breeder reactors to destroy by transmutation some of the longer-lived non-actinides as well, the waste must be segregated from the environment for one to a few hundred years, and therefore this is properly categorized as a long-term problem. Subcritical reactors or fusion reactors could also reduce the time the waste has to be stored.[61] It has been argued that the best solution for the nuclear waste is above ground temporary storage since technology is rapidly changing. Some people believe that current waste might become a valuable resource in the future.

According to a 2007 story broadcast on 60 Minutes, nuclear power gives France the cleanest air of any industrialized country, and the cheapest electricity in all of Europe.[62] France reprocesses its nuclear waste to reduce its mass and make more energy.[63] However, the article continues, "Today we stock containers of waste because currently scientists don't know how to reduce or eliminate the toxicity, but maybe in 100 years perhaps scientists will... Nuclear waste is an enormously difficult political problem which to date no country has solved. It is, in a sense, the Achilles heel of the nuclear industry... If France is unable to solve this issue, says Mandil, then 'I do not see how we can continue our nuclear program.'"[63] Further, reprocessing itself has its critics, such as the Union of Concerned Scientists.[64]

Low-level radioactive waste

The nuclear industry also produces a huge volume of low-level radioactive waste 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. In the United States, the Nuclear Regulatory Commission has repeatedly attempted to allow low-level materials to be handled as normal waste: landfilled, recycled into consumer items, et cetera. Most low-level waste releases very low levels of radioactivity and is only considered radioactive waste because of its history.[65]

Comparing radioactive waste to industrial toxic waste

In countries with nuclear power, radioactive wastes comprise less than 1% of total industrial toxic wastes, much of which remains hazardous indefinitely.[50] Overall, nuclear power produces far less waste material by volume than fossil-fuel based power plants. Coal-burning plants are particularly noted for producing large amounts of toxic and mildly radioactive ash due to concentrating naturally occurring metals and mildly radioactive material from the coal. A recent report from Oak Ridge National Laboratory concludes 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 as much as from ideal operation of nuclear plants.[66] Indeed, coal ash is much less radioactive than nuclear waste, but ash is released directly into the environment, whereas nuclear plants use shielding to protect the environment from the irradiated reactor vessel, fuel rods, and any radioactive waste on site.[67]

Reprocessing

Reprocessing can potentially recover up to 95% of the remaining uranium and plutonium in spent nuclear fuel, putting it into new mixed oxide fuel. This produces a reduction in long term radioactivity within the remaining waste, since this is largely short-lived fission products, and reduces its volume by over 90%. Reprocessing of civilian fuel from power reactors is currently done on large scale in Britain, France and (formerly) Russia, soon will be done in China and perhaps India, and is being done on an expanding scale in Japan. The full potential of reprocessing has not been achieved because it requires breeder reactors, which are not yet commercially available. France is generally cited as the most successful reprocessor, but it presently only recycles 28% (by mass) of the yearly fuel use, 7% within France and another 21% in Russia.[68]

Unlike other countries, the US stopped civilian reprocessing from 1976 to 1981 as one part of US non-proliferation policy, since reprocessed material such as plutonium could be used in nuclear weapons: however, reprocessing is not allowed in the U.S.[69] In the U.S., spent nuclear fuel is currently all treated as waste.[70]

In February, 2006, a new U.S. initiative, the Global Nuclear Energy Partnership was announced. It is an international effort aimed to reprocess fuel in a manner making nuclear proliferation unfeasible, while making nuclear power available to developing countries.[71]

Depleted uranium

Uranium enrichment produces many tons of depleted uranium (DU) which consists of U-238 with most of the easily fissile U-235 isotope removed. U-238 is a tough metal with several commercial uses—for example, aircraft production, radiation shielding, and armor—as it has a higher density than lead. Depleted uranium is also useful in munitions as DU penetrators (bullets or APFSDS tips) "self sharpen", due to uranium's tendency to fracture along shear bands.[72][73]

There are concerns that U-238 may lead to health problems in groups exposed to this material excessively, such as tank crews and civilians living in areas where large quantities of DU ammunition have been used in shielding, bombs, missile warheads, and bullets. In January 2003 the World Health Organization released a report finding that contamination from DU munitions were localized to a few tens of meters from the impact sites and contamination of local vegetation and water was 'extremely low'. The report also states that approximately 70% of ingested DU will leave the body after twenty four hours and 90% after a few days.[74]

Economics

The economics of nuclear power plants are primarily influenced by the high initial investment necessary to construct a plant. In 2009, estimates for the cost of a new plant in the U.S. ranged from $6 to $10 billion. It is therefore usually more economical to run them as long as possible, or construct additional reactor blocks in existing facilities. In 2008, new nuclear power plant construction costs were rising faster than the costs of other types of power plants.[75][76] A prestigious panel assembled for a 2003 MIT study of the industry found the following:

In deregulated markets, nuclear power is not now cost competitive with coal and natural gas. However, plausible reductions by industry in capital cost, operation and maintenance costs, and construction time could reduce the gap. Carbon emission credits, if enacted by government, can give nuclear power a cost advantage.
—The Future of Nuclear Power[77]

Comparative economics with other power sources are also discussed in the Main article above and in nuclear power debate.

Accidents and safety

Nine nuclear power plant accidents with more than US$300 million in property damage, to 2010[78][79][80]
Date Location Description Cost
(in millions
2006 $)
December 7, 1975 Greifswald, East Germany Electrician's error causes fire in the main trough that destroys control lines and five main coolant pumps US$443
February 22, 1977 Jasłovske Bohunice, Czechoslovakia Severe corrosion of reactor and release of radioactivity into the plant area, necessitating total decommission US$1,700
March 28, 1979 Middletown, Pennsylvania, US Loss of coolant and partial core meltdown, see Three Mile Island accident and Three Mile Island accident health effects US$2,400
March 9, 1985 Athens, Alabama, US Instrumentation systems malfunction during startup, which led to suspension of operations at all three Browns Ferry Units - operations restarted in 1991 for unit 2, in 1995 for unit 3, and (after a $1.8 billion recommissioning operation) in 2007 for unit 3 US$1,830
April 11, 1986 Plymouth, Massachusetts, US Recurring equipment problems force emergency shutdown of Boston Edison's Pilgrim Nuclear Power Plant US$1,001
April 26, 1986 Chernobyl, Kiev, Ukraine Steam explosion and meltdown with 57 deaths (see Chernobyl disaster) necessitating the evacuation of 300,000 people from Kiev and dispersing radioactive material across Europe (see Chernobyl disaster effects) US$6,700
March 31, 1987 Delta, Pennsylvania, US Peach Bottom units 2 and 3 shutdown due to cooling malfunctions and unexplained equipment problems US$400
September 2, 1996 Crystal River, Florida, US Balance-of-plant equipment malfunction forces shutdown and extensive repairs at Crystal River Unit 3 US$384
February 1, 2010 Montpelier, Vermont, US Deteriorating underground pipes from the Vermont Yankee Nuclear Power Plant leak radioactive tritium into groundwater supplies US$10 [81]

Environmental effects of nuclear power

A 2008 synthesis of 103 studies, published by Benjamin K. Sovacool, determined that the value of CO2 emissions for nuclear power over the lifecycle of a plant was 66.08 g/kWh, based on the mean value of all the 103 studies. Comparative results for wind power, hydroelectricity, solar thermal power, and solar photovoltaic were 9-10 g/kWh, 10-13 g/kWh, 13 g/kWh and 32 g/kWh respectively.[82]

Comparisons of life-cycle greenhouse gas emissions

Comparisons of life cycle analysis (LCA) of carbon dioxide emissions show nuclear power as comparable to renewable energy sources.[83][84] A conclusion that is disputed by others studies.[85]

Debate on nuclear power

The nuclear power debate is about the controversy[86][87][88] which has surrounded the deployment and use of nuclear fission reactors to generate electricity from nuclear fuel for civilian purposes. The debate about nuclear power peaked during the 1970s and 1980s, when it "reached an intensity unprecedented in the history of technology controversies", in some countries.[89][90]

Proponents of nuclear energy contend that nuclear power is a sustainable energy source that reduces carbon emissions and increases energy security by decreasing dependence on foreign oil.[91] Proponents claim that nuclear power produces virtually no conventional air pollution, such as greenhouse gases and smog, in contrast to the chief viable alternative of fossil fuel. Proponents also believe that nuclear power is the only viable course to achieve energy independence for most Western countries. Proponents claim that the risks of storing waste are small and can be further reduced by using the latest technology in newer reactors, and the operational safety record in the Western world is excellent when compared to the other major kinds of power plants.[92]

Opponents believe that nuclear power poses many threats to people and the environment.[93][94][95] These threats include the problems of processing, transport and storage of radioactive nuclear waste, the risk of nuclear weapons proliferation and terrorism, as well as health risks and environmental damage from uranium mining.[96][97] They also contend that reactors themselves are enormously complex machines where many things can and do go wrong, and there have been serious nuclear accidents.[79][98] Critics do not believe that the risks of using nuclear fission as a power source can be offset through the development of new technology. They also argue that when all the energy-intensive stages of the nuclear fuel chain are considered, from uranium mining to nuclear decommissioning, nuclear power is not a low-carbon electricity source.[99][100][101]

Arguments of economics and safety are used by both sides of the debate.

Nuclear power organizations

Against

Supportive

Future of the industry

Diablo Canyon Power Plant in San Luis Obispo County, California, USA

As of 2007, Watts Bar 1, which came on-line in February 7, 1996, was the last U.S. commercial nuclear reactor to go on-line. This is often quoted as evidence of a successful worldwide campaign for nuclear power phase-out. However, even in the U.S. and throughout Europe, investment in research and in the nuclear fuel cycle has continued, and some nuclear industry experts[105] predict electricity shortages, fossil fuel price increases, global warming and heavy metal emissions from fossil fuel use, new technology such as passively safe plants, and national energy security will renew the demand for nuclear power plants.

According to the World Nuclear Association, globally during the 1980s one new nuclear reactor started up every 17 days on average, and by the year 2015 this rate could increase to one every 5 days.[106]

Brunswick Nuclear Plant discharge canal

Many countries remain active in developing nuclear power, including China, India, Japan and Pakistan. all actively developing both fast and thermal technology, South Korea and the United States, developing thermal technology only, and South Africa and China, developing versions of the Pebble Bed Modular Reactor (PBMR). Several EU member states actively pursue nuclear programs, while some other member states continue to have a ban for the nuclear energy use. Japan has an active nuclear construction program with new units brought on-line in 2005. In the U.S., three consortia responded in 2004 to the U.S. Department of Energy's solicitation under the Nuclear Power 2010 Program and were awarded matching funds—the Energy Policy Act of 2005 authorized loan guarantees for up to six new reactors, and authorized the Department of Energy to build a reactor based on the Generation IV Very-High-Temperature Reactor concept to produce both electricity and hydrogen. As of the early 21st century, nuclear power is of particular interest to both China and India to serve their rapidly growing economies—both are developing fast breeder reactors. (See also energy development). In the energy policy of the United Kingdom it is recognized that there is a likely future energy supply shortfall, which may have to be filled by either new nuclear plant construction or maintaining existing plants beyond their programmed lifetime.

There is a possible impediment to production of nuclear power plants as only a few companies worldwide have the capacity to forge single-piece reactor pressure vessels,[107] which are necessary in most reactor designs. Utilities across the world are submitting orders years in advance of any actual need for these vessels. Other manufacturers are examining various options, including making the component themselves, or finding ways to make a similar item using alternate methods.[108] Other solutions include using designs that do not require single-piece forged pressure vessels such as Canada's Advanced CANDU Reactors or Sodium-cooled Fast Reactors.

This graph illustrates the potential rise in CO2 emissions if base-load electricity currently produced in the U.S. by nuclear power were replaced by coal or natural gas as current reactors go offline after their 60 year licenses expire. Note: graph assumes all 104 American nuclear power plants receive license extensions out to 60 years.

China plans to build more than 100 plants,[109] while in the US the licenses of almost half its reactors have already been extended to 60 years,[110] and plans to build more than 30 new ones are under consideration.[111] Further, the U.S. NRC and the U.S. Department of Energy have initiated research into Light water reactor sustainability which is hoped will lead to allowing extensions of reactor licenses beyond 60 years, in increments of 20 years, provided that safety can be maintained, as the loss in non-CO2-emitting generation capacity by retiring reactors "may serve to challenge U.S. energy security, potentially resulting in increased greenhouse gas emissions, and contributing to an imbalance between electric supply and demand."[112] In 2008, the International Atomic Energy Agency (IAEA) predicted that nuclear power capacity could double by 2030, though that would not be enough to increase nuclear's share of electricity generation.[113]

See also

References

  1. 1.0 1.1 1.2 World Nuclear Association. Another drop in nuclear generation World Nuclear News, 05 May 2010.
  2. (PDF) Key World Energy Statistics 2007. International Energy Agency. 2007. http://www.iea.org/textbase/nppdf/free/2007/key_stats_2007.pdf. Retrieved 2008-06-21. 
  3. "Nuclear Power Plants Information. Number of Reactors Operation Worldwide". International Atomic Energy Agency. http://www.iaea.org/cgi-bin/db.page.pl/pris.oprconst.htm. Retrieved 2008-06-21. 
  4. "World Nuclear Power Reactors 2007-08 and Uranium Requirements". World Nuclear Association. 2008-06-09. http://www.uic.com.au/reactors.htm. Retrieved 2008-06-21. 
  5. 5.0 5.1 Trevor Findlay (2010). The Future of Nuclear Energy to 2030 and its Implications for Safety, Security and Nonproliferation: Overview, The Centre for International Governance Innovation (CIGI), Waterloo, Ontario, Canada, pp. 10-11.
  6. Mycle Schneider, Steve Thomas, Antony Froggatt, and Doug Koplow (August 2009). The World Nuclear Industry Status Report 2009 Commissioned by German Federal Ministry of Environment, Nature Conservation and Reactor Safety, p. 5.
  7. "Summary status for the US". Energy Information Administration. 2010-01-21. http://www.eia.doe.gov/cneaf/electricity/epa/epates.html. Retrieved 2010-02-18. 
  8. Eleanor Beardsley (2006). "France Presses Ahead with Nuclear Power". NPR. http://www.npr.org/templates/story/story.php?storyId=5369610. Retrieved 2006-11-08. 
  9. "Gross electricity generation, by fuel used in power-stations". Eurostat. 2006. http://epp.eurostat.ec.europa.eu/portal/page?_pageid=1996,39140985&_dad=portal&_schema=PORTAL&screen=detailref&language=en&product=sdi_cc&root=sdi_cc/sdi_cc/sdi_cc_ene/sdi_cc2300. Retrieved 2007-02-03. 
  10. Nuclear Power Generation, US Industry Report" IBISWorld, August 2008
  11. "Nuclear Icebreaker Lenin". Bellona. 2003-06-20. http://www.bellona.org/english_import_area/international/russia/civilian_nuclear_vessels/icebreakers/30131. Retrieved 2007-11-01. 
  12. David Baurac (2002). "Passively safe reactors rely on nature to keep them cool". Logos (Argonne National Laboratory) 20 (1). http://www.anl.gov/Media_Center/logos20-1/passive01.htm. Retrieved 2007-11-01. 
  13. Introduction to Fusion Energy, J. Reece Roth, 1986.
  14. "Otto Hahn, The Nobel Prize in Chemistry, 1944". http://www.nobelprize.org. http://nobelprize.org/nobel_prizes/chemistry/laureates/1944/hahn-bio.html. Retrieved 2007-11-01. 
  15. "Otto Hahn, Fritz Strassmann, and Lise Meitner". http://www.chemheritage.org. http://www.chemheritage.org/classroom/chemach/atomic/hahn-meitner.html. Retrieved 2007-11-01. 
  16. "Otto Robert Frisch". http://www.nuclearfiles.org. http://www.nuclearfiles.org/menu/library/biographies/bio_frisch-otto.htm. Retrieved 2007-11-01. 
  17. 17.0 17.1 Kragh, Helge (1999). Quantum Generations: A History of Physics in the Twentieth Century. Princeton NJ: Princeton University Press. p. 286. ISBN 0691095523. 
  18. "From Obninsk Beyond: Nuclear Power Conference Looks to Future". International Atomic Energy Agency. http://www.iaea.org/NewsCenter/News/2004/obninsk.html. Retrieved 2006-06-27. 
  19. "Nuclear Power in Russia". World Nuclear Association. http://world-nuclear.org/info/inf45.htm. Retrieved 2006-06-27. 
  20. "This Day in Quotes: SEPTEMBER 16 - Too cheap to meter: the great nuclear quote debate". This day in quotes. 2009. http://www.thisdayinquotes.com/2009/09/too-cheap-to-meter-nuclear-quote-debate.html. Retrieved 2009-09-16. 
  21. Pfau, Richard (1984) No Sacrifice Too Great: The Life of Lewis L. Strauss University Press of Virginia, Charlottesville, Virginia, p. 187, ISBN 978-0-8139-1038-3
  22. David Bodansky (2004). Nuclear Energy: Principles, Practices, and Prospects. Springer. p. 32. ISBN 9780387207780. http://books.google.com/?id=qBqbr8uV9c8C&pg=PA32&dq=strauss+son+cheap+meter. Retrieved 2008-01-31. 
  23. "On This Day: October 17". BBC News. 1956-10-17. http://news.bbc.co.uk/onthisday/hi/dates/stories/october/17/newsid_3147000/3147145.stm. Retrieved 2006-11-09. 
  24. 24.0 24.1 "50 Years of Nuclear Energy" (PDF). International Atomic Energy Agency. http://www.iaea.org/About/Policy/GC/GC48/Documents/gc48inf-4_ftn3.pdf. Retrieved 2006-11-09. 
  25. The Changing Structure of the Electric Power Industry p. 110.
  26. Bernard L. Cohen. "THE NUCLEAR ENERGY OPTION". Plenum Press. http://www.phyast.pitt.edu/~blc/book/chapter9.html. Retrieved December 2007. 
  27. Evolution of Electricity Generation by FuelPDF (39.4 KB)
  28. Sharon Beder, 'The Japanese Situation', English version of conclusion of Sharon Beder, "Power Play: The Fight to Control the World's Electricity", Soshisha, Japan, 2006.
  29. Lutz Mez, Mycle Schneider and Steve Thomas (Eds.) (2009). International Perspectives of Energy Policy and the Role of Nuclear Power, Multi-Science Publishing Co. Ltd, p. 279.
  30. Matthew L. Wald. Nuclear Agency's Chief Praises Watchdog Groups, The New York Times, June 23, 1992.
  31. "The Rise and Fall of Nuclear Power". Public Broadcasting Service. http://www.pbs.org/wgbh/pages/frontline/shows/reaction/maps/chart2.html. Retrieved 2006-06-28. 
  32. Wolfgang Rudig (1990). Anti-nuclear Movements: A World Survey of Opposition to Nuclear Energy, Longman, p. 1.
  33. "The Political Economy of Nuclear Energy in the United States" (PDF). Social Policy. The Brookings Institution. 2004. http://www.brookings.edu/~/media/Files/rc/papers/2004/09environment_nivola/pb138.pdf. Retrieved 2006-11-09. 
  34. "Backgrounder on Chernobyl Nuclear Power Plant Accident". Nuclear Regulatory Commission. http://www.nrc.gov/reading-rm/doc-collections/fact-sheets/chernobyl-bg.html. Retrieved 2006-06-28. 
  35. "Italy rejoins the nuclear family". World Nuclear News. 2009-07-10. http://www.world-nuclear-news.org/NP_Italy_rejoins_the_nuclear_family_1007091.html. Retrieved 2009-07-17. 
  36. "Neutrons and gammas from Cf-252". Health Physics Society. http://www.hps.org/publicinformation/ate/q6333.html. Retrieved September 24, 2008. 
  37. 37.0 37.1 "DOE Fundamentals Handbook: Nuclear Physics and Reactor Theory" (PDF). US Department of Energy. http://www.hss.doe.gov/nuclearsafety/ns/techstds/standard/hdbk1019/h1019v2.pdf. Retrieved February 1, 2009. 
  38. "Reactor Protection & Engineered Safety Feature Systems". The Nuclear Tourist. http://www.nucleartourist.com/systems/rp.htm. Retrieved September 25, 2008. 
  39. "How nuclear power works". HowStuffWorks.com. http://science.howstuffworks.com/nuclear-power3.htm. Retrieved September 25, 2008. 
  40. "Ending the Production of Highly Enriched Uranium for Naval Reactors" (PDF). James Martin Center for Nonproliferation Studies. http://cns.miis.edu/pubs/npr/vol08/81/81mahip.pdf. Retrieved September 25, 2008. 
  41. "Next-generation Nuclear Technology: The ESBWR" (PDF). American Nuclear Society. http://www.ans.org/pubs/magazines/nn/docs/2006-1-3.pdf. Retrieved September 25, 2008. 
  42. "How to Build a Safer Reactor". TIME.com. 1991-04-29. http://www.time.com/time/magazine/article/0,9171,972829,00.html. Retrieved September 25, 2008. 
  43. "Fusion energy: the agony, the ecstasy and alternatives". PhysicsWorld.com. http://physicsworld.com/cws/article/print/1866. Retrieved September 25, 2008. 
  44. admin (2009-10-13). "Nuclear Power Is Flexible - Claverton Energy Group". Claverton-energy.com. http://www.claverton-energy.com/nuclear-power-is-flexible-in-its-output.html. Retrieved 2010-08-24. 
  45. Steve Kidd. Nuclear in France - what did they get right? Nuclear Engineering International, June 22, 2009.
  46. ""Uranium resources sufficient to meet projected nuclear energy requirements long into the future"". Nuclear Energy Agency (NEA). June 3, 2008. http://www.nea.fr/html/general/press/2008/2008-02.html. Retrieved 2008-06-16. 
  47. NEA, IAEA: Uranium 2007 – Resources, Production and Demand. OECD Publishing, June 10, 2008, ISBN 978-92-64-04766-2.
  48. [1] [2] James Jopf (2004). "World Uranium Reserves". American Energy Independence. http://www.americanenergyindependence.com/uranium.html. Retrieved 2006-11-10.  [3] [4]
  49. "Uranium in a global context". http://www.uraniumworld.org. 
  50. 50.0 50.1 50.2 "Waste Management in the Nuclear Fuel Cycle". Information and Issue Briefs. World Nuclear Association. 2006. http://www.world-nuclear.org/info/inf04.html. Retrieved 2006-11-09. 
  51. John McCarthy (2006). "Facts From Cohen and Others". Progress and its Sustainability. Stanford. http://www-formal.stanford.edu/jmc/progress/cohen.html. Retrieved 2006-11-09.  Citing Breeder reactors: A renewable energy source, American Journal of Physics, vol. 51, (1), Jan. 1983.
  52. "Advanced Nuclear Power Reactors". Information and Issue Briefs. World Nuclear Association. 2006. http://www.world-nuclear.org/info/inf08.html. Retrieved 2006-11-09. 
  53. "Thorium". Information and Issue Briefs. World Nuclear Association. 2006. http://www.world-nuclear.org/info/inf62.html. Retrieved 2006-11-09. 
  54. J. Ongena; G. Van Oost. ""Energy for Future Centuries: Will fusion be an inexhaustible, safe and clean energy source?"" (PDF). http://www.fusie-energie.nl/artikelen/ongena.pdf. Retrieved 2008-01-31. 
  55. M. I. Ojovan, W.E. Lee. An Introduction to Nuclear Waste Immobilisation, Elsevier Science Publishers B.V., Amsterdam, 315pp. (2005).
  56. "Radioactive Waste Management". World-nuclear.org. http://www.world-nuclear.org/info/inf04.html. Retrieved 2010-08-24. 
  57. "Nuclear Waste Management". World Nuclear Association. November 2007. http://world-nuclear.org/education/wast.htm. Retrieved January 2009. 
  58. World Energy Resources, Brown, Charles E. Springer-Verlag Press
  59. "Safely Managing Used Nuclear Fuel". Nuclear Energy Institute. http://www.nei.org/keyissues/nuclearwastedisposal/factsheets/safelymanagingusednuclearfuel/. Retrieved 2008-04-25. 
  60. "Nuclear waste piles up, and it's costing taxpayers billions". Csmonitor.com. 2010-03-24. http://www.csmonitor.com/USA/2010/0324/Nuclear-waste-piles-up-and-it-s-costing-taxpayers-billions. Retrieved 2010-08-24. 
  61. "Accelerator-driven Nuclear Energy". Information and Issue Briefs. World Nuclear Association. 2003. http://www.world-nuclear.org/info/inf35.htm. Retrieved 2006-11-09. 
  62. Steve Kroft (April 8, 2007). ""France: Vive Les Nukes"". 60 Minutes. http://www.cbsnews.com/stories/2007/04/06/60minutes/main2655782.shtml. Retrieved 2008-01-31. 
  63. 63.0 63.1 Jon Palfreman. "Why the French like nuclear energy". PBS Frontline. http://www.pbs.org/wgbh/pages/frontline/shows/reaction/readings/french.html. 
  64. Nuclear Reprocessing: Dangerous, Dirty, and Expensive: Why Extracting Plutonium from Spent Nuclear Reactor Fuel Is a Bad Idea PDF (174 KB)
  65. "Low-Level Waste". U.S. Nuclear Regulatory Commission. 2007-02-13. http://www.nrc.gov/waste/low-level-waste.html. Retrieved 2009-04-06. 
  66. Alex Gabbard. "Coal Combustion: Nuclear Resource or Danger". Oak Ridge National Laboratory. http://www.ornl.gov/info/ornlreview/rev26-34/text/colmain.html. Retrieved 2008-01-31. 
  67. "Coal ash is not more radioactive than nuclear waste". CE Journal. 2008-12-31. http://www.cejournal.net/?p=410. 
  68. IEEE Spectrum: Nuclear Wasteland. Retrieved on 2007-04-22
  69. "Nuclear Fuel Reprocessing: U.S. Policy Development" (PDF). http://www.fas.org/sgp/crs/nuke/RS22542.pdf. Retrieved 2009-07-25. 
  70. Processing of Used Nuclear Fuel for Recycle. WNA
  71. Baker, Peter; Linzer, Dafna (2006-01-26). "Nuclear Energy Plan Would Use Spent Fuel". Washington Post (2007-01-26). http://www.washingtonpost.com/wp-dyn/content/article/2006/01/25/AR2006012502229.html. Retrieved 2007-01-31. 
  72. Hambling, David (July 30, 2003). "'Safe' alternative to depleted uranium revealed". New Scientist. http://www.newscientist.com/article/dn4004-safe-alternative-to-depleted-uranium-revealed.html. Retrieved 2008-07-16. 
  73. Stevens, J. B.; R. C. Batra. "Adiabatic Shear Banding in Axisymmetric Impact and Penetration Problems". Virginia Polytechnic Institute and State University. http://www.sv.vt.edu/research/batra-stevens/pent.html. Retrieved 2008-07-16. 
  74. "Depleted uranium". World Health Organization. January 2003. http://www.who.int/mediacentre/factsheets/fs257/en/index.html. Retrieved 2008-07-16. 
  75. Maryland PIRG Foundation. "The High Cost of Nuclear Power." (2009).http://www.nirs.org/nukerelapse/calvert/highcostnpower_mdpirg.pdf. Retrieved 8-13-2009.
  76. Lovins, A. B.; Sheikh, I. Rocky Mountain Institute. "The Nuclear Illusion" (May 2008 Ambio preprint). http://www.rmi.org/images/PDFs/Energy/E08-01_AmbioNuclIlusion.pdf. Retrieved 8-13-2009.
  77. Massachusetts Institute of Technology. "The Future of Nuclear Power" (2003). http://web.mit.edu/nuclearpower/pdf/nuclearpower-summary.pdf. Retrieved 8-13-2009.
  78. Benjamin K. Sovacool (2009). The Accidental Century - Prominent Energy Accidents in the Last 100 Years
  79. 79.0 79.1 Benjamin K. Sovacool. The costs of failure: A preliminary assessment of major energy accidents, 1907–2007, Energy Policy 36 (2008), pp. 1802-1820.
  80. Benjamin K. Sovacool. A Critical Evaluation of Nuclear Power and Renewable Electricity in Asia, Journal of Contemporary Asia, Vol. 40, No. 3, August 2010, pp. 369–400.
  81. Report details efforts to prevent isotope from reaching Vt. water supplies www.boston.com
  82. Benjamin K. Sovacool. Valuing the greenhouse gas emissions from nuclear power: A critical survey. Energy Policy, Vol. 36, 2008, p. 2950.
  83. Energy Balances and CO2 Implications World Nuclear Association November 2005
  84. "Life-cycle emissions analyses". Nei.org. http://www.nei.org/keyissues/protectingtheenvironment/lifecycleemissionsanalysis/. Retrieved 2010-08-24. 
  85. Benjamin K. Sovacool. Valuing the greenhouse gas emissions from nuclear power: A critical survey. Energy Policy, Vol. 36, 2008, p. 2950.
  86. James J. MacKenzie. Review of The Nuclear Power Controversy by Arthur W. Murphy The Quarterly Review of Biology, Vol. 52, No. 4 (Dec., 1977), pp. 467-468.
  87. J. Samuel Walker (2004). Three Mile Island: A Nuclear Crisis in Historical Perspective (Berkeley: University of California Press), pp. 10-11.
  88. In February 2010 the nuclear power debate played out on the pages of the New York Times, see A Reasonable Bet on Nuclear Power and Revisiting Nuclear Power: A Debate and A Comeback for Nuclear Power?
  89. Herbert P. Kitschelt. Political Opportunity and Political Protest: Anti-Nuclear Movements in Four Democracies British Journal of Political Science, Vol. 16, No. 1, 1986, p. 57.
  90. Jim Falk (1982). Global Fission: The Battle Over Nuclear Power, Oxford University Press.
  91. U.S. Energy Legislation May Be 'Renaissance' for Nuclear Power.
  92. Bernard Cohen. "The Nuclear Energy Option". http://www.phyast.pitt.edu/~blc/book/BOOK.html. Retrieved 2009-12-09. 
  93. Share. "Nuclear Waste Pools in North Carolina". Projectcensored.org. http://www.projectcensored.org/top-stories/articles/4-nuclear-waste-pools-in-north-carolina/. Retrieved 2010-08-24. 
  94. NC WARN » Nuclear Power
  95. Sturgis, Sue. "Investigation: Revelations about Three Mile Island disaster raise doubts over nuclear plant safety". Southernstudies.org. http://www.southernstudies.org/2009/04/post-4.html. Retrieved 2010-08-24. 
  96. Greenpeace International and European Renewable Energy Council (January 2007). Energy Revolution: A Sustainable World Energy Outlook, p. 7.
  97. Giugni, Marco (2004). Social Protest and Policy Change: Ecology, Antinuclear, and Peace Movements.
  98. Stephanie Cooke (2009). In Mortal Hands: A Cautionary History of the Nuclear Age, Black Inc., p. 280.
  99. Kurt Kleiner. Nuclear energy: assessing the emissions Nature Reports, Vol. 2, October 2008, pp. 130-131.
  100. Mark Diesendorf (2007). Greenhouse Solutions with Sustainable Energy, University of New South Wales Press, p. 252.
  101. Mark Diesendorf. Is nuclear energy a possible solution to global warming?
  102. "About Friends of the Earth International". Friends of the Earth International. http://www.foei.org/en/who-we-are/about. Retrieved 2009-06-25. 
  103. "United Nations, Department of Public Information, Non-Governmental Organizations". Un.org. 2006-02-23. http://www.un.org/dpi/ngosection/dpingo-directory.asp?RegID=--&CnID=all&AcID=0&kw=greenpeace&NGOID=550. Retrieved 2010-08-24. 
  104. Background - January 7, 2010 (2010-01-07). "Greenpeace International: Greenpeace worldwide". Greenpeace.org. http://www.greenpeace.org/international/about/worldwide. Retrieved 2010-08-24. 
  105. "Nuclear Energy's Role in Responding to the Energy Challenges of the 21st Century" (PDF). Idaho National Engineering and Environmental Laboratory. http://nuclear.inl.gov/docs/papers-presentations/ga_tech_woodruff_3-4.pdf. Retrieved 2008-06-21. 
  106. Plans For New Reactors Worldwide, World Nuclear Association
  107. New nuclear build – sufficient supply capability? Steve Kid, Nuclear Engineering International, 3/3/2009
  108. Bloomberg exclusive: Samurai-Sword Maker's Reactor Monopoly May Cool Nuclear Revival By Yoshifumi Takemoto and Alan Katz, bloomberg.com, 3/13/08.
  109. Pfister, Bonnie (2008-06-28). "China wants 100 Westinghouse reactors". Pittsburgh Tribune-Review. http://www.pittsburghlive.com/x/pittsburghtrib/s_575073.html. Retrieved 2008-07-25. 
  110. "Nuclear Power in the USA". World Nuclear Association. June 2008. http://www.world-nuclear.org/info/inf41.html#licence. Retrieved 2008-07-25. 
  111. "Expected New Nuclear Power Plant Applications" (PDF). U.S. Nuclear Regulatory Commission. 2009-09-28. http://www.nrc.gov/reactors/new-reactors/new-licensing-files/expected-new-rx-applications.pdf. Retrieved 2010-01-08. 
  112. ""NRC/DOE Life After 60 Workshop Report"" (PDF). 2008. http://www.energetics.com/nrcdoefeb08/pdfs/Life%20After%2060%20Workshop%20Report.pdf. Retrieved 2009-04-01. 
  113. "Nuclear's Great Expectations: Projections Continue to Rise for Nuclear Power, but Relative Generation Share Declines". International Atomic Energy Agency (IAEA). 2008-09-11. http://www.iaea.org/NewsCenter/News/2008/np2008.html. Retrieved 2008-09-20. 

Further reading

External links