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Environmental impact of nuclear power

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Greenhouse gas emissions per energy source. Nuclear power is one of the sources with the least greenhouse gas emissions.
Nuclear power activities involving the environment; mining, enrichment, generation and geological disposal.

Nuclear power has various environmental impacts, both positive and negative, including the construction and operation of the plant, the nuclear fuel cycle, and the effects of nuclear accidents. Nuclear power plants do not burn fossil fuels and so do not directly emit carbon dioxide. The carbon dioxide emitted during mining, enrichment, fabrication and transport of fuel is small when compared with the carbon dioxide emitted by fossil fuels of similar energy yield, however, these plants still produce other environmentally damaging wastes.[1] Nuclear energy and renewable energy have reduced environmental costs by decreasing CO2 emissions resulting from energy consumption.[2]

There is a catastrophic risk potential if containment fails,[3] which in nuclear reactors can be brought about by overheated fuels melting and releasing large quantities of fission products into the environment.[4] In normal operation, nuclear power plants release less radioactive material than coal power plants whose fly ash contains significant amounts of thorium, uranium and their daughter nuclides.[5]

A large nuclear power plant may reject waste heat to a natural body of water; this can result in undesirable increase of the water temperature with adverse effect on aquatic life. Alternatives include cooling towers.[6]

The Onagawa Nuclear Power Plant – a plant that cools by direct use of ocean water, not requiring a cooling tower

Mining of uranium ore can disrupt the environment around the mine. However, with modern in-situ leaching technology this impact can be reduced compared to "classical" underground or open-pit mining. Disposal of spent nuclear fuel is controversial, with many proposed long-term storage schemes under intense review and criticism. Diversion of fresh- or low-burnup spent fuel to weapons production presents a risk of nuclear proliferation, however all nuclear weapons states derived the material for their first nuclear weapon from (non-power) research reactors or dedicated "production reactors" and/or uranium enrichment. Finally, some parts the structure of the reactor itself becomes radioactive through neutron activation and will require decades of storage before it can be economically dismantled and in turn disposed of as waste. Measures like reducing the cobalt content in steel to decrease the amount of cobalt-60 produced by neutron capture can reduce the amount of radioactive material produced and the radiotoxicity that originates from this material.[7] However, part of the issue is not radiological but regulatory as most countries assume any given object that originates from the "hot" (radioactive) area of a nuclear power plant or a facility in the nuclear fuel cycle is ipso facto radioactive, even if no contamination or neutron irradiation induced radioactivity is detectable.

Waste streams

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Nuclear power has at least three waste streams that may impact the environment:[8]

  1. Spent nuclear fuel at the reactor site (including fission products and plutonium waste)
  2. Tailings and waste rock at uranium mining mills
  3. Releases of ill-defined quantities of radioactive materials during accidents

Nuclear reprocessing and breeder reactors which can decrease the need for storage of spent fuel in a deep geological repository have faced economic and political hurdles but are in some use in Russia, India, China, Japan and France, which are among the countries with the highest nuclear energy production outside the United States. However, the U.S. has not undertaken significant efforts towards either reprocessing or breeder reactors since the 1970s instead relying on the once through fuel cycle.

Radioactive waste

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High-level waste

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Technicians emplacing transuranic waste at the Waste Isolation Pilot Plant, near Carlsbad, New Mexico. Various mishaps at the plant in 2014 brought focus to the problem of what to do with a mounting stockpile of spent fuel, from commercial nuclear reactors, currently stored at individual reactor sites. In 2010, the USDOE mothballed plans to develop the Yucca Mountain nuclear waste repository in Nevada.[9]

The spent nuclear fuel from uranium-235 and plutonium-239 nuclear fission contains a wide variety of carcinogenic radionuclide isotopes such as strontium-90, iodine-131, and caesium-137. Such waste includes some of the most long-lived transuranic elements such as americium-241 and isotopes of plutonium.[10] The most long-lived radioactive wastes, including spent nuclear fuel, usually must be contained and isolated from the environment for a long period of time. Spent nuclear fuel storage is mostly a problem in the United States, following a 1977 prohibition by then-President Jimmy Carter on nuclear fuel recycling. France, The United Kingdom, and Japan are some of the countries that have rejected the repository solution. Spent nuclear fuel produced by some types of reactors is a valuable asset, not simply waste.[11]

Disposal of these wastes in specially-engineered underground repositories is the preferred long-term storage solution.[12] The International Panel on Fissile Materials has said:

It is widely accepted that spent nuclear fuel and high-level reprocessing and plutonium wastes require well-designed storage for long periods of time, to minimize releases of the contained radioactivity into the environment. Safeguards are also required to ensure that neither plutonium nor highly enriched uranium is diverted to weapon use. There is general agreement that placing spent nuclear fuel in repositories hundreds of meters below the surface would be safer than indefinite storage of spent fuel on the surface.[13]

When designing long-term storage facilities, there are several crucial considerations, including the specific type of radioactive waste, the containers enclosing the waste, other engineered barriers or seals around the containers, the tunnels housing the containers, and the geologic makeup of the surrounding area.[14]

The ability of natural geologic barriers to isolate radioactive waste is demonstrated by the natural nuclear fission reactors at Oklo, Africa. During their long reaction period, about 5.4 metric tons of fission products, 1.5 metric tons of plutonium, and other transuranic elements were generated in the uranium ore body. These elements remain immobile and stable to this day, a span of almost 2 billion years.[15]

Despite long-standing agreement among many experts that geological disposal can be safe, technologically feasible, and environmentally sound, a large part of the general public in many countries remains skeptical.[16] One of the challenges facing the supporters of these efforts is to demonstrate confidently that a repository will contain waste for so long that future containment breaches will pose no significant health or environmental risks.

Nuclear reprocessing does not eliminate the need for a repository, but it reduces the required volume, the need for long-term heat dissipation, and the long-term radiation hazard. Reprocessing does not eliminate the political and social challenges to repository siting.[13]

The countries that have made the most progress towards a repository for high-level radioactive waste have typically started with public consultations and made voluntary siting a necessary condition. This consensus-seeking approach is believed to have a greater chance of success than top-down modes of decision making, but the process is necessarily slow, and there is "inadequate experience around the world to know if it will succeed in all existing and aspiring nuclear nations."[17] Moreover, many communities do not want to host a nuclear waste repository as they are "concerned about their community becoming a de facto site for waste for thousands of years, the health and environmental consequences of an accident, and lower property values."[18]

In a 2010 Presidential Memorandum, U.S. President Obama established the Blue Ribbon Commission on America's Nuclear Future.[19] The commission, composed of fifteen members, conducted an extensive two-year study of nuclear waste disposal.[19] During their research, the Commission visited Finland, France, Japan, Russia, Sweden, and the UK, and in 2012, the Commission submitted its final report.[20] The Commission did not issue recommendations for a specific site but rather presented a comprehensive recommendation for disposal strategies.[21] One major recommendation was that "the United States should undertake an integrated nuclear waste management program that leads to the timely development of one or more permanent deep geological facilities for the safe disposal of spent fuel and high-level nuclear waste."[21]

Pressurized heavy water reactors like the Canadian CANDU or the Indian IPHWR do not need enriched fuel and can operate using natural uranium. This allows better use of the energy contained in the initial uranium ore (while higher enrichment allows higher burnup, the amount of natural uranium needed to produce this fuel increases faster than the achievable burnup)[22] and reduces the energy needed in fuel manufacturing as the conversion of the yellowcake to uranium hexafluoride and back into an oxide fuel as well as the energy-intensive enrichment process can be skipped.

Other waste

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Moderate amounts of low-level waste are managed through a chemical and volume control system (CVCS). This includes gas, liquid, and solid waste produced via the process of purifying the water through evaporation. Liquid waste is reprocessed continuously, and gas waste is filtered, compressed, stored to allow decay, diluted, and then discharged. The rate at which this is allowed is regulated and studies must prove that such discharge does not pose public health risks (see radioactive effluent emissions).

Solid waste can be disposed of simply by placing it where it will not be disturbed for a few years. There are three low-level waste disposal sites in the United States, in South Carolina, Utah, and Washington.[23] Solid waste from the CVCS is combined with solid waste that comes from handling materials before it is buried off-site.[24]

Power plant emission

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Radioactive gases and effluents

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The Grafenrheinfeld Nuclear Power Plant. The tallest structure is the chimney that releases effluent gases.

Most commercial nuclear power plants release gaseous and liquid radiological effluents into the environment as a byproduct of the Chemical Volume Control System. These effluents are monitored in the US by the EPA and the NRC. Civilians living within 50 miles (80 km) of a nuclear power plant typically receive about 0.1 μSv per year.[25] For comparison, the average person living at or above sea level receives at least 260 μSv per year from cosmic radiation.[25]

All reactors in the United States are required by law to have a containment building. The walls of containment buildings are several feet thick and made of concrete designed to stop the release of any radiation emitted by the reactor into the environment. For comparison:[26]

The waste produced by coal plants is actually more radioactive than that generated by their nuclear counterparts. In fact, the fly ash emitted by a [coal] power plant—a by-product from burning coal for electricity—carries into the surrounding environment 100 times more radiation than a nuclear power plant producing the same amount of energy. . . . Estimated radiation doses ingested by people living near the coal plants were equal to or higher than doses for people living around the nuclear facilities. At one extreme, the scientists estimated fly ash radiation in individuals' bones at around 18 millirems (thousandths of a rem, a unit for measuring doses of ionizing radiation) a year. Doses for the two nuclear plants, by contrast, ranged from between three and six millirems for the same period. And when all food was grown in the area, radiation doses were 50 to 200 percent higher around the coal plants.

The total amount of radioactivity released through the CVCS depends on the power plant, the regulatory requirements, and the plant's performance. Atmospheric dispersion models combined with pathway models are employed to accurately approximate the exposure to a member of the public from the effluents emitted. Effluent monitoring is conducted continuously at the plant.

Tritium

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Tritium Effluent Limits[citation needed]
Country Limit (Bq/L)
Australia 76,103
Finland 30,000
WHO 10,000
Switzerland 10,000
Russia   7,700
Ontario, Canada   7,000
European Union 1001
United States 740
California Public Health Goal    14.8

A leak of radioactive water at Vermont Yankee in 2010, along with similar incidents at more than 20 other US nuclear plants in recent years, has kindled doubts about the reliability, durability, and maintenance of aging nuclear installations in the United States.[27]

Tritium is a radioactive isotope of hydrogen that emits a low-energy beta particle and is usually measured in becquerels (i.e. atoms decaying per second) per liter (Bq/L). Tritium can be contained in water released from a nuclear plant. The primary concern for tritium release is its presence in drinking water, in addition to biological magnification leading to tritium in crops and animals consumed for food.[28]

Legal concentration limits of tritium have differed greatly from place to place (see table right). For example, in June 2009 the Ontario Drinking Water Advisory Council recommended lowering the limit from 7,000 Bq/L to 20 Bq/L.[29] According to the NRC, tritium is the least dangerous radionuclide because it emits very weak radiation and leaves the body relatively quickly.[citation needed]

Uranium mining

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A drum of yellowcake
Rössing open pit uranium mine, Namibia

Uranium mining is the process of extracting uranium ore from the ground. Kazakhstan, Canada, and Australia are the top three producers and together account for 63% of world uranium production.[30] A prominent use of uranium is as fuel for nuclear power plants. The mining and milling of uranium present significant dangers to the environment.[31]

In 2010, 41% of the world's uranium production was produced by in-situ leaching, which uses solutions to dissolve the uranium while leaving the rock in place.[32] The remainder was produced by conventional mining, in which the mined uranium ore is ground to a uniform particle size and then the uranium extracted by chemical leaching. The product is a powder of unenriched uranium, "yellowcake," which is sold on the uranium market as U3O8. Uranium mining can use large amounts of water—for example, the Roxby Downs Olympic Dam mine in South Australia uses 35,000 m3 of water each day and plans to increase this to 150,000 m3 per day.[33]

The Church Rock uranium mill spill occurred in New Mexico on July 16, 1979, when the tailings disposal pond breached its dam.[34][35] Over 1,000 tons of solid radioactive mill waste and 93 million gallons of acidic, radioactive tailings solution flowed into the Puerco River, and contaminants traveled 80 miles (130 km) downstream to Navajo County, Arizona and onto the Navajo Nation.[35] The accident released more radiation than the Three Mile Island accident that occurred four months earlier and was the largest release of radioactive material in U.S. history, although the radioactive material was diluted by the 93 million gallons of water and sulfuric acid.[35][36][37][38] Groundwater near the spill was contaminated and the Puerco rendered unusable by local residents, who were not immediately aware of the toxic danger.[39]

Despite efforts made in cleaning up Cold War nuclear arms race uranium sites, significant problems stemming from the legacy of uranium development still exist today on the Navajo Nation and in the states of Utah, Colorado, New Mexico, and Arizona. Hundreds of abandoned mines, primarily used for the US arms race and not nuclear energy production, have not been cleaned up and present environmental and health risks in many communities.[40] The Environmental Protection Agency estimates that there are 4,000 mines with documented uranium production, and another 15,000 locations with uranium occurrences in 14 western states,[41] most found in the Four Corners area and Wyoming.[42] The Uranium Mill Tailings Radiation Control Act is a United States environmental law that amended the Atomic Energy Act of 1954 and gave the Environmental Protection Agency the authority to establish health and environmental standards for the stabilization, restoration, and disposal of uranium mill waste.[43]

Cancer

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Numerous studies have been done on the possible relationship between nuclear power and cancer. Such studies have looked for excess cancers in both plant workers and surrounding populations due to releases during normal operations of nuclear plants and other parts of the nuclear power industry, as well as excess cancers in workers and the public due to accidental releases. There is agreement that excess cancers in both plant workers and the surrounding public have been caused by accidental releases such as the Chernobyl accident.[44] There is also agreement that some workers in other parts of the nuclear fuel cycle (most notably uranium mining) have had elevated rates of cancer, at least in past decades.[45] Excess mortality is associated with all mining activity and is not unique to uranium mining.[46] However, numerous studies of possible cancers caused by nuclear power plants in normal operation have come to opposing conclusions, and the issue is a matter of scientific controversy and ongoing study.[47][48][49]

Several epidemiological studies have found that there is an increased risk of various diseases, especially cancers, among people who live near nuclear facilities. A widely cited 2007 meta-analysis by Baker et al. of 17 research papers was published in the European Journal of Cancer Care.[50] It offered evidence of elevated leukemia rates among children living near 136 nuclear facilities in the United Kingdom, Canada, France, United States, Germany, Japan, and Spain. However, this study has been criticized for several reasons, such as its combination of heterogeneous data (different age groups, sites that were not nuclear power plants, different zone definitions), arbitrary selection of 17 out of 37 individual studies, and exclusion of sites with zero observed cases or deaths.[51][52]

Elevated leukemia rates among children were also found in a 2008 German study by Kaatsch et al. that examined residents living near 16 major nuclear power plants in Germany.[50] This study has also been criticized for reasons similar to those described above.[52][53] These 2007 and 2008 results are not consistent with many other studies that have tended not to show such associations.[54][55][56][57][58] The British Committee on Medical Aspects of Radiation in the Environment issued a study in 2011 of children under five living near 13 nuclear power plants in the UK during the period 1969–2004. The committee found that children living near power plants in Britain are no more likely to develop leukemia than those living elsewhere.[52] Similarly, a 1991 study for the National Cancer Institute found no excess cancer mortalities in 107 US counties close to nuclear power plants.[59] However, in view of the ongoing controversy, the US Nuclear Regulatory Commission has requested the National Academy of Sciences to oversee a state-of-the-art study of cancer risk in populations near NRC-licensed facilities.[47]

A subculture of frequently undocumented[clarification needed] nuclear workers do the dirty, difficult, and potentially dangerous work often shunned by regular employees. The World Nuclear Association states that the transient workforce of "nuclear gypsies"—casual workers employed by subcontractors—has been "part of the nuclear scene for at least four decades."[60] Existing labor laws regarding worker health are not always properly enforced.[61] A 15-country collaborative cohort study of cancer risks due to exposure to low-dose ionizing radiation, involving 407,391 nuclear industry workers, showed significant increase in cancer mortality. The study evaluated 31 types of cancers, primary and secondary.[62]

Nuclear power reactor accidents can result in a variety of radioisotopes being released into the environment. The health impact of each radioisotope depends on a variety of factors. Iodine-131 is potentially an important source of morbidity in accidental discharges because of its prevalence and because it settles on the ground. When iodine-131 is released, it can be inhaled or consumed after it enters the food chain, primarily through contaminated fruits, vegetables, milk, and groundwater. Iodine-131 in the body rapidly accumulates in the thyroid gland, becoming a source of beta radiation.[63]

The 2011 Fukushima Daiichi nuclear disaster, the most serious nuclear accident since 1986, resulted in the displacement of 50,000 households.[64] Radiation checks led to bans of some shipments of vegetables and fish.[65] However, according to UN reports, the radiation leaks were small and did not cause any health problems in residents.[66] Evacuation of residents was criticized as not scientifically justified.[67]

Production of nuclear power relies on the nuclear fuel cycle, which includes uranium mining and milling. Uranium workers are routinely exposed to low levels of radon decay products and gamma radiation. Risks of leukemia from acute and high doses of gamma radiation are well-known, but there is debate about risks from lower doses. Only a few studies have examined the risks of other hematological cancers in uranium workers.[68]

Comparison to coal-fired power generation

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In terms of net radioactive release, the National Council on Radiation Protection and Measurements (NCRP) estimated the average radioactivity per short ton of coal is 17,100 millicuries per 4,000,000 tons. With 154 coal plants in the United States, this amounts to emissions of 0.6319 TBq per year, per plant.

It is sometimes cited that coal plants release 100 times the radioactivity of nuclear plants. This comes from NCRP Reports No. 92 and No. 95, which estimate the dose to the population from 1000 MWe coal and nuclear plants at 4.9 man-Sv/year and 0.048 man-Sv/year, respectively (a typical Chest x-ray gives a dose of about 0.06 mSv, for comparison).[69] The Environmental Protection Agency estimates an added dose of 0.3 μSv per year for living within 50 miles (80 km) of a coal plant and 0.009 milli-rem per year for those living within the same distance of a nuclear plant.[70] Nuclear power plants in normal operation emit less radioactivity than coal power plants.[69][70]

Unlike coal-fired or oil-fired power generation, nuclear power generation does not directly produce any sulfur dioxide, nitrogen oxides, or mercury (pollution from fossil fuels is blamed for 24,000 early deaths each year in the U.S. alone[71]). However, as with all energy sources, there is some pollution associated with support activities such as mining, manufacturing, and transportation.

A major European Union-funded research study known as ExternE, or Externalities of Energy, undertaken from 1995 to 2005 found that the environmental and health costs of nuclear power, per unit of energy delivered, was €0.0019/kWh. This is lower than that of many renewable sources, including the environmental impact caused by biomass use and the manufacture of photovoltaic solar panels, and was over thirty times lower than coal's impact of €0.06/kWh, or 6 cents/kWh. However, wind power's impact was €0.0009/kWh, just under half the price of nuclear power.[72]

In May 2023, the Washington Post wrote, "Had Germany kept its nuclear plants running from 2010, it could have slashed its use of coal for electricity to 13 percent by now. Today’s figure is 31 percent... Already more lives might have been lost just in Germany because of air pollution from coal power than from all of the world’s nuclear accidents to date, Fukushima and Chernobyl included."[73]

Contrast of radioactive accident emissions with industrial emissions

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Proponents of nuclear power argue that the problems of nuclear waste "do not come anywhere close" to approaching the problems of fossil fuel waste.[74][75] A 2004 article from the BBC states: "The World Health Organization (WHO) says 3 million people are killed worldwide by outdoor air pollution annually from vehicles and industrial emissions, and 1.6 million indoors through using solid fuel."[76] In the U.S. alone, fossil fuel waste kills 20,000 people each year.[77] A coal power plant releases 100 times as much radiation as a nuclear power plant of the same wattage.[78] It is estimated that during 1982, US coal burning released 155 times as much radioactivity into the atmosphere as the Three Mile Island accident.[79] The World Nuclear Association provides a comparison of deaths due to accidents among different forms of energy production. In their life-cycle comparison, deaths per TW-yr of electricity produced from 1970 to 1992 are quoted as 885 for hydropower, 342 for coal, 85 for natural gas, and 8 for nuclear.[80] The figures include uranium mining, which can be a hazardous industry, with many accidents and fatalities.[81]

Waste heat

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The North Anna plant uses direct exchange cooling into an artificial lake.

As with all thermoelectric plants, nuclear power plants need cooling systems. The most common systems for thermal power plants, including nuclear, are:

  • Once-through cooling, in which water is drawn from a large body, passes through the cooling system, and then flows back into the water body.
  • Cooling pond, in which water is drawn from a pond dedicated to the purpose, passes through the cooling system, then returns to the pond. Examples include the South Texas Nuclear Generating Station and the North Anna Nuclear Generating Station. The latter uses a cooling pond or artificial lake, which at the plant discharge canal is often about 30 °F warmer than in the other parts of the lake or in normal lakes (this is cited as an attraction of the area by some residents).[82] The environmental effects of the artificial lakes are often weighted in arguments against construction of new plants, and during droughts such lakes have drawn media attention.[83] The Turkey Point Nuclear Generating Station is credited with helping the conservation status of the American Crocodile, largely an effect of the waste heat produced.[84]
  • Cooling towers, in which water recirculates through the cooling system until it evaporates from the tower. Examples include the Shearon Harris Nuclear Power Plant.

A 2011 study by the National Renewable Energy Laboratory determined that the median nuclear plant with cooling towers consumed 672 gallons of water per megawatt-hour, less than the median consumption of concentrating solar power (865 gal/MWhr for trough type, and 786 gal/MWhr for power tower type), slightly less than coal (687 gal/MWhr), but more than that for natural gas (198 gal/MWhr). Once-through cooling systems use more water, but less water is lost to evaporation. In the median US nuclear plant with once-through cooling, 44,350 gal/MWhr pass through the cooling system, but only 269 gal/MWhr (less than 1 percent) is consumed by evaporation.[85]

Nuclear plants exchange 60 to 70% of their thermal energy by cycling with a body of water or by evaporating water through a cooling tower. This thermal efficiency is somewhat lower than that of coal-fired power plants,[86] thus creating more waste heat.

It is possible to use waste heat in cogeneration applications such as district heating. The principles of cogeneration and district heating with nuclear power are the same as any other form of thermal power production. The Ågesta Nuclear Power Plant in Sweden provides nuclear heat generation. In Switzerland, the Beznau Nuclear Power Plant provides heat to about 20,000 people.[87] However, district heating with nuclear power plants is less common than with other modes of waste heat generation; because of either siting regulations and/or the NIMBY effect, nuclear stations are generally not built in densely populated areas. Waste heat is more commonly used in industrial applications.[88] As district heating has a seasonal demand curve it is often only a seasonal solution of the waste heat problem. Furthermore, district heating is less efficient in less densely populated areas and as nuclear power plants are often constructed far out of population centers due to NIMBY and safety concerns, the usage of nuclear district heating hasn't been widespread.[89]

During Europe's 2003 and 2006 heat waves, French, Spanish, and German utilities had to secure exemptions from regulations in order to discharge overheated water into the environment. Some nuclear reactors shut down.[90][91]

With climate change causing weather extremes such as heat waves, reduced precipitation levels and droughts can have a significant impact on thermal power station infrastructure, including large biomass-electric and fission-electric stations if cooling in these power stations is provided by certain freshwater sources.[92] A number of thermal stations use indirect seawater cooling or cooling towers that use little to no freshwater. During heat waves, some stations designed to heat exchange with rivers and lakes are legally required to reduce output or cease operations to protect water levels and aquatic life.

This presently infrequent problem common among all thermal power stations may become increasingly significant over time.[92] If global warming continues, disruption of electricity may occur if station operators do not have other means of cooling, like cooling towers available.

Nuclear plants, like all thermal power plants including coal, geothermal and biomass power plants, use special structures to draw in water for cooling. Water is often drawn through screens to minimize debris. Many aquatic organisms are trapped and killed against the screens, through a process known as impingement. Aquatic organisms small enough to pass through the screens are subject to toxic stress in a process known as entrainment.[93][94]

Summer shutdowns are especially pronounced in France, which produces some 70% of electricity with nuclear power plants and where electric home heating is widespread. However, in regions with high heating, ventilation, and air conditioning power use, the summer season, rather than imposing lower power demands, may be the peak season of electricity demand, complicating scheduled summer shutdowns.

Greenhouse gas emissions

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Over its lifecycle nuclear energy has low greenhouse gas (GHG) emissions. Many stages of the nuclear fuel chain—mining, milling, transport, fuel fabrication, enrichment, reactor construction, decommissioning, and waste management—use fossil fuels or involve changes to land use, and hence emit some carbon dioxide and conventional pollutants.[95][96][97]

Nuclear energy produces about 10 grams of carbon dioxide per kilowatt hour, compared to about 500 for fossil gas and 1000 for coal. Like all energy sources, various life cycle analysis (LCA) studies have led to a range of estimates on the median value for nuclear power, with most comparisons of carbon dioxide emissions showing that nuclear power is comparable to renewable energy sources.[98][99]

Many people have argued that an expansion of nuclear power would help combat climate change. Others have argued that it is one way to reduce emissions, but it comes with its own problems, such as risks related to severe nuclear accidents, attacks on nuclear sites, and nuclear terrorism. Some activists also believe that there are better ways of dealing with climate change than investing in nuclear power, including the improved energy efficiency and greater reliance on decentralized and renewable energy sources.[100]

Environmental effects of accidents and attacks

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The 1979 Three Mile Island accident and 1986 Chernobyl disaster, along with high construction costs and delays resulting from demonstrations, injunctions, and political actions by anti-nuclear activists, effectively ended the rapid growth of global nuclear power capacity.[3] A release of radioactive materials followed the 2011 Japanese tsunami which damaged the Fukushima I Nuclear Power Plant, resulting in hydrogen gas explosions and partial meltdowns. The Fukushima disaster was classified a Level 7 event. The large-scale release of radioactivity resulted in people being evacuated from a 20 km exclusion zone set up around the power plant, similar to the 30 km radius Chernobyl Exclusion Zone still in effect. Published works suggest that the radioactivity levels around Chernobyl have lowered enough to now have only a limited impact on wildlife.[101]

In Japan, in July 2016, Fukushima Prefecture announced that the number of evacuees following the Great East Japan earthquake events had fallen below 90,000, in part because of the lifting of evacuation orders issued in some municipalities.[102]

Fukushima disaster

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Following the 2011 Japanese Fukushima nuclear disaster, authorities shut down the nation's 54 nuclear power plants. As of 2013, the Fukushima site remains highly radioactive, with some 160,000 evacuees still living in temporary housing, and some land will be unfarmable for centuries. The difficult cleanup job will take 40 or more years, and cost tens of billions of dollars.[103][104]
Japan towns, villages, and cities around the Fukushima Daiichi nuclear plant. The 20km and 30km areas had evacuation and sheltering orders, and additional administrative districts that had an evacuation order are highlighted.

In March 2011, an earthquake and tsunami caused damage that led to explosions and partial meltdowns at the Fukushima I Nuclear Power Plant in Japan.

Since then, radiation levels at the Fukushima I power plant have varied, spiking up to 1,000 mSv/h (millisievert per hour),[105] which can cause radiation sickness to occur following a one-hour exposure.[106] Significant emissions of radioactive particles took place following hydrogen explosions at three reactors, as technicians tried to pump in seawater to keep the uranium fuel rods cool and bled radioactive gas from the reactors in order to make room for the seawater.[107]

Concerns about the possibility of a large-scale release of radioactive material resulted in 20 km exclusion zone being set up around the power plant and people within the 20–30 km band being advised to stay indoors. Later, the UK, France, and some other countries told their nationals to consider leaving Tokyo, in response to fears of spreading nuclear contamination.[108] New Scientist reported that emissions of radioactive iodine and cesium from the crippled Fukushima I nuclear plant have approached levels evident after the Chernobyl disaster in 1986.[109] On March 24, 2011, Japanese officials announced that "radioactive iodine-131 exceeding safety limits for infants had been detected at 18 water-purification plants in Tokyo and five other prefectures." Officials said also that the fallout from the Dai-ichi plant is "hindering search efforts for victims from the March 11 earthquake and tsunami."[110]

According to the Federation of Electric Power Companies of Japan, "by April 27 approximately 55 percent of the fuel in reactor unit 1 had melted, along with 35 percent of the fuel in unit 2, and 30 percent of the fuel in unit 3; and overheated spent fuels in the storage pools of units 3 and 4 probably were also damaged."[111] As of April 2011, water was still being poured into the damaged reactors to cool melting fuel rods.[112] The accident has surpassed the 1979 Three Mile Island accident in seriousness and is comparable to the 1986 Chernobyl disaster.[111] The Economist reported that the Fukushima disaster is "a bit like three Three Mile Islands in a row, with added damage in the spent-fuel stores,"[113] and that there will be ongoing impacts:

Years of clean-up will drag into decades. A permanent exclusion zone could end up stretching beyond the plant’s perimeter. Seriously exposed workers may be at increased risk of cancers for the rest of their lives...[113]

John Price, a former member of the Safety Policy Unit at the UK's National Nuclear Corporation, said that it "might be 100 years before melting fuel rods can be safely removed from Japan's Fukushima nuclear plant."[112]

In the second half of August 2011, Japanese lawmakers announced that Prime Minister Naoto Kan would likely visit the Fukushima Prefecture to announce that the large, contaminated area around the destroyed reactors would be declared uninhabitable, perhaps for decades. Some of the areas in the temporary 12 miles (19 km) radius evacuation zone around Fukushima were found to be heavily contaminated with radionuclides, according to a survey released by the Japanese Ministry of Science and Education.[citation needed]

As of 2016, the government expects to gradually lift the designation of some “difficult-to-return zones,” a total area of 337 square kilometres (130 sq mi), by 2021. Rain, wind, and natural dissipation have removed many radioactive contaminants, lowering levels at the central district of Okuma town to 9 mSv/year, one-fifth the level recorded in 2011.[114]

However, according to UN reports, radiation leaks were small and did not cause any health damage to residents.[66] Rushed evacuation of residents was criticized as not scientifically justified, driven by radiophobia and causing more harm than the incident itself.[67][115]

Chernobyl disaster

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Map showing Caesium-137 contamination in the Chernobyl area in 1996

As of 2013, the 1986 Chernobyl disaster in Ukraine remains the world's worst nuclear power plant disaster. Estimates of its death toll are controversial and range from 62 to 25,000, with the high projections including deaths that have yet to happen. Peer-reviewed publications have generally supported a projected total figure in the low tens of thousands. For example, an estimate of 16,000 excess cancer deaths are predicted to occur due to the Chernobyl accident out to the year 2065, whereas, in the same period, several hundred million cancer cases are expected from other causes.[116] The IARC also stated in a press release: "To put it in perspective, tobacco smoking will cause several thousand times more cancers in the same population," but also, referring to the numbers of different types of cancers, "The exception is thyroid cancer, which, over ten years ago, was already shown to be increased in the most contaminated regions around the site of the accident."[117] The full version of the World Health Organization health effects report adopted by the United Nations, also published in 2006, included the prediction of, in total, no more of 4,000 deaths from cancer.[118] The Union of Concerned Scientists took issue with the report, and they, following the disputed linear no-threshold model (LNT) model of cancer susceptibility,[119] instead estimated that the Chernobyl disaster would cause a total of 25,000 excess cancer deaths worldwide.[120] That would place the total Chernobyl death toll below that of the worst dam failure accident in history, the Banqiao Dam disaster of 1975 in China.

Large amounts of radioactive contamination were spread across Europe due to the Chernobyl disaster; cesium and strontium contaminated many agricultural products, livestock, and soil. The accident necessitated the evacuation of the entire city of Pripyat and of 300,000 people from Kiev, rendering an area of land unusable by humans for an indeterminate period.[121]

As radioactive materials decay, they release particles that can damage the body and lead to cancer, particularly cesium-137 and iodine-131. In the Chernobyl disaster, releases of cesium-137 contaminated land. Some communities, including the entire city of Pripyat, were abandoned indefinitely. One news source reported that thousands of people who drank milk contaminated with radioactive iodine developed thyroid cancer.[122] The exclusion zone (approximately a 30 km radius around Chernobyl) may have significantly elevated levels of radiation, which is now predominantly due to the decay of cesium-137. This contamination is expected to last approximately 300 years.[123]

Due to the bioaccumulation of cesium-137, some mushrooms as well as wild animals which eat them may have levels which are not considered safe for human consumption.[124] Mandatory radiation testing of sheep in parts of the UK that graze on lands with contaminated peat was lifted in 2012.[125]

In 2007, the Ukrainian government declared much of the Chernobyl Exclusion Zone, almost 490 square kilometres (190 sq mi), a zoological animal reserve.[126] Many species of animals have experienced population increases since human influence has largely left the region, including moose, bison, and wolves.[127] However, other species such as barn swallows and many invertebrates have diminished.[128] There is much controversy among biologists over whether Chernobyl is now a wildlife reserve.[129]

SL-1 meltdown

[edit]
This image of the SL-1 core served as a sober reminder of the damage that a nuclear meltdown can cause.

The SL-1, or Stationary Low-Power Reactor Number One, was a United States Army experimental nuclear power reactor which underwent a steam explosion and meltdown on January 3, 1961, killing its three operators: John Byrnes, Richard McKinley, and Richard Legg.[130] The direct cause was the improper manual withdrawal of the central control rod, which was responsible for absorbing neutrons in the reactor core. This caused the reactor power to surge to about 20,000MW and in turn, an explosion occurred. The event is the only known fatal reactor accident in the United States and the first to occur in the world.[131][130] The accident released about 80 curies (3.0 TBq) of iodine-131,[132] which was not considered significant due to its location in a remote desert of Idaho. About 1,100 curies (41 TBq) of fission products were released into the atmosphere.[133]

Radiation exposure limits prior to the accident were 100 röntgens to save a life and 25 to save valuable property. During the response to the accident, 22 people received doses of 3 to 27 röntgens.[134] Removal of radioactive waste and disposal of the three bodies eventually exposed 790 people to harmful levels of radiation.[135] The hands of the initial victims were buried separately from their bodies because of their radiation levels.[130]

Attacks and sabotage

[edit]

Nuclear power plants, uranium enrichment plants, fuel fabrication plants, and even potentially uranium mines are vulnerable to attacks which could lead to widespread radioactive contamination. The attack threat is of several general types: commando-like ground-based attacks on equipment which, if disabled, could lead to a reactor core meltdown or widespread dispersal of radioactivity; and external attacks such as an aircraft crash into a reactor complex, or cyber attacks.[136] Terrorists could target nuclear power plants in an attempt to release radioactive contamination into the environment and community.

Nuclear reactors become preferred targets during military conflict and have been repeatedly attacked by military air strikes:[137]

  • In September 1980, Iran bombed the incomplete Osirak reactor complex in Iraq.
  • In June 1981, an Israeli air strike completely destroyed Iraq's Osirak reactor.
  • Between 1984 and 1987, Iraq bombed Iran's incomplete Bushehr nuclear plant six times.
  • In Iraq in 1991, the U.S. bombed three nuclear reactors and an enrichment pilot facility.

The United States 9/11 Commission said that nuclear power plants were potential targets originally considered for the September 11, 2001 attacks.[citation needed] If terrorist groups could sufficiently damage safety systems to cause a core meltdown at a nuclear power plant and/or sufficiently damage spent fuel pools, such an attack could lead to a widespread radioactive contamination. According to a 2004 report by the U.S. Congressional Budget Office, "The human, environmental, and economic costs from a successful attack on a nuclear power plant that results in the release of substantial quantities of radioactive material to the environment could be great."[138] 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.[136]

Insider sabotage occurs because insiders can observe and work around security measures. In a study of insider crimes, the authors repeatedly said that successful insider crimes depended on the perpetrators’ observation and knowledge of security vulnerabilities.[citation needed] Since the atomic age began, the U.S. Department of Energy’s nuclear laboratories have been known for widespread violations of security rules.[citation needed] A better understanding of the scope of the insider threat will help to overcome complacency and is critical to getting countries to take stronger preventative measures.[139]

Researchers have emphasized the need to make nuclear facilities extremely safe from sabotage and attacks that could release massive quantities of radioactivity. New reactor designs have passive safety features, such as automatic flooding of the reactor core without active intervention by reactor operators. These safety measures have generally been developed and studied with respect to accidents, not to deliberate reactor attacks by terrorist groups. However, the US Nuclear Regulatory Commission now requires new reactor license applications to consider security during the design stage.[136]

Natural disasters

[edit]
The location of the Fessenheim Nuclear Power Plant in the Rhine Rift Valley near the fault that caused the 1356 Basel earthquake is causing concern.

Following the 2011 Fukushima I nuclear accidents, there has been increased focus on the risks associated with seismic activity and the potential for environmental radioactive release. Genpatsu-shinsai, meaning nuclear power plant earthquake disaster, is a term coined by Japanese seismologist Professor Katsuhiko Ishibashi in 1997.[140] It describes a domino effect scenario in which a major earthquake causes a severe accident at a nuclear power plant near a major population center, resulting in an uncontrollable release of radiation that make damage control and rescue impossible. In such a scenario, earthquake damage severely impedes the evacuation of the population. Ishibashi predicts that such an event would have a global impact seriously affecting future generations.[140][141]

The 1999 Blayais Nuclear Power Plant flood was a flood that took place in France on the evening of December 27, 1999. It was caused when a combination of the tide and high winds from the extratropical storm Martin led to the plant's sea walls being overwhelmed.[142] The event resulted in the loss of the plant's off-site power supply and knocked out several safety-related systems, resulting in a Level 2 event on the International Nuclear Event Scale.[143] The incident illustrated the potential for flooding to damage nuclear plants, with the potential for radioactive release.[142][144]

Decommissioning

[edit]
The reactor pressure vessel of the decommissioned Trojan Nuclear Power Plant being transported away from the site for burial. Images courtesy of the NRC.

Nuclear decommissioning is the process by which a nuclear power plant site is dismantled so that it will no longer require measures for radiation protection. The presence of radioactive material necessitates processes that are occupationally dangerous, hazardous to the local environment, expensive, and time-intensive.[145]

Most nuclear plants currently operating in the US were originally designed for a life of about 30–40 years[146] and are licensed to operate for 40 years by the US Nuclear Regulatory Commission.[147] The average age of these reactors is 32 years.[147] Therefore, many reactors are coming to the end of their licensing period. If their licenses are not renewed, the plants must go through a decontamination and decommissioning process.[146][148] As of 2022 debate continues in many countries about how long their nuclear plants should run for, with some being shut-down earlier than expected when they were built and others having their lifetimes extended by decades.[149][150][151]

Decommissioning is an administrative and technical process. It includes clean-up of radioactivity and progressive demolition of the plant. Once a facility is fully decommissioned, no danger of a radiologic nature should persist. The costs of decommissioning are to be spread over the lifetime of a facility and saved in a decommissioning fund. After a facility has been completely decommissioned, it is released from regulatory control, and the licensee of the plant will no longer be responsible for its nuclear safety. With some plants, the intent is to eventually return to "greenfield" status.

See also

[edit]

References

[edit]
  1. ^ "Electricity and the environment - U.S. Energy Information Administration (EIA)". www.eia.gov. Retrieved 2021-10-28.
  2. ^ Sadiq, Muhammad; Shinwari, Riazullah; Wen, Fenghua; Usman, Muhammad; Hassan, Syed Tauseef; Taghizadeh-Hesary, Farhad (2023-02-01). "Do globalization and nuclear energy intensify the environmental costs in top nuclear energy-consuming countries?". Progress in Nuclear Energy. 156: 104533. doi:10.1016/j.pnucene.2022.104533. ISSN 0149-1970.
  3. ^ a b International Panel on Fissile Materials (September 2010). "The Uncertain Future of Nuclear Energy" (PDF). Research Report 9. p. 1.
  4. ^ "Environment and Health in Electricity Generation - World Nuclear Association". world-nuclear.org. Retrieved 2021-10-28.
  5. ^ "Coal Ash is More Radioactive than Nuclear Waste: Scientific American".
  6. ^ Liu, Xingmin (November 2018). "Nuclear District Heating Warm the World, Guard the Globe (Deep-pool Low-temperature Heating Reactor---DHR)" (PDF). International Framework for Nuclear Energy Cooperation.
  7. ^ Resnikoff, Marvin (November 2019). "Decommissioned Nuclear Reactors Are Hot" (PDF). Vermont Department of Public Service.
  8. ^ Benjamin K. Sovacool. A Critical Evaluation of Nuclear Power and Renewable Electricity in Asia, Journal Contemporary Asia, Vol. 40, No. 3, August 2010, pp. 376.
  9. ^ Jeff Tollefson (4 March 2014). "US seeks waste-research revival: Radioactive leak brings nuclear repositories into the spotlight". Nature. 507 (7490): 15–16. doi:10.1038/507015a. PMID 24598616.
  10. ^ Department of Energy Carlsbad Field Office (Jun 2002). "Chapter 1, "Introduction and Statement of Purpose and Need"" (PDF). Final Environmental Assessment for Actinide Chemistry and Repository Science Laboratory. DOE/EA-1404. US Department of Energy. Retrieved 2011-03-21.
  11. ^ Shughart, William F. (1 October 2014). "Why Doesn't U.S. Recycle Nuclear Fuel?". Forbes. Archived from the original on 23 January 2016. Retrieved 18 July 2016. spent nuclear fuel is a valuable asset, not simply waste requiring disposal
  12. ^ NEA – Moving forward with geological disposal
  13. ^ a b Harold Feiveson; Zia Mian; M.V. Ramana; Frank von Hippel (27 June 2011). "Managing nuclear spent fuel: Policy lessons from a 10-country study". Bulletin of the Atomic Scientists. Archived from the original on 26 April 2012. Retrieved 8 August 2011.
  14. ^ US DOE – Radioactive waste: an international concern Archived 2006-09-24 at the Wayback Machine
  15. ^ R. Naudet. 1976. The Oklos nuclear reactors: 1800 millions years ago. Interdisciplinary Science Reviews, 1(1) p.72-84.
  16. ^ Vandenbosch, Robert, and Susanne E. Vandenbosch. 2007. Nuclear waste stalemate. Salt Lake City: University of Utah Press.
  17. ^ M.V. Ramana. Nuclear Power: Economic, Safety, Health, and Environmental Issues of Near-Term Technologies, Annual Review of Environment and Resources, 2009, 34, p. 145.
  18. ^ Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, p. 144; See also Nuclear Nebraska.
  19. ^ a b "About the Commission". Archived from the original on 1 April 2012. Retrieved 1 January 2016.
  20. ^ "Please Note". Archived from the original on 17 August 2012. Retrieved 1 January 2016.
  21. ^ a b Blue Ribbon Commission on America’s Nuclear Future. "Disposal Subcommittee Report to the Full Commission" (PDF). Archived from the original (PDF) on 1 June 2012. Retrieved 1 January 2016.
  22. ^ "CANDU reactor - Energy Education".
  23. ^ NRC. Radioactive Waste: Production, Storage, Disposal (NUREG/BR-0216, Rev. 2)
  24. ^ NRC. Radioactive Waste Management
  25. ^ a b ANS dosechart Archived 2018-07-15 at the Wayback Machine [American Nuclear Society]
  26. ^ Hvistendahl, Mara. "Coal Ash Is More Radioactive Than Nuclear Waste". Scientific American. Retrieved 2022-05-04.
  27. ^ Beth Daley. Leaks imperil nuclear industry: Vermont Yankee among troubled Boston Globe, January 31, 2010.
  28. ^ Nuclear Regulatory Commission. Groundwater Contamination (Tritium) at Nuclear Plants.
  29. ^ "Tritium in drinking water". nuclearsafety.gc.ca. Canadian Nuclear Safety Commission. 3 February 2014. Retrieved 29 July 2017.
  30. ^ "World Uranium Mining". World Nuclear Association. Archived from the original on 2018-12-26. Retrieved 2010-06-11.
  31. ^ "Uranium resources sufficient to meet projected nuclear energy requirements long into the future". Nuclear Energy Agency (NEA). 3 June 2008. Archived from the original on 5 December 2008. Retrieved 2008-06-16.
  32. ^ "Continued growth in uranium production". World-nuclear-news.org. 2011-05-03. Retrieved 2012-10-16.
  33. ^ Nuclear power and water scarcity, ScienceAlert, 28 October 2007, Retrieved 2008-08-08
  34. ^ "Navajos mark 20th anniversary of Church Rock spill", The Daily Courier, Prescott, Arizona, July 18, 1999
  35. ^ a b c Pasternak, Judy (2010). Yellow Dirt: A Poisoned Land and a People Betrayed. Free Press. p. 149. ISBN 978-1416594826.
  36. ^ US Congress, House Committee on Interior and Insular Affairs, Subcommittee on Energy and the Environment. Mill Tailings Dam Break at Church Rock, New Mexico, 96th Cong, 1st Sess (October 22, 1979):19–24.
  37. ^ Brugge, D.; DeLemos, J.L.; Bui, C. (2007), "The Sequoyah Corporation Fuels Release and the Church Rock Spill: Unpublicized Nuclear Releases in American Indian Communities", American Journal of Public Health, 97 (9): 1595–600, doi:10.2105/ajph.2006.103044, PMC 1963288, PMID 17666688
  38. ^ Quinones, Manuel (December 13, 2011), "As Cold War abuses linger, Navajo Nation faces new mining push", E&E News, retrieved December 28, 2012
  39. ^ Pasternak 2010, p. 150.
  40. ^ Pasternak, Judy (2006-11-19). "A peril that dwelt among the Navajos". Los Angeles Times.
  41. ^ U.S. EPA, Radiation Protection, "Uranium Mining Waste" 30 August 2012 Web.4 December 2012 http://www.epa.gov/radiation/tenorm/uranium.html
  42. ^ Uranium Mining and Extraction Processes in the United States Figure 2.1. Mines and Other Locations with Uranium in the Western U.S. http://www.epa.gov/radiation/docs/tenorm/402-r-08-005-voli/402-r-08-005-v1-ch2.pdf
  43. ^ Laws We Use (Summaries):1978 – Uranium Mill Tailings Radiation Control Act(42 USC 2022 et seq.), EPA, retrieved December 16, 2012
  44. ^ US National Cancer Institute, Accidents at Nuclear Power Plants and Cancer Risk, 19 Apr. 2011.
  45. ^ US Centers for Disease Control and Prevention, Uranium miners, 13 July 2012.
  46. ^ Fernández-Navarro, Pablo; García-Pérez, Javier; Ramis, Rebeca; Boldo, Elena; López-Abente, Gonzalo (2012-10-01). "Proximity to mining industry and cancer mortality". Science of the Total Environment. 435–436: 66–73. Bibcode:2012ScTEn.435...66F. doi:10.1016/j.scitotenv.2012.07.019. hdl:20.500.12105/7583. ISSN 0048-9697. PMID 22846765.
  47. ^ a b US Nuclear Regulatory Commission, Fact Sheet on Analysis of Cancer Risk in Populations Near Nuclear Facilities—Phase 1 Feasibility Study, 29 Mar. 2012.
  48. ^ Giovanni Ghirga, "Cancer in children residing near nuclear power plants: an open question", Italian Journal of Pediatrics,
  49. ^ Canadian Nuclear Safety Commission, Mythbusters, 3 Feb. 2014
  50. ^ a b Baker, P. J.; Hoel, D. G. (2007). "Meta-analysis of standardized incidence and mortality rates of childhood leukaemia in proximity to nuclear facilities". European Journal of Cancer Care. 16 (4): 355–363. doi:10.1111/j.1365-2354.2007.00679.x. PMID 17587361.
  51. ^ Spix, C.; Blettner, M. (2009). "Re: BAKER P.J. & HOEL D.G. (2007)European Journal of Cancer Care16, 355–363. Meta-analysis of standardized incidence and mortality rates of childhood leukaemia in proximity to nuclear facilities". European Journal of Cancer Care. 18 (4): 429–430. doi:10.1111/j.1365-2354.2008.01027.x. PMID 19594613.
  52. ^ a b c Elliott, A, Editor (2011) COMARE 14th Report: Further consideration of the incidence of childhood leukaemia around nuclear power plants in Great Britain 6 May 2011, Retrieved 6 May 2011
  53. ^ Little, J.; McLaughlin, J.; Miller, A. (2008). "Leukaemia in young children living in the vicinity of nuclear power plants". International Journal of Cancer. 122 (4): x–xi. doi:10.1002/ijc.23347. PMID 18072253. S2CID 20727452.
  54. ^ M.V. Ramana. Nuclear Power: Economic, Safety, Health, and Environmental Issues of Near-Term Technologies, Annual Review of Environment and Resources, 2009. 34, p.142.
  55. ^ Laurier, D.; Hémon, D.; Clavel, J. (2008). "Childhood leukaemia incidence below the age of 5 years near French nuclear power plants". Journal of Radiological Protection. 28 (3): 401–403. doi:10.1088/0952-4746/28/3/N01. PMC 2738848. PMID 18714138.
  56. ^ Lopez-Abente, Gonzalo et al., (2009)Leukemia, Lymphomas, and Myeloma Mortality in the Vicinity of Nuclear Power Plants and Nuclear Fuel Facilities in Spain Archived 2011-08-26 at the Wayback Machine Cancer Epidemiology, Biomarkers & Prevention, Vol. 8, 925–934, October 1999
  57. ^ Jablon, S.; Hrubec, Z.; Boice Jr, J. (1991). "Cancer in populations living near nuclear facilities. A survey of mortality nationwide and incidence in two states". JAMA: The Journal of the American Medical Association. 265 (11): 1403–1408. doi:10.1001/jama.265.11.1403. PMID 1999880.
  58. ^ Yoshimoto, Y.; Yoshinaga, S.; Yamamoto, K.; Fijimoto, K.; Nishizawa, K.; Sasaki, Y. (2004). "Research on potential radiation risks in areas with nuclear power plants in Japan: Leukaemia and malignant lymphoma mortality between 1972 and 1997 in 100 selected municipalities". Journal of Radiological Protection. 24 (4): 343–368. Bibcode:2004JRP....24..343Y. doi:10.1088/0952-4746/24/4/001. PMID 15682904. S2CID 12750203.
  59. ^ US National Cancer Institute, No Excess Mortality Risk Found in Counties with Nuclear Facilities Archived 2009-02-06 at the Wayback Machine, accessed 22 Mar. 2014.
  60. ^ World Nuclear Association. "Fukushima Accident". WNA. Retrieved 23 August 2014.
  61. ^ Jacob, P.; Rühm, L.; Blettner, M.; Hammer, G.; Zeeb, H. (March 30, 2009). "Is cancer risk of radiation workers larger than expected?". Occupational and Environmental Medicine. 66 (12): 789–796. doi:10.1136/oem.2008.043265. PMC 2776242. PMID 19570756.
  62. ^ Cardis, E.; Vrijheid, M.; Blettner, M.; Gilbert, E.; Hakama, M.; Hill, C.; Howe, G.; Kaldor, J.; Muirhead, C. R.; Schubauer-Berigan, M.; Yoshimura, T.; Bermann, F.; Cowper, G.; Fix, J.; Hacker, C.; Heinmiller, B.; Marshall, M.; Thierry-Chef, I.; Utterback, D.; Ahn, Y-O.; Amoros, E.; Ashmore, P.; Auvinen, A.; Bae, J-M.; Bernar, J.; Biau, A.; Combalot, E.; Deboodt, P.; Sacristan, A. Diez; Eklöf, M.; Engels, H.; Engholm, G.; Gulis, G.; Habib, R. R.; Holan, K.; Hyvonen, H.; Kerekes, A.; Kurtinaitis, J.; Malker, H.; Martuzzi, M.; Mastauskas, A.; Monnet, A.; Moser, M.; Pearce, M. S.; Richardson, D. B.; Rodriguez-Artalejo, F.; Rogel, A.; Tardy, H.; Telle-Lamberton, M.; Turai, I.; Usel, M.; Veress, K. (April 2007). "The 15-Country Collaborative Study of Cancer Risk among Radiation Workers in the Nuclear Industry: Estimates of Radiation-Related Cancer Risks". Radiation Research. International Agency for Research on Cancer. 167 (4): 396–416. Bibcode:2007RadR..167..396C. doi:10.1667/RR0553.1. PMID 17388693. S2CID 36282894.
  63. ^ John P. Christodouleas (June 16, 2011). "Short-Term and Long-Term Health Risks of Nuclear-Power-Plant Accidents". New England Journal of Medicine. 364 (24): 2334–2341. doi:10.1056/NEJMra1103676. PMID 21506737.
  64. ^ Tomoko Yamazaki; Shunichi Ozasa (June 27, 2011). "Fukushima Retiree Leads Anti-Nuclear Shareholders at Tepco Annual Meeting". Bloomberg.
  65. ^ Mari Saito (May 7, 2011). "Japan anti-nuclear protesters rally after PM call to close plant". Reuters.
  66. ^ a b "Fukushima radiation did not damage health of local people, UN says". the Guardian. 2021-03-10. Retrieved 2021-03-12.
  67. ^ a b SPIEGEL, DER (19 August 2011). "Studying the Fukushima Aftermath: 'People Are Suffering from Radiophobia'". Der Spiegel. Retrieved 2021-03-12.
  68. ^ Lydia B. Zablotska (April 2014). "Leukemis, lymphoma and multiple myeloma mortality". Environmental Research. 130: 43–50. doi:10.1016/j.envres.2014.01.002. PMC 4002578. PMID 24583244.
  69. ^ a b Coal Combustion – ORNL Review Vol. 26, No. 3&4, 1993 Archived February 5, 2007, at the Wayback Machine
  70. ^ a b The EPA. Calculate Your Radiation Dose
  71. ^ "Dirty Air, Dirty Power: Mortality and Health Damage Due to Air Pollution from Power Plants". Clean Air Task Force. 2004. Archived from the original on 2006-09-23. Retrieved 2006-11-10.
  72. ^ ExternE-Pol, External costs of current and advanced electricity systems, associated with emissions from the operation of power plants and with the rest of the energy chain, final technical report. Archived 2016-04-15 at the Wayback Machine See figure 9, 9b and figure 11
  73. ^ Data on the German retreat from nuclear energy tell a cautionary tale, Washington Post, May 10, 2023, Archive
  74. ^ David Bodansky. "The Environmental Paradox of Nuclear Power". American Physical Society. Archived from the original on 2008-01-27. Retrieved 2008-01-31. (reprinted from Environmental Practice, vol. 3, no. 2 (June 2001), pp.86–88 (Oxford University Press))
  75. ^ "Some Amazing Facts about Nuclear Power". August 2002. Retrieved 2008-01-31.
  76. ^ Alex Kirby (13 December 2004). "Pollution: A life and death issue". BBC News. Retrieved 2008-01-31.
  77. ^ Don Hopey (June 29, 2005). "State sues utility for U.S. pollution violations". Pittsburgh Post-Gazette. Archived from the original on January 24, 2007. Retrieved 2008-01-31.
  78. ^ Alex Gabbard. "Coal Combustion: Nuclear Resource or Danger". Oak Ridge National Laboratory. Archived from the original on 2007-02-05. Retrieved 2008-01-31.
  79. ^ Nuclear proliferation through coal burning Archived 2009-03-27 at the Wayback Machine — Gordon J. Aubrecht, II, Ohio State University
  80. ^ "Safety of Nuclear Power Reactors". Archived from the original on 2007-02-04. Retrieved 2009-03-12.
  81. ^ Doug Brugge; Jamie L. deLemos; Cat Bui (September 2007). "The Sequoyah Corporation Fuels Release and the Church Rock Spill: Unpublicized Nuclear Releases in American Indian Communities". Am J Public Health. 97 (9): 1595–600. doi:10.2105/AJPH.2006.103044. PMC 1963288. PMID 17666688.
  82. ^ Washington Post. Happy in Their Haven Beside the Nuclear Plant.
  83. ^ NBC. Dropping Lake Levels Affect Shearon Harris
  84. ^ "About Turkey Point". FPL.com. Florida Power & Light. Retrieved 2007-07-25.
  85. ^ John Macknick and others, A Review of Operational Water Consumption and Withdrawal Factors for Electricity Generating Technologies, National Renewable Energy Laboratory, Technical Report NREL/TP-6A20-50900.
  86. ^ "Cooling power plants World Nuclear Association". Archived from the original on 2013-02-24. Retrieved 2008-07-14.
  87. ^ SUGIYAMA KEN'ICHIRO (Hokkaido Univ.) et al. Nuclear District Heating: The Swiss Experience Archived 2007-12-02 at the Wayback Machine
  88. ^ IAEA, 1997: Nuclear power applications: Supplying heat for homes and industries Archived 2010-07-09 at the Wayback Machine
  89. ^ Losev, V.L.; Sigal, M.V.; Soldatov, G.E (1989). "Nuclear district heating in CMEA countries" (PDF). International Atomic Energy Agency.
  90. ^ The Observer. Heatwave shuts down nuclear power plants.
  91. ^ Susan Sachs (2006-08-10). "Nuclear power's green promise dulled by rising temps". Christian Science Monitor.
  92. ^ a b Dr. Frauke Urban and Dr. Tom Mitchell 2011. Climate change, disasters and electricity generation Archived 2012-09-20 at the Wayback Machine. London: Overseas Development Institute and Institute of Development Studies
  93. ^ Contesting the Future of Nuclear Power, p. 149.
  94. ^ Klepper, Otto (1974). "Siting Considerations for future offshore nuclear energy stations". Nuclear Technology. 22 (2): 160–169. Bibcode:1974NucTe..22..160K. doi:10.13182/NT74-A31399. S2CID 94157465.
  95. ^ Kurt Kleiner. Nuclear energy: assessing the emissions Nature Reports, Vol. 2, October 2008, pp. 130–131.
  96. ^ Mark Diesendorf (2007). Greenhouse Solutions with Sustainable Energy, University of New South Wales Press, p. 252.
  97. ^ Mark Diesendorf. Is nuclear energy a possible solution to global warming? Archived July 22, 2012, at the Wayback Machine pdf
  98. ^ "Hydropower-Internalised Costs and Externalised Benefits"; Frans H. Koch; International Energy Agency (IEA)-Implementing Agreement for Hydropower Technologies and Programmes; 2000.
  99. ^ AEA Technology environment (May 2005). "Environmental Product Declaration of Electricity from Torness Nuclear Power Station" (PDF). Archived from the original on 4 August 2008. Retrieved 31 January 2010.
  100. ^ Ramana, M.V. (2009). "Nuclear Power: Economic, Safety, Health, and Environmental Issues of Near-Term Technologies". Annual Review of Environment and Resources. 34: 143. doi:10.1146/annurev.environ.033108.092057. S2CID 154613195.
  101. ^ Barras, Colin (22 April 2016). "The Chernobyl exclusion zone is arguably a nature reserve". www.bbc.com. British Broadcasting Corporation. Archived from the original on 21 May 2016. Retrieved 18 July 2016. across most of the exclusion zone, the doses aren't really high enough
  102. ^ Ishii, Noriyuki (5 July 2016). "Number of Fukushima Evacuees Falls Below 90,000". www.jaif.or.jp. Japan Atomic Industrial Forum. Archived from the original on 18 July 2016. Retrieved 18 July 2016.
  103. ^ Richard Schiffman (12 March 2013). "Two years on, America hasn't learned lessons of Fukushima nuclear disaster". The Guardian.
  104. ^ Martin Fackler (June 1, 2011). "Report Finds Japan Underestimated Tsunami Danger". New York Times.
  105. ^ "Radiation spike hinders work at Japan nuke plant". CBS News. 2011-03-15. Retrieved 18 March 2011.
  106. ^ Turner, James Edward (2007). Atoms, Radiation, and Radiation Protection. Wiley-VCH. p. 421. ISBN 978-3-527-40606-7.
  107. ^ Keith Bradsher; et al. (April 12, 2011). "Japanese Officials on Defensive as Nuclear Alert Level Rises". New York Times.
  108. ^ Cresswell, Adam (March 16, 2011), "Stealthy, silent destroyer of DNA", The Australian
  109. ^ Winter, Michael (March 24, 2011). "Report: Emissions from Japan plant approach Chernobyl levels". USA Today.
  110. ^ Michael Winter (March 24, 2011). "Report: Emissions from Japan plant approach Chernobyl levels". USA Today.
  111. ^ a b Jungmin Kang (4 May 2011). "Five steps to prevent another Fukushima". Bulletin of the Atomic Scientists.
  112. ^ a b David Mark; Mark Willacy (April 1, 2011). "Crews 'facing 100-year battle' at Fukushima". ABC News.
  113. ^ a b "Nuclear power: When the steam clears". The Economist. March 24, 2011.
  114. ^ Ohtsuki, Noriyoshi (17 July 2016). "Some restricted zones to be lifted near Fukushima nuclear plant". www.asahi.com. Asahi Shimbun. Archived from the original on 18 July 2016. Retrieved 18 July 2016. radiation level is now about 9 millisieverts per year, about one-fifth the level of five years ago
  115. ^ Lawson, Dominic. "The worst fallout from Fukushima was hysteria". The Times. ISSN 0140-0460. Retrieved 2021-03-17.
  116. ^ Cardis, Elisabeth; et al. (2006). "Estimates of the cancer burden in Europe from radioactive fallout from the Chernobyl accident". International Journal of Cancer. 119 (6): 1224–1235. doi:10.1002/ijc.22037. PMID 16628547. S2CID 37694075.
  117. ^ Press Release N° 168: The Cancer Burden from Chernobyl in Europe Archived 2011-07-01 at the Wayback Machine, Lyon Cedex, France: World Health Organization, International Agency for Research on Cancer, April 20, 2006.
  118. ^ Peplow, Mark. Special Report: Counting The Dead, Nature, 440, pp. 982–983, April 20, 2006, DOI:10.1038/440982a; Published online April 19, 2006; corrected April 21, 2006.
  119. ^ Tubiana, Maurice; Feinendegen, Ludwig; Yang, Chichuan; Kaminski, Joseph (April 2009). "The Linear No-Threshold Relationship Is Inconsistent with Radiation Biologic and Experimental Data". Radiology. 251 (1): 13–22. doi:10.1148/radiol.2511080671. PMC 2663584. PMID 19332842.
  120. ^ Chernobyl Cancer Death Toll Estimate More Than Six Times Higher Than the 4,000 Frequently Cited, According to a New UCS Analysis Archived 2011-06-02 at the Wayback Machine, Union of Concerned Scientists, April 22, 2011. Retrieved from UCSUSA.org website.
  121. ^ Sovacool, Benjamin K. (2008). "The costs of failure: A preliminary assessment of major energy accidents, 1907–2007". Energy Policy. 36 (5): 1806. doi:10.1016/j.enpol.2008.01.040.
  122. ^ Renee Schoof (April 12, 2011). "Japan's nuclear crisis comes home as fuel risks get fresh look". McClatchy.
  123. ^ Health Impact of the Chernobyl Accident, NuclearInfo.net website, August 31, 2005.
  124. ^ Juergen Baetz (1 April 2011). "Radioactive boars and mushrooms in Europe remain a grim reminder 25 years after Chornobyl". The Associated Press. Retrieved 7 June 2012.[permanent dead link]
  125. ^ "Post-Chernobyl disaster sheep controls lifted on last UK farms". BBC. 1 June 2012. Retrieved 7 June 2012.
  126. ^ Ukrainian President Turns Chernobyl Exclusion Zone, 48,870 Hectares, Into Game Reserve Archived 2013-08-01 at the Wayback Machine, League of Ukrainian Canadian Women, August 21, 2007; which in turn cites:
    • Interfax-Ukraine news agency, Kiev, (in Russian), August 13, 2007
    • BBC Monitoring Service, United Kingdom, August 13, 2007.
  127. ^ Stephen Mulvey. Wildlife Defies Chernobyl Radiation, BBC News, April 20, 2006.
  128. ^ Potter, Ned. Chernobyl: Nuclear Wasteland? Or Nature Reserve?, ABC News, May 1, 2009.
  129. ^ Higginbotham, Adam. Half-life: 25 years after the Chernobyl meltdown, a scientific debate rages on, Wired, May 5, 2011.
  130. ^ a b c "The SL-1 Reactor Accident".
  131. ^ Stacy, Susan M. (2000). Proving the Principle: A History of The Idaho National Engineering and Environmental Laboratory, 1949–1999 (PDF). U.S. Department of Energy, Idaho Operations Office. ISBN 978-0-16-059185-3. Archived from the original (PDF) on 2012-11-01. Chapter 16.
  132. ^ The Nuclear Power Deception Table 7: Some Reactor Accidents
  133. ^ Horan, J. R., and J. B. Braun, 1993, Occupational Radiation Exposure History of Idaho Field Office Operations at the INEL, EGG-CS-11143, EG&G Idaho, Inc., October, Idaho Falls, Idaho.
  134. ^ Johnston, Wm. Robert. "SL-1 reactor excursion, 1961". Johnston's Archive. Retrieved 30 July 2010.
  135. ^ Maslin, Janet (March 21, 1984). "Sl-1 (1983): Looking at Perils of Toxicity". The New York Times. Retrieved July 30, 2010.
  136. ^ a b c Charles D. Ferguson; Frank A. Settle (2012). "The Future of Nuclear Power in the United States" (PDF). Federation of American Scientists.
  137. ^ Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, p. 192.
  138. ^ "Congressional Budget Office Vulnerabilities from Attacks on Power Reactors and Spent Material".
  139. ^ Matthew Bunn and Scott Sagan (2014). "A Worst Practices Guide to Insider Threats: Lessons from Past Mistakes". The American Academy of Arts & Sciences.
  140. ^ a b Genpatsu-Shinsai: Catastrophic Multiple Disaster of Earthquake and Quake-induced Nuclear Accident Anticipated in the Japanese Islands (Slides), Katsuhiko Ishibashi, 23rd. General Assembly of IUGG, 2003, Sapporo, Japan, accessed 2011-03-28
  141. ^ Genpatsu-Shinsai: Catastrophic Multiple Disaster of Earthquake and Quake-induced Nuclear Accident Anticipated in the Japanese Islands (Abstract), Katsuhiko Ishibashi, 23rd. General Assembly of IUGG, 2003, Sapporo, Japan, accessed 2011-03-28
  142. ^ a b Generic Results and Conclusions of Re-evaluating the Flooding in French and German Nuclear Power Plants Archived October 6, 2011, at the Wayback Machine J. M. Mattéi, E. Vial, V. Rebour, H. Liemersdorf, M. Türschmann, Eurosafe Forum 2001, published 2001, accessed 2011-03-21
  143. ^ COMMUNIQUE N°7 – INCIDENT SUR LE SITE DU BLAYAIS Archived May 27, 2013, at the Wayback Machine ASN, published 1999-12-30, accessed 2011-03-22
  144. ^ Lessons Learned from 1999 Blayais Flood: Overview of the EDF Flood Risk Management Plan, Eric de Fraguier, EDF, published 2010-03-11, accessed 2011-03-22
  145. ^ Benjamin K. Sovacool. "A Critical Evaluation of Nuclear Power and Renewable Electricity in Asia", Journal of Contemporary Asia, Vol. 40, No. 3, August 2010, p. 373.
  146. ^ a b "Nuclear Decommissioning: Decommission nuclear facilities - World Nuclear Association". Archived from the original on 2015-10-19. Retrieved 2013-08-21.
  147. ^ a b "How old are U.S. Nuclear power plants, and when was the newest one built? - FAQ - U.S. Energy Information Administration (EIA)".
  148. ^ "NRC: Decommissioning of Nuclear Facilities".
  149. ^ "UK looking to extend life of nuclear plant by 20 years amid energy crisis". Financial Times. 2022-03-14. Retrieved 2022-10-16.
  150. ^ Welle (www.dw.com), Deutsche. "German Greens lay out nuclear power position amid federal government infighting | DW | 15.10.2022". DW.COM. Retrieved 2022-10-16.
  151. ^ Belgium, Central Office, NucNet a s b l, Brussels. "Armenia / IAEA Ready To Help As Country Prepares For Lifetime Extension And New-Build :: NucNet | The Independent Nuclear News Agency". The Independent Global Nuclear News Agency. Retrieved 2022-10-16.{{cite web}}: CS1 maint: multiple names: authors list (link)
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