Nuclear safety and security

(Redirected from Nuclear Safety)

Nuclear safety is defined by the International Atomic Energy Agency (IAEA) as "The achievement of proper operating conditions, prevention of accidents or mitigation of accident consequences, resulting in protection of workers, the public and the environment from undue radiation hazards". The IAEA defines nuclear security as "The prevention and detection of and response to, theft, sabotage, unauthorized access, illegal transfer or other malicious acts involving nuclear materials, other radioactive substances or their associated facilities".[1]

A clean-up crew working to remove radioactive contamination after the Three Mile Island accident.

This covers nuclear power plants and all other nuclear facilities, the transportation of nuclear materials, and the use and storage of nuclear materials for medical, power, industry, and military uses.

The nuclear power industry has improved the safety and performance of reactors, and has proposed new and safer reactor designs. However, a perfect safety cannot be guaranteed. Potential sources of problems include human errors and external events that have a greater impact than anticipated: the designers of reactors at Fukushima in Japan did not anticipate that a tsunami generated by an earthquake would disable the backup systems which were supposed to stabilize the reactor after the earthquake.[2][3][4][5] Catastrophic scenarios involving terrorist attacks, war, insider sabotage, and cyberattacks are also conceivable.

Nuclear weapon safety, as well as the safety of military research involving nuclear materials, is generally handled by agencies different from those that oversee civilian safety, for various reasons, including secrecy.[6] There are ongoing concerns about terrorist groups acquiring nuclear bomb-making material.[7]

Overview of nuclear processes and safety issues

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As of 2011, nuclear safety considerations occur in a number of situations, including:

With the exception of thermonuclear weapons and experimental fusion research, all safety issues specific to nuclear power stems from the need to limit the biological uptake of committed dose (ingestion or inhalation of radioactive materials), and external radiation dose due to radioactive contamination.

Nuclear safety therefore covers at minimum:

  • Extraction, transportation, storage, processing, and disposal of fissionable materials
  • Safety of nuclear power generators
  • Control and safe management of nuclear weapons, nuclear material capable of use as a weapon, and other radioactive materials
  • Safe handling, accountability and use in industrial, medical and research contexts
  • Disposal of nuclear waste
  • Limitations on exposure to radiation

Responsible agencies

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International

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The International Atomic Energy Agency was created in 1957 to encourage peaceful development of nuclear technology while providing international safeguards against nuclear proliferation.

Internationally the International Atomic Energy Agency "works with its Member States and multiple partners worldwide to promote safe, secure and peaceful nuclear technologies."[8] Some scientists say that the 2011 Japanese nuclear accidents have revealed that the nuclear industry lacks sufficient oversight, leading to renewed calls to redefine the mandate of the IAEA so that it can better police nuclear power plants worldwide.[9]

The IAEA Convention on Nuclear Safety was adopted in Vienna on 17 June 1994 and entered into force on 24 October 1996. The objectives of the convention are to achieve and maintain a high level of nuclear safety worldwide, to establish and maintain effective defences in nuclear installations against potential radiological hazards, and to prevent accidents having radiological consequences.[10]

The convention was drawn up in the aftermath of the Three Mile Island and Chernobyl accidents at a series of expert level meetings from 1992 to 1994, and was the result of considerable work by States, including their national regulatory and nuclear safety authorities, and the International Atomic Energy Agency, which serves as the Secretariat for the convention.

The obligations of the Contracting Parties are based to a large extent on the application of the safety principles for nuclear installations contained in the IAEA document Safety Fundamentals ‘The Safety of Nuclear Installations’ (IAEA Safety Series No. 110 published 1993). These obligations cover the legislative and regulatory framework, the regulatory body, and technical safety obligations related to, for instance, siting, design, construction, operation, the availability of adequate financial and human resources, the assessment and verification of safety, quality assurance and emergency preparedness.

The convention was amended in 2014 by the Vienna Declaration on Nuclear Safety.[11] This resulted in the following principles:

1. New nuclear power plants are to be designed, sited, and constructed, consistent with the objective of preventing accidents in the commissioning and operation and, should an accident occur, mitigating possible releases of radionuclides causing long-term off site contamination and avoiding early radioactive releases or radioactive releases large enough to require long-term protective measures and actions.

2. Comprehensive and systematic safety assessments are to be carried out periodically and regularly for existing installations throughout their lifetime in order to identify safety improvements that are oriented to meet the above objective. Reasonably practicable or achievable safety improvements are to be implemented in a timely manner.

3. National requirements and regulations for addressing this objective throughout the lifetime of nuclear power plants are to take into account the relevant IAEA Safety Standards and, as appropriate, other good practices as identified inter alia in the Review Meetings of the CNS.

There are several problems with the IAEA, says Najmedin Meshkati of University of Southern California, writing in 2011:

"It recommends safety standards, but member states are not required to comply; it promotes nuclear energy, but it also monitors nuclear use; it is the sole global organization overseeing the nuclear energy industry, yet it is also weighed down by checking compliance with the Nuclear Non-Proliferation Treaty (NPT)".[9]

National

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Many nations utilizing nuclear power have specialist institutions overseeing and regulating nuclear safety. Civilian nuclear safety in the U.S. is regulated by the Nuclear Regulatory Commission (NRC). However, critics of the nuclear industry complain that the regulatory bodies are too intertwined with the industries themselves to be effective. The book The Doomsday Machine for example, offers a series of examples of national regulators, as they put it 'not regulating, just waving' (a pun on waiving) to argue that, in Japan, for example, "regulators and the regulated have long been friends, working together to offset the doubts of a public brought up on the horror of the nuclear bombs".[12] Other examples offered[13] include:

  • in China, where Kang Rixin, former general manager of the state-owned China National Nuclear Corporation, was sentenced to life in jail in 2010 for accepting bribes (and other abuses), a verdict raising questions about the quality of his work on the safety and trustworthiness of China's nuclear reactors.
  • in India, where the nuclear regulator reports to the national Atomic Energy Commission, which champions the building of nuclear power plants there and the chairman of the Atomic Energy Regulatory Board, S. S. Bajaj, was previously a senior executive at the Nuclear Power Corporation of India, the company he is now helping to regulate.
  • in Japan, where the regulator reports to the Ministry of Economy, Trade and Industry, which overtly seeks to promote the nuclear industry and ministry posts and top jobs in the nuclear business are passed among the same small circle of experts.

The book argues that nuclear safety is compromised by the suspicion that, as Eisaku Sato, formerly a governor of Fukushima province (with its infamous nuclear reactor complex), has put it of the regulators: “They're all birds of a feather”.[13]

The safety of nuclear plants and materials controlled by the U.S. government for research, weapons production, and those powering naval vessels is not governed by the NRC.[14][15] In the UK nuclear safety is regulated by the Office for Nuclear Regulation (ONR) and the Defence Nuclear Safety Regulator (DNSR). The Australian Radiation Protection and Nuclear Safety Agency (ARPANSA) is the Federal Government body that monitors and identifies solar radiation and nuclear radiation risks in Australia. It is the main body dealing with ionizing and non-ionizing radiation[16] and publishes material regarding radiation protection.[17]

Other agencies include:

Nuclear power plant safety and security

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Complexity

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Nuclear power plants are some of the most sophisticated and complex energy systems ever designed.[18] Any complex system, no matter how well it is designed and engineered, cannot be deemed failure-proof.[4] Veteran journalist and author Stephanie Cooke has argued:

The reactors themselves were enormously complex machines with an incalculable number of things that could go wrong. When that happened at Three Mile Island in 1979, another fault line in the nuclear world was exposed. One malfunction led to another, and then to a series of others, until the core of the reactor itself began to melt, and even the world's most highly trained nuclear engineers did not know how to respond. The accident revealed serious deficiencies in a system that was meant to protect public health and safety.[19]

The 1979 Three Mile Island accident inspired Perrow's book Normal Accidents, where a nuclear accident occurs, resulting from an unanticipated interaction of multiple failures in a complex system. TMI was an example of a normal accident because it was "unexpected, incomprehensible, uncontrollable and unavoidable".[20]

Perrow concluded that the failure at Three Mile Island was a consequence of the system's immense complexity. Such modern high-risk systems, he realized, were prone to failures however well they were managed. It was inevitable that they would eventually suffer what he termed a 'normal accident'. Therefore, he suggested, we might do better to contemplate a radical redesign, or if that was not possible, to abandon such technology entirely.[21]

A fundamental issue contributing to a nuclear power system's complexity is its extremely long lifetime. The timeframe from the start of construction of a commercial nuclear power station through the safe disposal of its last radioactive waste, may be 100 to 150 years.[18]

Failure modes of nuclear power plants

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There are concerns that a combination of human and mechanical error at a nuclear facility could result in significant harm to people and the environment:[22]

Operating nuclear reactors contain large amounts of radioactive fission products which, if dispersed, can pose a direct radiation hazard, contaminate soil and vegetation, and be ingested by humans and animals. Human exposure at high enough levels can cause both short-term illness and death and longer-term death by cancer and other diseases.[23]

It is impossible for a commercial nuclear reactor to explode like a nuclear bomb since the fuel is never sufficiently enriched for this to occur.[24]

Nuclear reactors can fail in a variety of ways. Should the instability of the nuclear material generate unexpected behavior, it may result in an uncontrolled power excursion. Normally, the cooling system in a reactor is designed to be able to handle the excess heat this causes; however, should the reactor also experience a loss-of-coolant accident, then the fuel may melt or cause the vessel in which it is contained to overheat and melt. This event is called a nuclear meltdown.

After shutting down, for some time the reactor still needs external energy to power its cooling systems. Normally this energy is provided by the power grid to which that plant is connected, or by emergency diesel generators. Failure to provide power for the cooling systems, as happened in Fukushima I, can cause serious accidents.

Nuclear safety rules in the United States "do not adequately weigh the risk of a single event that would knock out electricity from the grid and from emergency generators, as a quake and tsunami recently did in Japan", Nuclear Regulatory Commission officials said in June 2011.[25]

Vulnerability of nuclear plants to attack

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Nuclear reactors become preferred targets during military conflict and, over the past three decades, have been repeatedly attacked during military air strikes, occupations, invasions and campaigns:[26]

  • In September 1980, Iran bombed the Al Tuwaitha nuclear complex in Iraq in Operation Scorch Sword.
  • In June 1981, an Israeli air strike completely destroyed Iraq's Osirak nuclear research facility in Operation Opera.
  • Between 1984 and 1987, Iraq bombed Iran's Bushehr nuclear plant six times.
  • On 8 January 1982, Umkhonto we Sizwe, the armed wing of the ANC, attacked South Africa's Koeberg nuclear power plant while it was still under construction.
  • In 1991, the U.S. bombed three nuclear reactors and an enrichment pilot facility in Iraq.
  • In 1991, Iraq launched Scud missiles at Israel's Dimona nuclear power plant
  • In September 2007, Israel bombed a Syrian reactor under construction.[26]
  • On 4 March 2022, Russian forces carried out artillery strikes at the Zaporizhzhia Nuclear Power Plant during the 2022 Russian invasion of Ukraine.[27]

In the U.S., plants are surrounded by a double row of tall fences which are electronically monitored. The plant grounds are patrolled by a sizeable force of armed guards.[28] In Canada, all reactors have an "on-site armed response force" that includes light-armored vehicles that patrol the plants daily.[29] The NRC's "Design Basis Threat" criterion for plants is a secret, and so what size of attacking force the plants are able to protect against is unknown. However, to scram (make an emergency shutdown) a plant takes fewer than 5 seconds while unimpeded restart takes hours, severely hampering a terrorist force in a goal to release radioactivity.

Attack from the air is an issue that has been highlighted since the September 11 attacks in the U.S. However, it was in 1972 when three hijackers took control of a domestic passenger flight along the east coast of the U.S. and threatened to crash the plane into a U.S. nuclear weapons plant in Oak Ridge, Tennessee. The plane got as close as 8,000 feet above the site before the hijackers’ demands were met.[30][31]

The most important barrier against the release of radioactivity in the event of an aircraft strike on a nuclear power plant is the containment building and its missile shield. Former NRC Chairman Dale Klein has said "Nuclear power plants are inherently robust structures that our studies show provide adequate protection in a hypothetical attack by an airplane. The NRC has also taken actions that require nuclear power plant operators to be able to manage large fires or explosions—no matter what has caused them."[32]

In addition, supporters point to large studies carried out by the U.S. Electric Power Research Institute that tested the robustness of both reactor and waste fuel storage and found that they should be able to sustain a terrorist attack comparable to the September 11 terrorist attacks in the U.S. Spent fuel is usually housed inside the plant's "protected zone"[33] or a spent nuclear fuel shipping cask; stealing it for use in a "dirty bomb" would be extremely difficult. Exposure to the intense radiation would almost certainly quickly incapacitate or kill anyone who attempts to do so.[34]

Threat of terrorist attacks

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Nuclear power plants are considered to be targets for terrorist attacks.[35] Even during the construction of the first nuclear power plants, this issue has been advised by security bodies. Concrete threats of attack against nuclear power plants by terrorists or criminals are documented from several states.[35] While older nuclear power plants were built without special protection against air accidents in Germany, the later nuclear power plants built with a massive concrete buildings are partially protected against air accidents. They are designed against the impact of combat aircraft at a speed of about 800 km / h.[36] It was assumed as a basis of assessment of the impact of an aircraft of type Phantom II with a mass of 20 tonnes and speed of 215 m / s.[37]

The danger arising from a terrorist caused large aircraft crash on a nuclear power plant[36] is currently being discussed. Such a terrorist attack could have catastrophic consequences.[38] For example, the German government has confirmed that the nuclear power plant Biblis A would not be completely protected from an attack by a military aircraft.[39] Following the terrorist attacks in Brussels in 2016, several nuclear power plants were partially evacuated. At the same time, it became known that the terrorists had spied on the nuclear power plants, and several employees had their access privileges withdrawn.[40]

Moreover, "nuclear terrorism", for instance with a so-called "Dirty bomb," poses a considerable potential hazard.[41][42]

Plant location

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earthquake map
 
Fort Calhoun Nuclear Generating Station surrounded by the 2011 Missouri River Floods on June 16, 2011
 
Angra Nuclear Power Plant in Rio de Janeiro state, Brazil

In many countries, plants are often located on the coast, in order to provide a ready source of cooling water for the essential service water system. As a consequence the design needs to take the risk of flooding and tsunamis into account. The World Energy Council (WEC) argues disaster risks are changing and increasing the likelihood of disasters such as earthquakes, cyclones, hurricanes, typhoons, flooding.[43] High temperatures, low precipitation levels and severe droughts may lead to fresh water shortages.[43] Failure to calculate the risk of flooding correctly lead to a Level 2 event on the International Nuclear Event Scale during the 1999 Blayais Nuclear Power Plant flood,[44] while flooding caused by the 2011 Tōhoku earthquake and tsunami lead to the Fukushima I nuclear accidents.[45]

The design of plants located in seismically active zones also requires the risk of earthquakes and tsunamis to be taken into account. Japan, India, China and the USA are among the countries to have plants in earthquake-prone regions. Damage caused to Japan's Kashiwazaki-Kariwa Nuclear Power Plant during the 2007 Chūetsu offshore earthquake[46][47] underlined concerns expressed by experts in Japan prior to the Fukushima accidents, who have warned of a genpatsu-shinsai (domino-effect nuclear power plant earthquake disaster).[48]

Safeguarding critical infrastructure like nuclear power plants is a requirement and necessary for chemical facilities, operating nuclear reactors and many other utility facilities. In 2003, the United States Nuclear Regulatory Commission (NRC) developed mandates regarding enhanced security at nuclear power plants.[citation needed] Primary among them were changes to the security perimeter and the screening of employees, vendors, and visitors as they accessed the site. Many facilities recognize their vulnerabilities, and licensed security-contracting firms have arisen.[citation needed]

Multiple reactors

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The Fukushima nuclear disaster illustrated the dangers of building multiple nuclear reactor units close to one another. Because of the closeness of the reactors, Plant Director Masao Yoshida "was put in the position of trying to cope simultaneously with core meltdowns at three reactors and exposed fuel pools at three units".[49]

Nuclear safety systems

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The three primary objectives of nuclear safety systems as defined by the Nuclear Regulatory Commission are to shut down the reactor, maintain it in a shutdown condition, and prevent the release of radioactive material during events and accidents.[50] These objectives are accomplished using a variety of equipment, which is part of different systems, of which each performs specific functions.

Routine emissions of radioactive materials

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During everyday routine operations, emissions of radioactive materials from nuclear plants are released to the outside of the plants although they are quite slight amounts.[51][52][53][54] The daily emissions go into the air, water and soil.[52][53]

NRC says, "nuclear power plants sometimes release radioactive gases and liquids into the environment under controlled, monitored conditions to ensure that they pose no danger to the public or the environment",[55] and "routine emissions during normal operation of a nuclear power plant are never lethal".[56]

According to the United Nations (UNSCEAR), regular nuclear power plant operation including the nuclear fuel cycle amounts to 0.0002 millisieverts (mSv) annually in average public radiation exposure; the legacy of the Chernobyl disaster is 0.002 mSv/a as a global average as of a 2008 report; and natural radiation exposure averages 2.4 mSv annually although frequently varying depending on an individual's location from 1 to 13 mSv.[57]

Japanese public perception of nuclear power safety

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In March 2012, Prime Minister Yoshihiko Noda said that the Japanese government shared the blame for the Fukushima disaster, saying that officials had been blinded by an image of the country's technological infallibility and were "all too steeped in a safety myth."[58]

Japan has been accused by authors such as journalist Yoichi Funabashi of having an "aversion to facing the potential threat of nuclear emergencies." According to him, a national program to develop robots for use in nuclear emergencies was terminated in midstream because it "smacked too much of underlying danger." Though Japan is a major power in robotics, it had none to send in to Fukushima during the disaster. He mentions that Japan's Nuclear Safety Commission stipulated in its safety guidelines for light-water nuclear facilities that "the potential for extended loss of power need not be considered." However, this kind of extended loss of power to the cooling pumps caused the Fukushima meltdown.[59]

In other countries such as the UK, nuclear plants have not been claimed to be absolutely safe. It is instead claimed that a major accident has a likelihood of occurrence lower than (for example) 0.0001/year.[citation needed]

Incidents such as the Fukushima Daiichi nuclear disaster could have been avoided with stricter regulations over nuclear power. In 2002, TEPCO, the company that operated the Fukushima plant, admitted to falsifying reports on over 200 occasions between 1997 and 2002. TEPCO faced no fines for this. Instead, they fired four of their top executives. Three of these four later went on to take jobs at companies that do business with TEPCO.[60]

Uranium supplies

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Nuclear fuel is a strategic resource whose continuous supply needs to be secured to prevent plant outages. IAEA recommends at least two suppliers to prevent supply disruptions as result of political events or monopolistic pressure. Worldwide uranium supplies are well diversified, with dozens of suppliers in various countries, and the small amounts of fuel required make the diversification much easier than in the case of the large-volume fossil fuel supplies required by the energy sector. For example, Ukraine faced such a challenge as a result of the conflict with Russia, which continued to supply the fuel but used it to leverage political pressure. In 2016 Ukraine obtained 50% of its supplies from Russia, and the other half from Sweden,[61] with a number of framework contracts with other countries.[62]

Title 10 CFR Part 73 (U.S. NRC)

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Title 10 of the Code of Federal Regulations (CFR) Part 73, Physical Protection of Plants and Materials, regulated by the entity the Nuclear Regulatory Commission (NRC) contains Subparts A (General Provisions) through I (Enforcement) and Subpart T (Security Notifications, Reports, and Recordkeeping) are available online U.S. NRC 10 CFR Part 7 This section and the table contents below, as reflected in the e-CFR per December 20, 2023, is as follows:

Table (10 CFR Part 73 - Physical Protection of Plants and Materials)
Subpart Sections
A - General Provisions § 73.1 - 73.8
B - Enhanced Weapons, Preemption, and Firearms Background Checks § 73.15, § 73.17
C - General Performance Objective for Protection of Strategic Special Nuclear Material § 73.20
D - Protection of Safeguards Information § 73.21 - 73.23
E - Physical Protection Requirements of Special Nuclear Material and Spent Nuclear Fuel in Transit § 73.24 - 73.38
F - Physical Protection Requirements at Fixed Sites § 73.40 - 73.55
G - Access Authorization and Access Control Requirements for the Physical Protection of Special Nuclear Material § 73.56 - 73.67
H - Records and Postings § 73.70 – 73.75
I - Enforcement § 73.77 – 73.81
Subpart J - Subpart S [Reserved]
T - Security Notifications, Reports, and Recordkeeping § 73.1200 – 73.1215
Appendix A - U.S. Nuclear Regulatory Commission Offices and Classified Mailing Addresses

Appendix B - General Criteria for Security Personnel

Appendix C - Licensee Safeguards Contingency Plans

Appendix D - Physical Protection of Irradiated Reactor Fuel in Transit, Training Program Subject Schedule

Appendix E - Levels of Physical Protection To Be Applied in International Transport of Nuclear Material

Appendix F - Countries and Organizations That Are Parties to the Convention on the Physical Protection of Nuclear Material

Appendix G - [Reserved]

Appendix H - Weapons Qualification Criteria

Other

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Refer to Vehicle Barriers for regulation details affiliated with 10 CFR 73.55(e)(10)(i)(A) and Vehicle Barrier Systems and protection from land vehicles.

Refer to Security Lighting for regulation details affiliated with 10 CFR 73.55(i)(6)(ii), identifying minimum illumination requirements.

Refer to Cybersecurity for regulation details affiliated with 10 CFR 73.54, identifying cybersecurity requirements for nuclear facilities. For guidelines on the satisfaction of 10 CFR 73.54 requirements, refer to NEI 08-09.

Hazards of nuclear material

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Spent nuclear fuel stored underwater and uncapped at the Hanford site in Washington, USA.

There is currently a total of 47,000 tonnes of high-level nuclear waste stored in the USA. Nuclear waste is approximately 94% Uranium, 1.3% Plutonium, 0.14% other actinides, and 5.2% fission products.[63] About 1.0% of this waste consists of long-lived isotopes 79Se, 93Zr, 99Te, 107Pd, 126Sn, 129I and 135Cs. Shorter lived isotopes including 89Sr, 90Sr, 106Ru, 125Sn, 134Cs, 137Cs, and 147Pm constitute 0.9% at one year, decreasing to 0.1% at 100 years. The remaining 3.3–4.1% consists of non-radioactive isotopes.[64][65][66] There are technical challenges, as it is preferable to lock away the long-lived fission products, but the challenge should not be exaggerated. One tonne of waste, as described above, has measurable radioactivity of approximately 600 TBq equal to the natural radioactivity in one km3 of the Earth's crust, which if buried, would add only 25 parts per trillion to the total radioactivity.

The difference between short-lived high-level nuclear waste and long-lived low-level waste can be illustrated by the following example. As stated above, one mole of both 131I and 129I release 3x1023 decays in a period equal to one half-life. 131I decays with the release of 970 keV whilst 129I decays with the release of 194 keV of energy. 131gm of 131I would therefore release 45 gigajoules over eight days beginning at an initial rate of 600 EBq releasing 90 kilowatts with the last radioactive decay occurring inside two years.[67] In contrast, 129gm of 129I would therefore release 9 gigajoules over 15.7 million years beginning at an initial rate of 850 MBq releasing 25 microwatts with the radioactivity decreasing by less than 1% in 100,000 years.[68]

One tonne of nuclear waste also reduces CO2 emission by 25 million tonnes.[63]

 
Anti-nuclear protest near nuclear waste disposal centre at Gorleben in northern Germany

[69] Radionuclides such as 129I or 131I, may be highly radioactive, or very long-lived, but they cannot be both. One mole of 129I (129 grams) undergoes the same number of decays (3x1023) in 15.7 million years, as does one mole of 131I (131 grams) in 8 days. 131I is therefore highly radioactive, but disappears very quickly, whilst 129I releases a very low level of radiation for a very long time. Two long-lived fission products, technetium-99 (half-life 220,000 years) and iodine-129 (half-life 15.7 million years), are of somewhat greater concern because of a greater chance of entering the biosphere.[70] The transuranic elements in spent fuel are neptunium-237 (half-life two million years) and plutonium-239 (half-life 24,000 years),[71] which will also remain in the environment for long periods of time. A more complete solution to both the problem of both actinides and to the need for low-carbon energy may be the integral fast reactor. One tonne of nuclear waste after a complete burn in an IFR reactor will have prevented 500 million tonnes of CO2 from entering the atmosphere.[63] Otherwise, waste storage usually necessitates treatment, followed by a long-term management strategy involving permanent storage, disposal or transformation of the waste into a non-toxic form.[72]

Governments around the world are considering a range of waste management and disposal options, usually involving deep-geologic placement, although there has been limited progress toward implementing long-term waste management solutions.[73] This is partly because the timeframes in question when dealing with radioactive waste range from 10,000 to millions of years,[74][75] according to studies based on the effect of estimated radiation doses.[76]

Since the fraction of a radioisotope's atoms decaying per unit of time is inversely proportional to its half-life, the relative radioactivity of a quantity of buried human radioactive waste would diminish over time compared to natural radioisotopes (such as the decay chain of 120 trillion tons of thorium and 40 trillion tons of uranium which are at relatively trace concentrations of parts per million each over the crust's 3 * 1019 ton mass).[77][78][79] For instance, over a timeframe of thousands of years, after the most active short half-life radioisotopes decayed, burying U.S. nuclear waste would increase the radioactivity in the top 2000 feet of rock and soil in the United States (10 million km2) by 1 part in 10 million over the cumulative amount of natural radioisotopes in such a volume, although the vicinity of the site would have a far higher concentration of artificial radioisotopes underground than such an average.[80]

Safety culture and human errors

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The thermonuclear bomb that fell into the sea recovered off Palomares, Almería, 1966

One relatively prevalent notion in discussions of nuclear safety is that of safety culture. The International Nuclear Safety Advisory Group, defines the term as “the personal dedication and accountability of all individuals engaged in any activity which has a bearing on the safety of nuclear power plants”.[81] The goal is “to design systems that use human capabilities in appropriate ways, that protect systems from human frailties, and that protect humans from hazards associated with the system”.[81]

At the same time, there is some evidence that operational practices are not easy to change. Operators almost never follow instructions and written procedures exactly, and “the violation of rules appears to be quite rational, given the actual workload and timing constraints under which the operators must do their job”. Many attempts to improve nuclear safety culture “were compensated by people adapting to the change in an unpredicted way”.[81]

According to Areva's Southeast Asia and Oceania director, Selena Ng, Japan's Fukushima nuclear disaster is "a huge wake-up call for a nuclear industry that hasn't always been sufficiently transparent about safety issues". She said "There was a sort of complacency before Fukushima and I don't think we can afford to have that complacency now".[82]

An assessment conducted by the Commissariat à l’Énergie Atomique (CEA) in France concluded that no amount of technical innovation can eliminate the risk of human-induced errors associated with the operation of nuclear power plants. Two types of mistakes were deemed most serious: errors committed during field operations, such as maintenance and testing, that can cause an accident; and human errors made during small accidents that cascade to complete failure.[83]

According to Mycle Schneider, reactor safety depends above all on a 'culture of security', including the quality of maintenance and training, the competence of the operator and the workforce, and the rigour of regulatory oversight. So a better-designed, newer reactor is not always a safer one, and older reactors are not necessarily more dangerous than newer ones. The 1979 Three Mile Island accident in the United States occurred in a reactor that had started operation only three months earlier, and the Chernobyl disaster occurred after only two years of operation. A serious loss of coolant occurred at the French Civaux-1 reactor in 1998, less than five months after start-up.[84]

However safe a plant is designed to be, it is operated by humans who are prone to errors. Laurent Stricker, a nuclear engineer and chairman of the World Association of Nuclear Operators says that operators must guard against complacency and avoid overconfidence. Experts say that the "largest single internal factor determining the safety of a plant is the culture of security among regulators, operators and the workforce — and creating such a culture is not easy".[84]

Investigative journalist Eric Schlosser, author of Command and Control, discovered that at least 700 "significant" accidents and incidents involving 1,250 nuclear weapons were recorded in the United States between 1950 and 1968.[85] Experts believe that up to 50 nuclear weapons were lost during the Cold War.[86]

Risks

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The routine health risks and greenhouse gas emissions from nuclear fission power are small relative to those associated with coal, but there are several "catastrophic risks":[87]

The extreme danger of the radioactive material in power plants and of nuclear technology in and of itself is so well known that the US government was prompted (at the industry's urging) to enact provisions that protect the nuclear industry from bearing the full burden of such inherently risky nuclear operations. The Price-Anderson Act limits industry's liability in the case of accidents, and the 1982 Nuclear Waste Policy Act charges the federal government with responsibility for permanently storing nuclear waste.[88]

Population density is one critical lens through which other risks have to be assessed, says Laurent Stricker, a nuclear engineer and chairman of the World Association of Nuclear Operators:[84]

The KANUPP plant in Karachi, Pakistan, has the most people — 8.2 million — living within 30 kilometres of a nuclear plant, although it has just one relatively small reactor with an output of 125 megawatts. Next in the league, however, are much larger plants — Taiwan's 1,933-megawatt Kuosheng plant with 5.5 million people within a 30-kilometre radius and the 1,208-megawatt Chin Shan plant with 4.7 million; both zones include the capital city of Taipei.[84]

172,000 people living within a 30 kilometre radius of the Fukushima Daiichi nuclear power plant, have been forced or advised to evacuate the area. More generally, a 2011 analysis by Nature and Columbia University, New York, shows that some 21 nuclear plants have populations larger than 1 million within a 30-km radius, and six plants have populations larger than 3 million within that radius.[84]

Black Swan events are highly unlikely occurrences that have big repercussions. Despite planning, nuclear power will always be vulnerable to black swan events:[5]

A rare event – especially one that has never occurred – is difficult to foresee, expensive to plan for and easy to discount with statistics. Just because something is only supposed to happen every 10,000 years does not mean that it will not happen tomorrow.[5] Over the typical 40-year life of a plant, assumptions can also change, as they did on September 11, 2001, in August 2005 when Hurricane Katrina struck, and in March, 2011, after Fukushima.[5]

The list of potential black swan events is "damningly diverse":[5]

Nuclear reactors and their spent-fuel pools could be targets for terrorists piloting hijacked planes. Reactors may be situated downstream from dams that, should they ever burst, could unleash massive floods. Some reactors are located close to faults or shorelines, a dangerous scenario like that which emerged at Three Mile Island and Fukushima – a catastrophic coolant failure, the overheating and melting of the radioactive fuel rods, and a release of radioactive material.[5]

The AP1000 has an estimated core damage frequency of 5.09 × 10−7 per plant per year. The Evolutionary Power Reactor (EPR) has an estimated core damage frequency of 4 × 10−7 per plant per year. In 2006 General Electric published recalculated estimated core damage frequencies per year per plant for its nuclear power plant designs:[89]

BWR/4 – 1 × 10−5
BWR/6 – 1 × 10−6
ABWR – 2 × 10−7
ESBWR – 3 × 10−8

Beyond design basis events

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The Fukushima I nuclear accident was caused by a "beyond design basis event," the tsunami and associated earthquakes were more powerful than the plant was designed to accommodate, and the accident is directly due to the tsunami overflowing the too-low seawall.[2] Since then, the possibility of unforeseen beyond design basis events has been a major concern for plant operators.[84]

Transparency and ethics

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According to journalist Stephanie Cooke, it is difficult to know what really goes on inside nuclear power plants because the industry is shrouded in secrecy. Corporations and governments control what information is made available to the public. Cooke says "when information is made available, it is often couched in jargon and incomprehensible prose".[90]

Kennette Benedict has said that nuclear technology and plant operations continue to lack transparency and to be relatively closed to public view:[91]

Despite victories like the creation of the Atomic Energy Commission, and later the Nuclear Regular Commission, the secrecy that began with the Manhattan Project has tended to permeate the civilian nuclear program, as well as the military and defense programs.[91]

In 1986, Soviet officials held off reporting the Chernobyl disaster for several days. The operators of the Fukushima plant, Tokyo Electric Power Co, were also criticised for not quickly disclosing information on releases of radioactivity from the plant. Russian President Dmitry Medvedev said there must be greater transparency in nuclear emergencies.[92]

Historically many scientists and engineers have made decisions on behalf of potentially affected populations about whether a particular level of risk and uncertainty is acceptable for them. Many nuclear engineers and scientists that have made such decisions, even for good reasons relating to long term energy availability, now consider that doing so without informed consent is wrong, and that nuclear power safety and nuclear technologies should be based fundamentally on morality, rather than purely on technical, economic and business considerations.[93]

Non-Nuclear Futures: The Case for an Ethical Energy Strategy is a 1975 book by Amory B. Lovins and John H. Price.[94][95] The main theme of the book is that the most important parts of the nuclear power debate are not technical disputes but relate to personal values, and are the legitimate province of every citizen, whether technically trained or not.[96]

Nuclear and radiation accidents

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The nuclear industry has an excellent safety record and the deaths per megawatt hour are the lowest of all the major energy sources.[97] According to Zia Mian and Alexander Glaser, the "past six decades have shown that nuclear technology does not tolerate error". Nuclear power is perhaps the primary example of what are called ‘high-risk technologies’ with ‘catastrophic potential’, because “no matter how effective conventional safety devices are, there is a form of accident that is inevitable, and such accidents are a ‘normal’ consequence of the system.” In short, there is no escape from system failures.[98]

Whatever position one takes in the nuclear power debate, the possibility of catastrophic accidents and consequent economic costs must be considered when nuclear policy and regulations are being framed.[99]

Accident liability protection

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Kristin Shrader-Frechette has said "if reactors were safe, nuclear industries would not demand government-guaranteed, accident-liability protection, as a condition for their generating electricity".[100] No private insurance company or even consortium of insurance companies "would shoulder the fearsome liabilities arising from severe nuclear accidents".[101]

Hanford Site

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The Hanford site represents two-thirds of America's high-level radioactive waste by volume. Nuclear reactors line the riverbank at the Hanford Site along the Columbia River in January 1960.

The Hanford Site is a mostly decommissioned nuclear production complex on the Columbia River in the U.S. state of Washington, operated by the United States federal government. Plutonium manufactured at the site was used in the first nuclear bomb, tested at the Trinity site, and in Fat Man, the bomb detonated over Nagasaki, Japan. During the Cold War, the project was expanded to include nine nuclear reactors and five large plutonium processing complexes, which produced plutonium for most of the 60,000 weapons in the U.S. nuclear arsenal.[102][103] Many of the early safety procedures and waste disposal practices were inadequate, and government documents have since confirmed that Hanford's operations released significant amounts of radioactive materials into the air and the Columbia River, which still threatens the health of residents and ecosystems.[104] The weapons production reactors were decommissioned at the end of the Cold War, but the decades of manufacturing left behind 53 million US gallons (200,000 m3) of high-level radioactive waste,[105] an additional 25 million cubic feet (710,000 m3) of solid radioactive waste, 200 square miles (520 km2) of contaminated groundwater beneath the site[106] and occasional discoveries of undocumented contaminations that slow the pace and raise the cost of cleanup.[107] The Hanford site represents two-thirds of the nation's high-level radioactive waste by volume.[108] Today, Hanford is the most contaminated nuclear site in the United States[109][110] and is the focus of the nation's largest environmental cleanup.[102]

1986 Chernobyl disaster

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Map showing Caesium-137 contamination in Belarus, Russia, and Ukraine as of 1996.

The Chernobyl disaster was a nuclear accident that occurred on 26 April 1986 at the Chernobyl Nuclear Power Plant in Ukraine. An explosion and fire released large quantities of radioactive contamination into the atmosphere, which spread over much of Western USSR and Europe. It is considered the worst nuclear power plant accident in history, and is one of only two classified as a level 7 event on the International Nuclear Event Scale (the other being the Fukushima Daiichi nuclear disaster).[111] The battle to contain the contamination and avert a greater catastrophe ultimately involved over 500,000 workers and cost an estimated 18 billion rubles, crippling the Soviet economy.[112] The accident raised concerns about the safety of the nuclear power industry, slowing its expansion for a number of years.[113]

UNSCEAR has conducted 20 years of detailed scientific and epidemiological research on the effects of the Chernobyl accident. Apart from the 57 direct deaths in the accident itself, UNSCEAR predicted in 2005 that up to 4,000 additional cancer deaths related to the accident would appear "among the 600 000 persons receiving more significant exposures (liquidators working in 1986–87, evacuees, and residents of the most contaminated areas)".[114] Russia, Ukraine, and Belarus have been burdened with the continuing and substantial decontamination and health care costs of the Chernobyl disaster.[115]

Eleven of Russia's reactors are of the RBMK 1000 type, similar to the one at Chernobyl Nuclear Power Plant. Some of these RBMK reactors were originally to be shut down but have instead been given life extensions and uprated in output by about 5%. Critics say that these reactors are of an "inherently unsafe design", which cannot be improved through upgrades and modernization, and some reactor parts are impossible to replace. Russian environmental groups say that the lifetime extensions "violate Russian law, because the projects have not undergone environmental assessments".[116]

2011 Fukushima I accidents

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Fukushima reactor control room.
 
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.[117][118]

Despite all assurances, a major nuclear accident on the scale of the 1986 Chernobyl disaster happened again in 2011 in Japan, one of the world's most industrially advanced countries. Nuclear Safety Commission Chairman Haruki Madarame told a parliamentary inquiry in February 2012 that "Japan's atomic safety rules are inferior to global standards and left the country unprepared for the Fukushima nuclear disaster last March". There were flaws in, and lax enforcement of, the safety rules governing Japanese nuclear power companies, and this included insufficient protection against tsunamis.[119]

A 2012 report in The Economist said: "The reactors at Fukushima were of an old design. The risks they faced had not been well analysed. The operating company was poorly regulated and did not know what was going on. The operators made mistakes. The representatives of the safety inspectorate fled. Some of the equipment failed. The establishment repeatedly played down the risks and suppressed information about the movement of the radioactive plume, so some people were evacuated from more lightly to more heavily contaminated places".[120]

The designers of the Fukushima I Nuclear Power Plant reactors did not anticipate that a tsunami generated by an earthquake would disable the backup systems that were supposed to stabilize the reactor after the earthquake.[2] Nuclear reactors are such "inherently complex, tightly coupled systems that, in rare, emergency situations, cascading interactions will unfold very rapidly in such a way that human operators will be unable to predict and master them".[3]

Lacking electricity to pump water needed to cool the atomic core, engineers vented radioactive steam into the atmosphere to release pressure, leading to a series of explosions that blew out concrete walls around the reactors. Radiation readings spiked around Fukushima as the disaster widened, forcing the evacuation of 200,000 people. There was a rise in radiation levels on the outskirts of Tokyo, with a population of 30 million, 135 miles (210 kilometers) to the south.[45]

Back-up diesel generators that might have averted the disaster were positioned in a basement, where they were quickly overwhelmed by waves. The cascade of events at Fukushima had been predicted in a report published in the U.S. several decades ago:[45]

The 1990 report by the U.S. Nuclear Regulatory Commission, an independent agency responsible for safety at the country's power plants, identified earthquake-induced diesel generator failure and power outage leading to failure of cooling systems as one of the “most likely causes” of nuclear accidents from an external event.[45]

The report was cited in a 2004 statement by Japan's Nuclear and Industrial Safety Agency, but it seems adequate measures to address the risk were not taken by TEPCO. Katsuhiko Ishibashi, a seismology professor at Kobe University, has said that Japan's history of nuclear accidents stems from an overconfidence in plant engineering. In 2006, he resigned from a government panel on nuclear reactor safety, because the review process was rigged and “unscientific”.[45]

According to the International Atomic Energy Agency, Japan "underestimated the danger of tsunamis and failed to prepare adequate backup systems at the Fukushima Daiichi nuclear plant". This repeated a widely held criticism in Japan that "collusive ties between regulators and industry led to weak oversight and a failure to ensure adequate safety levels at the plant".[118] The IAEA also said that the Fukushima disaster exposed the lack of adequate backup systems at the plant. Once power was completely lost, critical functions like the cooling system shut down. Three of the reactors "quickly overheated, causing meltdowns that eventually led to explosions, which hurled large amounts of radioactive material into the air".[118]

Louise Fréchette and Trevor Findlay have said that more effort is needed to ensure nuclear safety and improve responses to accidents:

The multiple reactor crises at Japan's Fukushima nuclear power plant reinforce the need for strengthening global instruments to ensure nuclear safety worldwide. The fact that a country that has been operating nuclear power reactors for decades should prove so alarmingly improvisational in its response and so unwilling to reveal the facts even to its own people, much less the International Atomic Energy Agency, is a reminder that nuclear safety is a constant work-in-progress. [121]

David Lochbaum, chief nuclear safety officer with the Union of Concerned Scientists, has repeatedly questioned the safety of the Fukushima I Plant's General Electric Mark 1 reactor design, which is used in almost a quarter of the United States' nuclear fleet.[122]

A report from the Japanese Government to the IAEA says the "nuclear fuel in three reactors probably melted through the inner containment vessels, not just the core". The report says the "inadequate" basic reactor design — the Mark-1 model developed by General Electric — included "the venting system for the containment vessels and the location of spent fuel cooling pools high in the buildings, which resulted in leaks of radioactive water that hampered repair work".[123]

Following the Fukushima emergency, the European Union decided that reactors across all 27 member nations should undergo safety tests.[124]

According to UBS AG, the Fukushima I nuclear accidents are likely to hurt the nuclear power industry's credibility more than the Chernobyl disaster in 1986:

The accident in the former Soviet Union 25 years ago 'affected one reactor in a totalitarian state with no safety culture,' UBS analysts including Per Lekander and Stephen Oldfield wrote in a report today. 'At Fukushima, four reactors have been out of control for weeks – casting doubt on whether even an advanced economy can master nuclear safety.'[125]

The Fukushima accident exposed some troubling nuclear safety issues:[126]

Despite the resources poured into analyzing crustal movements and having expert committees determine earthquake risk, for instance, researchers never considered the possibility of a magnitude-9 earthquake followed by a massive tsunami. The failure of multiple safety features on nuclear power plants has raised questions about the nation's engineering prowess. Government flip-flopping on acceptable levels of radiation exposure confused the public, and health professionals provided little guidance. Facing a dearth of reliable information on radiation levels, citizens armed themselves with dosimeters, pooled data, and together produced radiological contamination maps far more detailed than anything the government or official scientific sources ever provided.[126]

As of January 2012, questions also linger as to the extent of damage to the Fukushima plant caused by the earthquake even before the tsunami hit. Any evidence of serious quake damage at the plant would "cast new doubt on the safety of other reactors in quake-prone Japan".[127]

Two government advisers have said that "Japan's safety review of nuclear reactors after the Fukushima disaster is based on faulty criteria and many people involved have conflicts of interest". Hiromitsu Ino, Professor Emeritus at the University of Tokyo, says "The whole process being undertaken is exactly the same as that used previous to the Fukushima Dai-Ichi accident, even though the accident showed all these guidelines and categories to be insufficient".[128]

In March 2012, Prime Minister Yoshihiko Noda acknowledged that the Japanese government shared the blame for the Fukushima disaster, saying that officials had been blinded by a false belief in the country's "technological infallibility", and were all too steeped in a "safety myth".[129]

Other accidents

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Serious nuclear and radiation accidents include the Chalk River accidents (1952, 1958 & 2008), Mayak disaster (1957), Windscale fire (1957), SL-1 accident (1961), Soviet submarine K-19 accident (1961), Three Mile Island accident (1979), Church Rock uranium mill spill (1979), Soviet submarine K-431 accident (1985), Therac-25 accidents (1985–1987), Goiânia accident (1987), Zaragoza radiotherapy accident (1990), Costa Rica radiotherapy accident (1996), Tokaimura nuclear accident (1999), Sellafield THORP leak (2005), and the Flerus IRE cobalt-60 spill (2006).[130][131]

Health impacts

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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.

Four hundred and thirty-seven nuclear power stations are presently in operation but, unfortunately, five major nuclear accidents have occurred in the past. These accidents occurred at Kyshtym (1957), Windscale (1957), Three Mile Island (1979), Chernobyl (1986), and Fukushima (2011). A report in Lancet says that the effects of these accidents on individuals and societies are diverse and enduring:[132]

"Accumulated evidence about radiation health effects on atomic bomb survivors and other radiation-exposed people has formed the basis for national and international regulations about radiation protection. However, past experiences suggest that common issues were not necessarily physical health problems directly attributable to radiation exposure, but rather psychological and social effects. Additionally, evacuation and long-term displacement created severe health-care problems for the most vulnerable people, such as hospital inpatients and elderly people."[132]

In spite of accidents like these, studies have shown that nuclear deaths are mostly in uranium mining and that nuclear energy has generated far fewer deaths than the high pollution levels that result from the use of conventional fossil fuels.[133] However, the nuclear power industry relies on uranium mining, which itself is a hazardous industry, with many accidents and fatalities.[134]

Journalist Stephanie Cooke says that it is not useful to make comparisons just in terms of number of deaths, as the way people live afterwards is also relevant, as in the case of the 2011 Japanese nuclear accidents:[135]

"You have people in Japan right now that are facing either not returning to their homes forever, or if they do return to their homes, living in a contaminated area for basically ever... It affects millions of people, it affects our land, it affects our atmosphere ... it's affecting future generations ... I don't think any of these great big massive plants that spew pollution into the air are good. But I don't think it's really helpful to make these comparisons just in terms of number of deaths".[135]

The Fukushima accident forced more than 80,000 residents to evacuate from neighborhoods around the plant.[123]

A survey by the Iitate, Fukushima local government obtained responses from some 1,743 people who have evacuated from the village, which lies within the emergency evacuation zone around the crippled Fukushima Daiichi Plant. It shows that many residents are experiencing growing frustration and instability due to the nuclear crisis and an inability to return to the lives they were living before the disaster. Sixty percent of respondents stated that their health and the health of their families had deteriorated after evacuating, while 39.9 percent reported feeling more irritated compared to before the disaster.[136]

"Summarizing all responses to questions related to evacuees' current family status, one-third of all surveyed families live apart from their children, while 50.1 percent live away from other family members (including elderly parents) with whom they lived before the disaster. The survey also showed that 34.7 percent of the evacuees have suffered salary cuts of 50 percent or more since the outbreak of the nuclear disaster. A total of 36.8 percent reported a lack of sleep, while 17.9 percent reported smoking or drinking more than before they evacuated."[136]

Chemical components of the radioactive waste may lead to cancer. For example, Iodine 131 was released along with the radioactive waste when Chernobyl disaster and Fukushima disasters occurred. It was concentrated in leafy vegetation after absorption in the soil. It also stays in animals’ milk if the animals eat the vegetation. When Iodine 131 enters the human body, it migrates to the thyroid gland in the neck and can cause thyroid cancer.[137]

Other elements from nuclear waste can lead to cancer as well. For example, Strontium 90 causes breast cancer and leukemia, Plutonium 239 causes liver cancer.[138]

Improvements to nuclear fission technologies

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Redesigns of fuel pellets and cladding are being undertaken which can further improve the safety of existing power plants.

Newer reactor designs intended to provide increased safety have been developed over time. These designs include those that incorporate passive safety and Small Modular Reactors. While these reactor designs "are intended to inspire trust, they may have an unintended effect: creating distrust of older reactors that lack the touted safety features".[139]

The next nuclear plants to be built will likely be Generation III or III+ designs, and a few such are already in operation in Japan. Generation IV reactors would have even greater improvements in safety. These new designs are expected to be passively safe or nearly so, and perhaps even inherently safe (as in the PBMR designs).

Some improvements made (not all in all designs) are having three sets of emergency diesel generators and associated emergency core cooling systems rather than just one pair, having quench tanks (large coolant-filled tanks) above the core that open into it automatically, having a double containment (one containment building inside another), etc.

Approximately 120 reactors,[140] such as all those in Switzerland prior to and all reactors in Japan after the Fukushima accident, incorporate Filtered Containment Venting Systems, onto the containment structure, which are designed to relieve the containment pressure during an accident by releasing gases to the environment while retaining most of the fission products in the filter structures.[141]

However, safety risks may be the greatest when nuclear systems are the newest, and operators have less experience with them. Nuclear engineer David Lochbaum explained that almost all serious nuclear accidents occurred with what was at the time the most recent technology. He argues that "the problem with new reactors and accidents is twofold: scenarios arise that are impossible to plan for in simulations; and humans make mistakes".[83] As one director of a U.S. research laboratory put it, "fabrication, construction, operation, and maintenance of new reactors will face a steep learning curve: advanced technologies will have a heightened risk of accidents and mistakes. The technology may be proven, but people are not".[83]

Developing countries

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There are concerns about developing countries "rushing to join the so-called nuclear renaissance without the necessary infrastructure, personnel, regulatory frameworks and safety culture".[121] Some countries with nuclear aspirations, like Nigeria, Kenya, Bangladesh and Venezuela, have no significant industrial experience and will require at least a decade of preparation even before breaking ground at a reactor site.[121]

Precipitated by a 2010 Nuclear Security Summit convened by the Obama administration, China and the United States launched a number of initiatives to secure potentially dangerous, Chinese-supplied, nuclear material in countries such as Ghana or Nigeria.[142] Through these initiatives, China and the US have converted Chinese-origin Miniature Neutron Source Reactors (MNSRs) from using highly enriched uranium to using low-enriched uranium fuel (which is not directly usable in weapons, thereby making reactors more proliferation resistant).[143]

China and the United States collaborated to build the China Center of Excellence on Nuclear Security, which opened in 2015.[144]: 209  The Center is a forum for nuclear security exchange, training, and demonstration in the Asia Pacific region.[144]: 209 

Nuclear security and terrorist attacks

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Nuclear power plants, civilian research reactors, certain naval fuel facilities, uranium enrichment plants, and fuel fabrication plants, 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.[145]

The United States 9/11 Commission has said that nuclear power plants were potential targets originally considered for the September 11, 2001 attacks. 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 widespread radioactive contamination. The Federation of American Scientists have said that if nuclear power use is to expand significantly, nuclear facilities will have to be made extremely safe from attacks that could release massive quantities of radioactivity into the community. New reactor designs have features of passive safety, which may help. In the United States, the NRC carries out "Force on Force" (FOF) exercises at all Nuclear Power Plant (NPP) sites at least once every three years.[145]

Nuclear reactors become preferred targets during military conflict and, over the past three decades, have been repeatedly attacked during military air strikes, occupations, invasions and campaigns.[26] Various acts of civil disobedience since 1980 by the peace group Plowshares have shown how nuclear weapons facilities can be penetrated, and the groups actions represent extraordinary breaches of security at nuclear weapons plants in the United States. The National Nuclear Security Administration has acknowledged the seriousness of the 2012 Plowshares action. Non-proliferation policy experts have questioned "the use of private contractors to provide security at facilities that manufacture and store the government's most dangerous military material".[146] Nuclear weapons materials on the black market are a global concern,[147][148] and there is concern about the possible detonation of a small, crude nuclear weapon by a militant group in a major city, with significant loss of life and property.[149][150] Stuxnet is a computer worm discovered in June 2010 that is believed to have been created by the United States and Israel to attack Iran's nuclear facilities.[151]

Nuclear fusion research

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Nuclear fusion power is a developing technology still under research. It relies on fusing rather than fissioning (splitting) atomic nuclei, using very different processes compared to current nuclear power plants. Nuclear fusion reactions have the potential to be safer and generate less radioactive waste than fission.[152][153] These reactions appear potentially viable, though technically quite difficult and have yet to be created on a scale that could be used in a functional power plant. Fusion power has been under theoretical and experimental investigation since the 1950s.

Construction of the International Thermonuclear Experimental Reactor facility began in 2007, but the project has run into many delays and budget overruns. The facility is now not expected to begin operations until the year 2027 – 11 years after initially anticipated.[154] A follow on commercial nuclear fusion power station, DEMO, has been proposed.[155][156] There is also suggestions for a power plant based upon a different fusion approach, that of an Inertial fusion power plant.

Fusion powered electricity generation was initially believed to be readily achievable, as fission power had been. However, the extreme requirements for continuous reactions and plasma containment led to projections being extended by several decades. In 2010, more than 60 years after the first attempts, commercial power production was still believed to be unlikely before 2050.[155]

More stringent safety standards

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Matthew Bunn, the former US Office of Science and Technology Policy adviser, and Heinonen, the former Deputy Director General of the IAEA, have said that there is a need for more stringent nuclear safety standards, and propose six major areas for improvement:[99]

  • operators must plan for events beyond design bases;
  • more stringent standards for protecting nuclear facilities against terrorist sabotage;
  • a stronger international emergency response;
  • international reviews of security and safety;
  • binding international standards on safety and security; and
  • international co-operation to ensure regulatory effectiveness.

Coastal nuclear sites must also be further protected against rising sea levels, storm surges, flooding, and possible eventual "nuclear site islanding".[99]

See also

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References

edit
  1. ^ IAEA safety Glossary – Version 2.0 September 2006
  2. ^ a b c Phillip Lipscy, Kenji Kushida, and Trevor Incerti. 2013. "The Fukushima Disaster and Japan's Nuclear Plant Vulnerability in Comparative Perspective Archived 2013-10-29 at the Wayback Machine." Environmental Science and Technology 47 (May), 6082–6088.
  3. ^ a b Hugh Gusterson (16 March 2011). "The lessons of Fukushima". Bulletin of the Atomic Scientists. Archived from the original on 6 June 2013.
  4. ^ a b Diaz Maurin, François (26 March 2011). "Fukushima: Consequences of Systemic Problems in Nuclear Plant Design". Economic & Political Weekly. 46 (13): 10–12. Archived from the original on 11 August 2012. Retrieved 1 November 2017.
  5. ^ a b c d e f Adam Piore (June 2011). "Nuclear energy: Planning for the Black Swan p.32". Scientific American. Retrieved 2014-05-15.
  6. ^ Force V: The history of Britain's airborne deterrent, by Andrew Brookes. Jane's Publishing Co Ltd; First Edition 1 Jan. 1982, ISBN 0710602383, p.101.
  7. ^ "Nuclear Terrorism: Frequently Asked Questions". Belfer Center for Science and International Affairs. September 26, 2007. {{cite journal}}: Cite journal requires |journal= (help)
  8. ^ Vienna International Centre (March 30, 2011). "About IAEA: The "Atoms for Peace" Agency". iaea.org.
  9. ^ a b Stephen Kurczy (March 17, 2011). "Japan nuclear crisis sparks calls for IAEA reform". CSMonitor.com.
  10. ^ IAEA Convention on Nuclear Safety
  11. ^ "Vienna Declaration on Nuclear Safety" (PDF).
  12. ^ The Doomsday Machine, by Martin Cohen and Andrew Mckillop, Palgrave 2012, page 74
  13. ^ a b The Doomsday Machine, by Martin Cohen and Andrew Mckillop, Palgrave 2012, page 72
  14. ^ About NRC, U.S. Nuclear Regulatory Commission, Retrieved 2007-06-01.
  15. ^ Our Governing Legislation, U.S. Nuclear Regulatory Commission, Retrieved 2007-06-01.
  16. ^ Health and Safety Archived 2009-11-12 at the Wayback Machine http://www.australia.gov.au
  17. ^ Radiation Protection Archived 2010-01-03 at the Wayback Machine http://www.arpansa.gov.au
  18. ^ a b Jan Willem Storm van Leeuwen (2008). Nuclear power – the energy balance
  19. ^ Stephanie Cooke (2009). In Mortal Hands: A Cautionary History of the Nuclear Age, Black Inc., p. 280.
  20. ^ Perrow, C. (1982), ‘The President's Commission and the Normal Accident’, in Sils, D., Wolf, C. and Shelanski, V. (Eds), Accident at Three Mile Island: The Human Dimensions, Westview, Boulder, pp.173–184.
  21. ^ Pidgeon, N. (2011). "In retrospect: Normal Accidents". Nature. 477 (7365): 404–405. Bibcode:2011Natur.477..404P. doi:10.1038/477404a.
  22. ^ "Nuclear Power".
  23. ^ Globalsecurity.org: Nuclear Power Plants: Vulnerability to Terrorist Attack p. 3.
  24. ^ Safety of Nuclear Power Reactors, World Nuclear Association, http://www.world-nuclear.org/info/inf06.html Archived 2007-02-04 at the Wayback Machine
  25. ^ Matthew Wald (June 15, 2011). "U.S. Reactors Unprepared for Total Power Loss, Report Suggests". New York Times.
  26. ^ a b c Benjamin K. Sovacool (2011). Contesting the Future of Nuclear Power: A Critical Global Assessment of Atomic Energy, World Scientific, p. 192.
  27. ^ "Update 10 – IAEA Director General Statement on Situation in Ukraine". www.iaea.org. 2022-03-04. Retrieved 2022-03-04.
  28. ^ U.S. NRC: "Nuclear Security – Five Years After 9/11". Accessed 23 July 2007
  29. ^ "N.B. nuclear plant reviewing bids for two new light-armoured vehicles". The National Post. 7 July 2017. Retrieved 7 July 2017.
  30. ^ Threat Assessment: U.S. Nuclear Plants Near Airports May Be at Risk of Airplane Attack Archived 2010-11-10 at the Wayback Machine, Global Security Newswire, June 11, 2003.
  31. ^ Newtan, Samuel Upton (2007). Nuclear War 1 and Other Major Nuclear Disasters of the 20th Century, AuthorHouse, p.146.
  32. ^ "STATEMENT FROM CHAIRMAN DALE KLEIN ON COMMISSION'S AFFIRMATION OF THE FINAL DBT RULE". Nuclear Regulatory Commission. Retrieved 2007-04-07.
  33. ^ "The Nuclear Fuel Cycle". Information and Issue Briefs. World Nuclear Association. 2005. Archived from the original on 2013-03-01. Retrieved 2006-11-10.
  34. ^ Lewis Z Koch (2004). "Dirty Bomber? Dirty Justice". Bulletin of the Atomic Scientists. Retrieved 2006-11-10.
  35. ^ a b Julia Mareike Neles, Christoph Pistner (Hrsg.), Kernenergie. Eine Technik für die Zukunft?, Berlin – Heidelberg 2012, S. 114 f.
  36. ^ a b Julia Mareike Neles, Christoph Pistner (Hrsg.), Kernenergie. Eine Technikkk für die Zukunft?, Berlin – Heidelberg 2012, S. 115.
  37. ^ Manfred Grathwohl, Energieversorgung, Berlin – New York 1983, S. 429.
  38. ^ Terroranschlag auf Atomkraftwerk Biblis würde Berlin bedrohen. In: Der Spiegel
  39. ^ In: Der Spiegel: Biblis nicht gegen Flugzeugabsturz geschützt
  40. ^ Tihange-Mitarbeiter gesperrt, Terroristen spähen Wissenschaftler aus Archived 2016-08-04 at the Wayback Machine, Aachener Zeitung, 24.3.2016
  41. ^ Wolf-Georg Schärf, Europäisches Atomrecht. Recht der Nuklearenergie Berlin – Boston 2012, S. 1.
  42. ^ spiegel.de: Experten warnen vor neuen Terrorgefahren durch Atom-Comeback
  43. ^ a b Dr. Frauke Urban and Dr. Tom Mitchell 2011. Climate change, disasters and electricity generation Archived September 20, 2012, at the Wayback Machine. London: Overseas Development Institute and Institute of Development Studies
  44. ^ 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
  45. ^ a b c d e Jason Clenfield (March 17, 2011). "Japan Nuclear Disaster Caps Decades of Faked Reports, Accidents". Bloomberg Businessweek.[dead link]
  46. ^ ABC News. Strong Quake Rocks Northwestern Japan Archived 2007-08-21 at the Wayback Machine. July 16, 2007.
  47. ^ Xinhua News. Two die, over 200 injured in strong quake in Japan Archived 2012-10-09 at the Wayback Machine. July 16, 2007.
  48. ^ 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
  49. ^ Yoichi Funabashi and Kay Kitazawa (March 1, 2012). "Fukushima in review: A complex disaster, a disastrous response". Bulletin of the Atomic Scientists. 68 (2): 9–21. Bibcode:2012BuAtS..68b...9F. doi:10.1177/0096340212440359. S2CID 145122789. Archived from the original on February 2, 2016. Retrieved August 22, 2016.
  50. ^ "Glossary: Safety-related". Retrieved 2011-03-20.
  51. ^ "What you can do to protect yourself: Be Informed". Nuclear Power Plants | RadTown USA | US EPA. United States Environmental Protection Agency. Retrieved March 12, 2012.
  52. ^ a b Nuclear Information and Resource Service (NIRS): "ROUTINE RADIOACTIVE RELEASES FROM NUCLEAR REACTORS – IT DOESN'T TAKE AN ACCIDENT". March 2015. Archived from the original on May 14, 2011. Retrieved 2016-08-22.{{cite web}}: CS1 maint: bot: original URL status unknown (link)
  53. ^ a b "Nuclear Power: During normal operations, do commercial nuclear power plants release radioactive material?". Radiation and Nuclear Power | Radiation Information and Answers. Radiation Answers. Retrieved March 12, 2012.
  54. ^ "Radiation Dose". Factsheets & FAQs: Radiation in Everyday Life. International Atomic Energy Agency (IAEA). Archived from the original on October 19, 2013. Retrieved March 12, 2012.
  55. ^ "What happens to radiation produced by a plant?". NRC: Frequently Asked Questions (FAQ) About Radiation Protection. Nuclear Regulatory Commission. Retrieved March 12, 2012.
  56. ^ "Is radiation exposure from a nuclear power plant always fatal?". NRC: Frequently Asked Questions (FAQ) About Radiation Protection. Nuclear Regulatory Commission. Retrieved March 12, 2012.
  57. ^ "UNSCEAR 2008 Report to the General Assembly" (PDF). United Nations Scientific Committee on the Effects of Atomic Radiation. 2008.
  58. ^ Hiroko Tabuchi (March 3, 2012). "Japanese Prime Minister Says Government Shares Blame for Nuclear Disaster". The New York Times. Retrieved 2012-04-13.
  59. ^ Yoichi Funabashi (March 11, 2012). "The End of Japanese Illusions". New York Times. Retrieved 2012-04-13.
  60. ^ Wang, Qiang, Xi Chen, and Xu Yi-Chong. "Accident like the Fukushima Unlikely in a Country with Effective Nuclear Regulation: Literature Review and Proposed Guidelines." Renewable and Sustainable Energy Reviews 16.1 (2012): 126–46. Web. 3 July 2016. <http://www.egi.ac.cn/xwzx/kydt/201211/W020121101676826557345.pdf>.
  61. ^ "Kärnfrågan". Fokus (in Swedish). 2015-02-06. Retrieved 2020-06-08.
  62. ^ "Ukraine further diversifies nuclear fuel supply with Canadian deal". www.unian.info. Retrieved 2020-06-08.
  63. ^ a b c "What is Nuclear Waste?". What is Nuclear?.
  64. ^ "Fission 235U". US Nuclear Data Program. Archived from the original on 2014-06-06.
  65. ^ "Fission 233U". US Nuclear Data Program. Archived from the original on 2013-10-09.
  66. ^ "Fission 239Pu". US Nuclear Data Program. Archived from the original on 2013-10-09.
  67. ^ "131I". US Nuclear Data Program. Archived from the original on 2014-02-28.
  68. ^ "129I". US Nuclear Data Program. Archived from the original on 2014-02-28.
  69. ^ "Natural Radioactivity". Idaho State University. Archived from the original on 2017-09-03. Retrieved 2015-02-03.
  70. ^ "Environmental Surveillance, Education and Research Program". Idaho National Laboratory. Archived from the original on 2008-11-21. Retrieved 2009-01-05.
  71. ^ Vandenbosch 2007, p. 21.
  72. ^ Ojovan, M. I.; Lee, W.E. (2005). An Introduction to Nuclear Waste Immobilisation. Amsterdam: Elsevier Science Publishers. p. 315. ISBN 978-0-08-044462-8.
  73. ^ Brown, Paul (2004-04-14). "Shoot it at the sun. Send it to Earth's core. What to do with nuclear waste?". The Guardian. London.
  74. ^ National Research Council (1995). Technical Bases for Yucca Mountain Standards. Washington, D.C.: National Academy Press. p. 91. ISBN 978-0-309-05289-4.
  75. ^ "The Status of Nuclear Waste Disposal". The American Physical Society. January 2006. Retrieved 2008-06-06.
  76. ^ "Public Health and Environmental Radiation Protection Standards for Yucca Mountain, Nevada; Proposed Rule" (PDF). United States Environmental Protection Agency. 2005-08-22. Retrieved 2008-06-06.
  77. ^ Sevior M. (2006). "Considerations for nuclear power in Australia". International Journal of Environmental Studies. 63 (6): 859–872. Bibcode:2006IJEnS..63..859S. doi:10.1080/00207230601047255. S2CID 96845138.
  78. ^ "Thorium Resources In Rare Earth Elements" (PDF). Archived from the original (PDF) on 2012-12-18.
  79. ^ American Geophysical Union, Fall Meeting 2007, abstract #V33A-1161. Mass and Composition of the Continental Crust
  80. ^ Interdisciplinary Science Reviews 23:193–203;1998. Dr. Bernard L. Cohen, University of Pittsburgh. Perspectives on the High Level Waste Disposal Problem
  81. ^ a b c M.V. Ramana. Nuclear Power: Economic, Safety, Health, and Environmental Issues of Near-Term Technologies, Annual Review of Environment and Resources, 2009. 34, pp.139–140.
  82. ^ David Fickling (April 20, 2011). "Areva Says Fukushima A Huge Wake-Up Call For Nuclear Industry". Fox Business. Archived from the original on July 1, 2011.
  83. ^ a b c 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. 381.
  84. ^ a b c d e f Declan Butler (21 April 2011). "Reactors, residents and risk". Nature. 472 (7344): 400–1. doi:10.1038/472400a. PMID 21525903. S2CID 4371109.
  85. ^ "US nearly detonated atomic bomb over North Carolina – secret document". The Guardian. 20 September 2013.
  86. ^ "The Cold War's Missing Atom Bombs". Der Spiegel. 14 November 2008. Archived from the original on 27 June 2019. Retrieved 20 August 2019.
  87. ^ International Panel on Fissile Materials (September 2010). "The Uncertain Future of Nuclear Energy" (PDF). Research Report 9. p. 1.[permanent dead link]
  88. ^ Kennette Benedict (13 October 2011). "The banality of death by nuclear power". Bulletin of the Atomic Scientists. Archived from the original on 25 April 2013. Retrieved 20 October 2011.
  89. ^ David Hinds, Chris Masla (January 2006). "Next-generation nuclear energy: The ESBWR" (PDF). Nuclear news. ans.org. Archived from the original (PDF) on 2010-07-04. Retrieved 2015-02-07.
  90. ^ Stephanie Cooke (March 19, 2011). "Nuclear power is on trial". CNN.com.
  91. ^ a b Kennette Benedict (26 March 2011). "The road not taken: Can Fukushima put us on a path toward nuclear transparency?". Bulletin of the Atomic Scientists. Archived from the original on 11 May 2011.
  92. ^ "Anti-nuclear protests in Germany and France". BBC News. 25 April 2011.
  93. ^ Pandora's box, A is for Atom- Adam Curtis
  94. ^ Lovins, Amory B. and Price, John H. (1975). Non-nuclear Futures: The Case for an Ethical Energy Strategy (Cambridge, Mass.: Ballinger Publishing Company, 1975. xxxii + 223pp. ISBN 0-88410-602-0, ISBN 0-88410-603-9).
  95. ^ Weinberg, Alvin M. (December 1976). "Book review. Non-nuclear futures: the case for an ethical energy strategy". Energy Policy. 4 (4): 363–366. doi:10.1016/0301-4215(76)90031-8. ISSN 0301-4215.
  96. ^ Non-Nuclear Futures, pp. xix–xxi.
  97. ^ Brian Wang (16 March 2011). "Deaths from electricity generation".
  98. ^ Zia Mian & Alexander Glaser (June 2006). "Life in a Nuclear Powered Crowd" (PDF). INESAP Information Bulletin No.26.
  99. ^ a b c European Environment Agency (Jan 23, 2013). "Late lessons from early warnings: science, precaution, innovation: Full report". p. 28,480.
  100. ^ Kristin Shrader-Frechette (19 August 2011). "Cheaper, safer alternatives than nuclear fission". Bulletin of the Atomic Scientists. Archived from the original on 2012-01-21.
  101. ^ Arjun Makhijani (21 July 2011). "The Fukushima tragedy demonstrates that nuclear energy doesn't make sense". Bulletin of the Atomic Scientists. Archived from the original on 2012-01-21.
  102. ^ a b "Hanford Site: Hanford Overview". United States Department of Energy. Archived from the original on 2012-05-11. Retrieved 2012-02-13.
  103. ^ "Science Watch: Growing Nuclear Arsenal". The New York Times. April 28, 1987. Retrieved 2007-01-29.
  104. ^ "An Overview of Hanford and Radiation Health Effects". Hanford Health Information Network. Archived from the original on 2010-01-06. Retrieved 2007-01-29.
  105. ^ "Hanford Quick Facts". Washington Department of Ecology. Archived from the original on 2008-06-24. Retrieved 2010-01-19.
  106. ^ "Hanford Facts". psr.org. Archived from the original on 2015-02-07. Retrieved 2015-02-07.
  107. ^ Stang, John (December 21, 2010). "Spike in radioactivity a setback for Hanford cleanup". Seattle Post-Intelligencer.
  108. ^ Harden, Blaine; Dan Morgan (June 2, 2007). "Debate Intensifies on Nuclear Waste". Washington Post. p. A02. Retrieved 2007-01-29.
  109. ^ Dininny, Shannon (April 3, 2007). "U.S. to Assess the Harm from Hanford". Seattle Post-Intelligencer. Associated Press. Retrieved 2007-01-29.
  110. ^ Schneider, Keith (February 28, 1989). "Agreement for a Cleanup at Nuclear Site". The New York Times. Retrieved 2008-01-30.
  111. ^ Black, Richard (2011-04-12). "Fukushima: As Bad as Chernobyl?". Bbc.co.uk. Retrieved 2011-08-20.
  112. ^ From interviews with Mikhail Gorbachev, Hans Blix and Vassili Nesterenko. The Battle of Chernobyl. Discovery Channel. Relevant video locations: 31:00, 1:10:00.
  113. ^ Kagarlitsky, Boris (1989). "Perestroika: The Dialectic of Change". In Mary Kaldor; Gerald Holden; Richard A. Falk (eds.). The New Detente: Rethinking East-West Relations. United Nations University Press. ISBN 978-0-86091-962-9.
  114. ^ "IAEA Report". In Focus: Chernobyl. International Atomic Energy Agency. Archived from the original on 2007-12-17. Retrieved 2006-03-29.
  115. ^ Hallenbeck, William H (1994). Radiation Protection. CRC Press. p. 15. ISBN 978-0-87371-996-4. Reported thus far are 237 cases of acute radiation sickness and 31 deaths.
  116. ^ Igor Koudrik & Alexander Nikitin (13 December 2011). "Second life: The questionable safety of life extensions for Russian nuclear power plants". Bulletin of the Atomic Scientists. Archived from the original on 25 March 2013. Retrieved 4 April 2013.
  117. ^ Richard Schiffman (12 March 2013). "Two years on, America hasn't learned lessons of Fukushima nuclear disaster". The Guardian. London.
  118. ^ a b c Martin Fackler (June 1, 2011). "Report Finds Japan Underestimated Tsunami Danger". New York Times.
  119. ^ "Nuclear Safety Chief Says Lax Rules Led to Fukushima Crisis". Bloomberg. 16 February 2012.[dead link]
  120. ^ "Blow-ups happen: Nuclear plants can be kept safe only by constantly worrying about their dangers". The Economist. 10 March 2012.
  121. ^ a b c Louise Fréchette & Trevor Findlay (March 28, 2011). "Nuclear safety is the world's problem". Ottawa Citizen.[permanent dead link]
  122. ^ Hannah Northey (March 28, 2011). "Japanese Nuclear Reactors, U.S. Safety to Take Center Stage on Capitol Hill This Week". New York Times.
  123. ^ a b "Japan says it was unprepared for post-quake nuclear disaster". Los Angeles Times. June 8, 2011. Archived from the original on June 8, 2011.
  124. ^ James Kanter (March 25, 2011). "Europe to Test Safety of Nuclear Reactors". New York Times.
  125. ^ James Paton (April 4, 2011). "Fukushima Crisis Worse for Atomic Power Than Chernobyl, UBS Says". Bloomberg Businessweek. Archived from the original on 2011-05-15.
  126. ^ a b Dennis Normile (28 November 2011). "In Wake of Fukushima Disaster, Japan's Scientists Ponder How to Regain Public Trust". Science. Archived from the original on 28 November 2011.
  127. ^ Hiroko Tabuchi (January 15, 2012). "Panel Challenges Japan's Account of Nuclear Disaster". New York Times.
  128. ^ "Japan Post-Fukushima Reactor Checks 'Insufficient,' Advisers Say". Businessweek. January 27, 2012. Archived from the original on February 14, 2012.
  129. ^ Hiroko Tabuchi (March 3, 2012). "Japanese Prime Minister Says Government Shares Blame for Nuclear Disaster". The New York Times.
  130. ^ Newtan, Samuel Upton (2007). Nuclear War 1 and Other Major Nuclear Disasters of the 20th Century, AuthorHouse.
  131. ^ "The Worst Nuclear Disasters – Photo Essays – TIME". Time. 2009-03-25. Archived from the original on March 28, 2009. Retrieved 2015-02-07.
  132. ^ a b Arifumi Hasegawa, Koichi Tanigawa, Akira Ohtsuru, Hirooki Yabe, Masaharu Maeda, et al. "Health effects of radiation and other health problems in the aftermath of nuclear accidents, with an emphasis on Fukushima Archived 2009-08-07 at the Wayback Machine", Lancet, Volume 386, No. 9992, pp. 479–488, 1 August 2015.
  133. ^ "Fossil fuels are far deadlier than nuclear power – tech – 23 March 2011 – New Scientist". Archived from the original on 2011-03-25. Retrieved 2015-02-07.
  134. ^ 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". American Journal of Public Health. 97 (9): 1595–600. doi:10.2105/AJPH.2006.103044. PMC 1963288. PMID 17666688.
  135. ^ a b Annabelle Quince (30 March 2011). "The history of nuclear power". ABC Radio National.
  136. ^ a b "Evacuees of Fukushima village report split families, growing frustration". Mainichi Daily News. January 30, 2012. Archived from the original on January 30, 2012.
  137. ^ Walsh, Bryan (March 2013). "Meltdown: Despite the Fear, the Health Risks from the Fukushima Accident Are Minimal". Time – via science.time.com.
  138. ^ "Medical Hazards of Radioactive Waste" (PDF). PNFA. Archived from the original (PDF) on 2013-04-10.
  139. ^ M. V. Ramana (July 2011). "Nuclear power and the public". Bulletin of the Atomic Scientists. 67 (4): 48. Bibcode:2011BuAtS..67d..43R. doi:10.1177/0096340211413358. S2CID 144321178. Archived from the original on 2016-02-01. Retrieved 2011-09-29.
  140. ^ NRC pdf on generations of FCVSs
  141. ^ "Severe accident mitigation through improvements in filtered containment vent systems and containment cooling strategies for water cooled reactors". International Atomic Energy Agency. 2017. Retrieved 2019-08-03.
  142. ^ Moore, Scott (2022). China's next act : how sustainability and technology are reshaping China's rise and the world's future. New York, NY. p. 210. ISBN 978-0-19-760401-4. OCLC 1316703008.{{cite book}}: CS1 maint: location missing publisher (link)
  143. ^ "The Little Known Success Story of U.S.-China Nuclear Security Cooperation". The Nuclear Threat Initiative. 2022-07-26. Archived from the original on 26 July 2022. Retrieved 2022-07-26.{{cite news}}: CS1 maint: bot: original URL status unknown (link)
  144. ^ a b Massot, Pascale (2024). China's Vulnerability Paradox: How the World's Largest Consumer Transformed Global Commodity Markets. New York, NY, United States of America: Oxford University Press. ISBN 978-0-19-777140-2.
  145. ^ a b Charles D. Ferguson & Frank A. Settle (2012). "The Future of Nuclear Power in the United States" (PDF). Federation of American Scientists.
  146. ^ Kennette Benedict (9 August 2012). "Civil disobedience". Bulletin of the Atomic Scientists.
  147. ^ Jay Davis. After A Nuclear 9/11 The Washington Post, March 25, 2008.
  148. ^ Brian Michael Jenkins. A Nuclear 9/11? CNN.com, September 11, 2008.
  149. ^ Orde Kittrie. Averting Catastrophe: Why the Nuclear Non-proliferation Treaty is Losing its Deterrence Capacity and How to Restore It Archived 2010-06-07 at the Wayback Machine May 22, 2007, p. 338.
  150. ^ Nicholas D. Kristof. A Nuclear 9/11 The New York Times, March 10, 2004.
  151. ^ Zetter, Kim (25 March 2013). "Legal Experts: Stuxnet Attack on Iran Was Illegal 'Act of Force'". Wired.
  152. ^ Introduction to Fusion Energy, J. Reece Roth, 1986.[page needed]
  153. ^ T. Hamacher & A.M. Bradshaw (October 2001). "Fusion as a Future Power Source: Recent Achievements and Prospects" (PDF). World Energy Council. Archived from the original (PDF) on 2004-05-06.
  154. ^ W Wayt Gibbs (30 December 2013). "Triple-threat method sparks hope for fusion". Nature. 505 (7481): 9–10. Bibcode:2014Natur.505....9G. doi:10.1038/505009a. PMID 24380935.
  155. ^ a b "Beyond ITER". The ITER Project. Information Services, Princeton Plasma Physics Laboratory. Archived from the original on 2006-11-07. Retrieved 2011-02-05. – Projected fusion power timeline
  156. ^ "Overview of EFDA Activities". EFDA. European Fusion Development Agreement. Archived from the original on 2006-10-01. Retrieved 2006-11-11.
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