Fukushima Daiichi nuclear disaster
||This article's introduction may be too long for the overall article length. (November 2015)|
Image on 16 March 2011 of the four damaged reactor buildings. From right to left: Unit 1, 2, 3 and 4. Hydrogen-air explosions occurred in Unit 1, 3 and 4, causing structural damage. A vent in Unit 2's wall, with water vapor/"steam" clearly visible, prevented a similar large explosion. Drone overflights on 20 March captured clearer images.
|Date||11 March 2011|
|Location||Ōkuma, Fukushima, Japan|
|Outcome||INES Level 7 (Major accident)|
|Non-fatal injuries||37 with physical injuries,[not in citation given]
2 workers taken to hospital with radiation burns
The Fukushima Daiichi nuclear disaster (福島第一原子力発電所事故 Fukushima Dai-ichi ( pronunciation) genshiryoku hatsudensho jiko?) was an energy accident at the Fukushima I Nuclear Power Plant, initiated primarily by the tsunami of the Tōhoku earthquake and tsunami on 11 March 2011. The damage caused by the tsunami produced equipment failures, and without this equipment a loss-of-coolant accident followed with three nuclear meltdowns and releases of radioactive materials beginning on 12 March. It is the largest nuclear disaster since the Chernobyl disaster of 1986 and the second disaster (after Chernobyl) to be given the Level 7 event classification of the International Nuclear Event Scale.
The plant comprised six separate boiling water reactors originally designed by General Electric (GE) and maintained by the Tokyo Electric Power Company (TEPCO). At the time of the earthquake, reactors 4, 5 and 6 were shut down in preparation for re-fueling. However, their spent fuel pools still required cooling. Immediately after the earthquake, the electricity producing reactors 1, 2 and 3 automatically shut down their sustained fission reactions, inserting control rods in what is termed a SCRAM. Following this legally mandated "safety precaution" which ceases the reactors' normal running conditions, the reactors were unable to generate power to run their own coolant pumps. Emergency diesel generators came online, as designed, to power electronics and coolant systems, all of which operated right up until the tsunami destroyed the generators for reactors 1–5 due to their location in unhardened low-lying areas. The two generators cooling reactor 6 were undamaged and were sufficient to be pressed into service to cool the neighboring reactor 5 along with their own reactor, averting the overheating issues that reactor 4 suffered.
The largest wave in the tsunami arrived some 50 minutes after the initial earthquake. The 13 meter tall wave overwhelmed the plant's seawall, which was only 10 m high, with the moment of impact being caught on camera. Water quickly flooded the low-lying rooms in which the emergency generators were housed. The flooded diesel generators failed soon afterwards, cutting power to the critical pumps that must continuously circulate coolant water through a Generation II reactor for several days to keep the fuel rods from melting down following the SCRAM event, as the ceramic fuel pellets in the fuel rods continue to generate Decay heat even after the fission process has terminated. The fuel rods will become hot enough to melt themselves down during the fuel decay time period if no adequate cold sink is available. After the secondary emergency pumps (run by back-up electrical batteries) ran out, one day after the tsunami, 12 March, the water pumps stopped and the reactors began to overheat due to the high decay heat produced in the first few days after the SCRAM (diminishing amounts of this decay heat continue to be released for years, but with time, passive cooling through water convection in a pool is sufficient to prevent fuel rod melting).
As workers struggled to supply power to the reactors' coolant systems and restore power to their control rooms, a number of hydrogen-air chemical explosions occurred, the first in Unit 1, on 12 March and the last in Unit 4, on 15 March. It is estimated that the hot zirconium fuel cladding-water reaction in reactors 1-3 produced 800 to 1000 kilograms of hydrogen gas each, which was vented out of the reactor pressure vessel, and mixed with the ambient air, eventually reaching explosive concentration limits in units 1 and 3, and due to piping connections between units 3 and 4, or alternatively from the same reaction occurring in the spent fuel pool in unit 4 itself, unit 4 also filled with hydrogen, with the hydrogen-air explosions occurring at the top of each unit, that is in their upper secondary containment building. Drone overflights on 20 March and afterwards captured clear images of the effects of each explosion on the outside structures, while the view inside was largely obscured by shadows and debris.
There have been no fatalities linked to short term overexposure to radiation reported due to the Fukushima accident, while approximately 18,500 people died due to the earthquake and tsunami. However approximately 610 are estimated to have died due to workers' exposure and the evacuation of residents near the power plant. Estimates of the total human fatalities caused by the nuclear accident are up to 10,000, maximum cancer mortality and morbidity is calculated to be respectively 1,500 and 1,800. In addition, the rates of mental illnesses among evacuated people rose fivefold compared to the Japanese average.
In 2013, the World Health Organization (WHO) indicated that the residents of the area who were evacuated were exposed to low amounts of radiation and that radiation induced health impacts are likely to be low. In particular, the 2013 WHO report predicts that for evacuated infant girls, their 0.75% pre-accident lifetime risk of developing thyroid cancer is calculated to be increased to 1.25% by being exposed to radioiodine, with the increase being slightly less for males. While the risks from a number of additional Radiation-induced cancers are also expected to be elevated due to exposure caused by the other low boiling point fission products that were released by the safety failures. The single greatest increase is for thyroid cancer, but in total, an overall 1% higher lifetime risk of developing cancers of all types, is predicted for infant females, with the risk slightly lower for males, making both some of the most radiation-sensitive goups. Along with those within the womb, which the WHO predicted, depending on their gender, to have the same elevations in risk as the infant groups.
A screening program a year later in 2012 found that more than a third (36%) of children in Fukushima Prefecture have abnormal growths in their thyroid glands. As of August 2013, there have been more than 40 children newly diagnosed with thyroid cancer and other cancers in Fukushima prefecture as a whole. However whether these incidences of cancer are elevated above the rate in un-contaminated areas and therefore were due to exposure to nuclear radiation is unknown at this stage. Data from the Chernobyl accident showed that an unmistakable rise in thyroid cancer rates following the disaster in 1986 only began after a cancer incubation period of 3–5 years, however whether this data can be directly compared to the Fukushima nuclear disaster is still yet to be determined.
A survey by the newspaper Mainichi Shimbun computed that of some 300,000 people who evacuated the area, approximately 1,600 deaths related to the evacuation conditions, such as living in temporary housing and hospital closures have occurred as of August 2013, a number comparable to the 1,599 deaths directly caused by the earthquake and tsunami in the Fukushima Prefecture in 2011. With the exact cause of the majority of these evacuation related deaths not being specified, as according to the municipalities, that would hinder the deceased relatives' application for condolence money compensation.
On 5 July 2012, the Japanese National Diet appointed The Fukushima Nuclear Accident Independent Investigation Commission (NAIIC) submitted its inquiry report to the Japanese Diet. The Commission found the nuclear disaster was "manmade", that the direct causes of the accident were all foreseeable prior to 11 March 2011. The report also found that the Fukushima Daiichi Nuclear Power Plant was incapable of withstanding the earthquake and tsunami. TEPCO, the regulatory bodies (NISA and NSC) and the government body promoting the nuclear power industry (METI), all failed to correctly develop the most basic safety requirements—such as assessing the probability of damage, preparing for containing collateral damage from such a disaster, and developing evacuation plans for the public in the case of a serious radiation release. Meanwhile, the government appointed Investigation Committee on the Accident at the Fukushima Nuclear Power Stations of Tokyo Electric Power Company submitted its final report to the Japanese government on 23 July 2012. A separate study by Stanford researchers found that Japanese plants operated by the largest utility companies were particularly unprotected against potential tsunami.
TEPCO admitted for the first time on 12 October 2012 that it had failed to take stronger measures to prevent disasters for fear of inviting lawsuits or protests against its nuclear plants. There are no clear plans for decommissioning the plant, but the plant management estimate is thirty or forty years. A frozen soil barrier is being constructed in order to prevent ongoing exposure of running groundwater with melted down nuclear fuel.
- 1 Background
- 2 Plant description
- 3 Events
- 4 Response
- 5 Event rating
- 6 Aftermath
- 7 Reactions
- 8 See also
- 9 References
- 10 External links
Following the 1999 Tokaimura criticality accident, there was interest in Japan for developing radiation-resistant robots for use in the event of nuclear accidents- other countries (e.g. Germany and France) already had them available. The Japanese government budgeted 3 billion yen (US $38 million) for research and development. Several companies produced state of the art prototypes in 2001, which were tested and deemed technical successes. In December 2002, a task force (which included TEPCO executives) further concluded that the robots were unnecessary: the possibility of Chernobyl-scale disasters was completely discounted and it was thus assumed that human employees- compared to whom the robots had limited speed and range- would still be able to operate in the event of an accident. The program halted, and the prototypes remained in storage until March 2006; some were subsequently donated to Tohoku University. The termination of the program left Japan without functional radiation-resistant robots to send into Fukushima when the crisis began.
As the crisis unfolded, the Japanese government sent a request for robots developed by the U.S. military. The robots went into the plants, and took pictures to help assess the situation, but they couldn't perform the full range of tasks usually carried out by human workers. Following Fukushima, efforts to develop humanoid robots that could supplement relief efforts have accelerated dramatically.
Similarly, pre-Fukushima, Japan's Nuclear Safety Commission said in its safety guidelines for light-water nuclear facilities that "the potential for extended loss of power need not be considered."
Three investigations into the Fukushima disaster showed the man-made nature of the catastrophe and its roots in regulatory capture associated with a "network of corruption, collusion, and nepotism." Regulatory capture refers to the "situation where regulators charged with promoting the public interest defer to the wishes and advance the agenda of the industry or sector they ostensibly regulate." Those with a vested interest in specific policy or regulatory outcomes lobby regulators and influence their choices and actions. Regulatory capture explains why some of the risks of operating nuclear power reactors in Japan were systematically downplayed and mismanaged so as to compromise operational safety.
Many reports say that the government shares blame with the regulatory agency for not heeding warnings and for not ensuring the independence of the oversight function. The New York Times said that the Japanese nuclear regulatory system sided with and promoted the nuclear industry because of amakudari ('descent from heaven') in which senior regulators accepted high paying jobs at companies they once oversaw. To protect their potential future position in the industry, regulators sought to avoid taking positions that upset or embarrass the companies. TEPCO's position as the largest electrical utility in Japan made it the most desirable position for retiring regulators. Typically the "most senior officials went to work at TEPCO, while those of lower ranks ended up at smaller utilities."
In August 2011, several top energy officials were fired by the Japanese government; affected positions included the Vice-minister for Economy, Trade and Industry; the head of the Nuclear and Industrial Safety Agency, and the head of the Agency for Natural Resources and Energy.
Simplified cross-section sketch of a typical BWR Mark I containment as used in units 1 to 5.
RPV: reactor pressure vessel.
DW: dry well enclosing reactor pressure vessel.
WW: wet well - torus-shaped all around the base enclosing steam suppression pool. Excess steam from the dry well enters the wet well water pool via downcomer pipes.
SFP: spent fuel pool area.
SCSW: secondary concrete shield wall.
The Fukushima I (Daiichi) Nuclear Power Plant consists of six GE light water, boiling water reactors (BWR) with a combined power of 4.7 gigawatts, making Fukushima Daiichi one of the world's 25 largest nuclear power stations. Fukushima Daiichi was the first GE-designed nuclear plant to be constructed and run entirely by the Tokyo Electric Power Company (TEPCO).
Reactor 1 is a 439 MWe type (BWR-3) reactor constructed in July 1967. It commenced operation on 26 March 1971. It was designed to withstand an earthquake with a peak ground acceleration of 0.18 g (1.74 m/s2) and a response spectrum based on the 1952 Kern County earthquake. Reactors 2 and 3 are both 784 MWe type BWR-4. Reactor 2 commenced operating in July 1974, and Reactor 3 in March 1976. The earthquake design basis for all units ranged from 0.42 g (4.12 m/s2) to 0.46 g (4.52 m/s2).
All units were inspected after the 1978 Miyagi earthquake when the ground acceleration reached 0.125 g (1.22 m/s2) for 30 seconds, but no damage to the critical parts of the reactor was discovered.
Units 1–5 have a Mark 1 type (light bulb torus) containment structure; unit 6 has Mark 2 type (over/under) containment structure. In September 2010, Reactor 3 was partially fueled by mixed-oxides (MOX).
At the time of the accident, the units and central storage facility contained the following numbers of fuel assemblies:
Location Unit 1 Unit 2 Unit 3 Unit 4 Unit 5 Unit 6 Central Storage Reactor Fuel Assemblies 400 548 548 0 548 764 0 Spent Fuel Assemblies 292 587 514 1331 946 876 6375 Fuel UO
New Fuel Assemblies 100 28 52 204 48 64 N/A
There is no MOX fuel in any of the cooling ponds. The only MOX fuel is loaded in the Unit 3 reactor.
These reactors generate electricity by using the heat of the fission reaction to create steam. When the reactor stops operating, the radioactive decay of unstable isotopes continues to generate heat for a time. This decay and the decay heat that results requires continued cooling. Initially this decay heat amounts to approximately 6% of the amount produced by fission, decreasing over several days before reaching cold shutdown levels.
The decay heat in the Unit 4 spent fuel pool had the capacity to boil about 70 tonnes of water per day (12 gallons per minute). On 16 April 2011, TEPCO declared that cooling systems for Units 1-4 were beyond repair and would have to be replaced.
In the reactor core, circulation is accomplished via high pressure systems that cycle water between the reactor pressure vessel and heat exchangers. These systems then transfer heat to a secondary heat exchanger via the essential service water system, using water that is pumped out to sea or an onsite cooling tower.
Units 2 and 3 were equipped with steam-turbine driven emergency core cooling systems that can be directly operated by steam produced by decay heat and which can inject water directly into the reactor. Some electrical power is needed to operate valves and monitoring systems.
Unit 1 was equipped with a different cooling system, the "Isolation Condenser" or "IC", which is entirely passive. This consists of a series of pipes run from the reactor core to the inside of a large tank of water. When the valves are opened, steam flows upward to the IC where the cool water in the tank condenses the steam back to water, and it runs under gravity back to the reactor core. For reasons that are unclear, at the beginning, Unit 1's IC was operated only intermittently during the emergency. However, during a 25 March 2014 presentation to the TVA, Dr Takeyuki Inagaki explained that the IC was being operated intermittently to maintain reactor vessel level and to prevent the core from cooling too quickly which can increase reactor power. Unfortunately, as the tsunami engulfed the station, the IC valves were closed and could not be reopened automatically due to the loss of electrical power, but could have been opened manually.
Two emergency diesel generators were available for each of units 1–5 and three for unit 6.
In the late 1990s, three additional backup generators for Units 2 and 4 were placed in new buildings located higher on the hillside, to comply with new regulatory requirements. All six units were given access to these generators, but the switching stations that sent power from these backup generators to the reactors' cooling systems for Units 1 through 5 were still in the poorly protected turbine buildings. All three of the generators added in the late 1990s were operational after the tsunami. If the switching stations had been moved to inside the reactor buildings or to other flood-proof locations, power would have been provided by these generators to the reactors' cooling systems.
The reactor's emergency diesel generators and DC batteries, crucial components in powering cooling systems after a power loss, were located in the basements of the reactor turbine buildings, in accordance with GE's specifications. Mid-level engineers expressed concerns that this left them vulnerable to flooding.
Fukushima II was also struck by the tsunami. However, it had incorporated design changes that improved its resistance to flooding, reducing flood damage. Generators and related electrical distribution equipment were located in the watertight reactor building, so that power from the electricity grid was being used by midnight. Seawater pumps for cooling were protected from flooding, and although 3 of 4 initially failed, they were restored to operation.
Central fuel storage areas
Used fuel assemblies taken from reactors are initially stored for at least 18 months in the pools adjacent to their reactors. They can then be transferred to the central fuel storage pond. Fukushima I's storage area contains 6375 fuel assemblies. After further cooling, fuel can be transferred to dry cask storage, which has shown no signs of abnormalities.
Many of the internal components and fuel assembly cladding are made from zircaloy because it is relatively transparent to neutrons. At normal operating temperatures of approximately 300 °C (572 °F), zircaloy is inert. However, above 1200 degrees Celsius, zirconium metal can react exothermically with water to form free hydrogen gas. The reaction between zirconium and the coolant produces more heat, accelerating the reaction.
1967: Layout of the emergency-cooling system
On 27 February 2012, NISA ordered TEPCO to report by 12 March 2012 regarding its reasoning in changing the piping layout for the emergency cooling system. These changes were made after the plans were registered in 1966 and the beginning of construction.
The original plans separated the piping systems for two reactors in the isolation condenser from each other. However, the application for approval of the construction plan showed the two piping systems connected outside the reactor. The changes were not noted, in violation of regulations.
After the tsunami, the isolation condenser should have taken over the function of the cooling pumps, by condensing the steam from the pressure vessel into water to be used for cooling the reactor. But the condenser did not function properly and TEPCO could not confirm whether a valve was opened.
1991: Back-up generator of reactor 1 flooded
On 30 October 1991, one of two backup generators of Reactor 1 failed, after flooding in the reactor's basement. Seawater used for cooling leaked into the turbine building from a corroded pipe at 20 cubic meters per hour, as reported by former employees in December 2011. An engineer was quoted as saying that he informed his superiors and of the possibility that a tsunami could damage the generators. TEPCO installed doors to prevent water from leaking into the generator rooms.
The Japanese Nuclear Safety Commission commented that it would revise its safety guidelines and would require the installation of additional power sources. On 29 December 2011, TEPCO admitted all these facts: its report mentioned that the room was flooded through a door and some holes for cables, but the power supply was not cut off by the flooding, and the reactor was stopped for one day. One of the two power sources was completely submerged, but its drive mechanism had remained unaffected.
2008: Tsunami study ignored
In 2007, TEPCO set up a department to supervise its nuclear facilities. Until June 2011 its chairman was Masao Yoshida, the Fukushima Daiichi chief. A 2008 in-house study identified an immediate need to better protect the facility from flooding by seawater. This study mentioned the possibility of tsunami-waves up to 10.2 metres (33 ft). Headquarters officials insisted that such a risk was unrealistic and did not take the prediction seriously.[verification needed]
A Mr. Okamura of the Active Fault and Earthquake Research Center urged TEPCO and NISA to review their assumption of possible tsunami heights based on a tenth century earthquake, but it was not seriously considered at that time. The U.S. Nuclear Regulatory Commission warned of a risk of losing emergency power in 1991 (NUREG-1150) and NISA referred to the report in 2004. No action to mitigate the risk was taken.
The plant was located in Japan, which, like the rest of the Pacific Rim, is in an active seismic zone. The International Atomic Energy Agency (IAEA) had expressed concern about the ability of Japan's nuclear plants to withstand seismic activity. At a 2008 meeting of the G8's Nuclear Safety and Security Group in Tokyo, an IAEA expert warned that a strong earthquake with a magnitude above 7.0 could pose a "serious problem" for Japan's nuclear power stations. The region had experienced three earthquakes of magnitude greater than 8, including the 869 Jogan Sanriku earthquake, the 1896 Meiji-Sanriku earthquake, and the 1933 Sanriku earthquake.
The 9.0 MW Tōhoku earthquake occurred at 14:46 on Friday, 11 March 2011 with epicenter near Honshu Island. It produced maximum ground g-forces of 0.56, 0.52, 0.56 (5.50, 5.07 and 5.48 m/s2) at units 2, 3 and 5 respectively. This exceeded their design tolerances of 0.45, 0.45 and 0.46 g (4.38, 4.41 and 4.52 m/s2). The shock values were within the design tolerances at units 1, 4 and 6.
When the earthquake struck, units 1, 2 and 3 were operating, but units 4, 5 and 6 had been shut down for periodic inspection. Reactors 1, 2 and 3 immediately underwent an automatic shutdown (called SCRAM).
When the reactors shut down, the plant stopped generating electricity, cutting off power. One of the two connections to off-site power for units 1–3 also failed, so 13 on-site emergency diesel generators began providing power.
The earthquake triggered a 13-to-15-metre (43 to 49 ft) maximum height tsunami that arrived approximately 50 minutes later. The waves overtopped the plant's 5.7 metres (19 ft) seawall, flooding the basements of the turbine buildings and disabling the emergency diesel generators at approximately 15:41.
TEPCO then notified authorities of a "first level emergency".
The switching stations that provided power from the three backup generators located higher on the hillside failed when the building that housed them flooded. Power for control systems switched over to batteries that were designed to last about eight hours. Further batteries and mobile generators were dispatched to the site. They were delayed by poor road conditions and the first arrived only at 21:00 11 March, almost six hours after the tsunami.
Multiple unsuccessful attempts were made to connect portable generating equipment to power water pumps. The failure was attributed to flooding at the connection point in the Turbine Hall basement and the absence of suitable cables. TEPCO switched its efforts to installing new lines from the grid. One generator at unit 6 resumed operation on 17 March, while external power returned to units 5 and 6 only on 20 March.
The government initially set in place a 4-stage evacuation process: a prohibited access area out to 3 km, an on-alert area 3–20 km and an evacuation prepared area 20–30 km. On day one nearly 134,000 people were evacuated from the prohibited access and on-alert areas. Four days later an additional 354,000 were evacuated from the prepared area. Later, Prime Minister Kan instructed people within the on-alert area to leave, and urged those in the prepared area to stay indoors. The latter groups were urged to evacuate on 25 March.
The 20 kilometer exclusion zone was guarded by roadblocks to ensure that fewer people would be affected by the radiation.
Units 1, 2 and 3
|This section requires expansion. (August 2013)|
On 12 March, an explosion in Unit 1 was caused by the ignition of the hydrogen, destroying the upper part of the building.
On 14 March, a similar explosion occurred in the Reactor 3 building, blowing off the roof and injuring eleven people.
On the 15th, There was an explosion in the Reactor 2 building due a shared vent pipe with reactor 3.
There exists considerable uncertainty about the amount of damage the reactor cores sustained during the accident – TEPCO revised several times over the past years the estimates about the extent of the core melt for the three affected reactor units and the location of the molten nuclear fuel ("Corium") within the containment buildings. As of 2015 it can be assumed that most fuel has melted through the Reactor Pressure Vessel (RPV, commonly known as the "reactor core") and is resting on the bottom of the Primary Containment Vessel (PCV), having been stopped by the concrete of the PCV.
On 16 March 2011 TEPCO estimated that 70% of the fuel in Unit 1 had melted, and 33% in Unit 2, further suspecting that Unit 3's core might also be damaged.
In the TEPCO report of the Modular Accident Analysis Program (MAAP) from November 2011, further estimates are made to the state and location of the fuel. The report came to the conclusion that the RPV in Unit 1 had been damaged during the disaster, and that "significant amounts" of molten fuel had fallen into the bottom of the PCV – the erosion of the concrete of the PCV by the molten fuel after the core meltdown was estimated to stop in approx. 0.7 metres (2 ft 4 in) in depth, while the thickness of the containment is 7.6 metres (25 ft) thick. Gas sampling done before the report detected no signs of an ongoing reaction of the fuel with the concrete of the PCV and all the fuel in Unit 1 was estimated to be "well cooled down, including the fuel dropped on the bottom of the reactor".
Furthermore, the 2011 MAAP report showed that fuel in Units 2 and 3 had melted, however less than Unit 1, and fuel was presumed to be still in the RPV, with no significant amounts of fuel fallen to the bottom of the PCV. The report further suggested that "there is a range in the evaluation results" from "all fuel in the RPV (none fuel fallen to the PCV)" in Unit 2 and Unit 3, to "most fuel in the RPV (some fuel in PCV)". For Unit 2 and Unit 3 it was estimated that the "fuel is cooled sufficiently". The larger damage in Unit 1 in comparison with the other two units was according to the report due to longer time that no cooling water was injected in Unit 1, which resulted in much more decay heat to accumulate – for about 1 day there was no water injection for Unit 1, while Unit 2 and Unit 3 had only a quarter of a day without water injection.
In November 2013 Mari Yamaguchi reported for Associated Press that there are computer simulations which suggest that "the melted fuel in Unit 1, whose core damage was the most extensive, has breached the bottom of the primary containment vessel and even partially eaten into its concrete foundation, coming within about 30 centimeters (one foot) of leaking into the ground" – a Kyoto University nuclear engineer said with regards to these estimates: "We just can't be sure until we actually see the inside of the reactors."
According to a December 2013 report TEPCO estimated for Unit 1 that "the decay heat must have decreased enough, the molten fuel can be assumed to remain in PCV (Primary container vessel)".
In August 2014 TEPCO released a new revised estimate that reactor 3 had a complete melt through in the initial phase of the accident. According to this new estimate within the first three days of the accident the entire core content of reactor 3 had melted through the RPV and fallen to the bottom of the PCV. These estimates were based on a simulation, which indicated that reactor 3's melted core penetrated through 1.2 metres (3 ft 11 in) of the PCV's concrete base, and came close to 26–68 centimetres (10–27 in) of the PCV's steel wall.
In February 2015 TEPCO started the "Muon scanning" process for Units 1, 2 and 3. With this scanning setup it will be possible to determine the approximate amount and location of the remaining nuclear fuel within the reactor pressure vessel (RPV), but not the amount and resting place of the Corium in the PCV. In March 2015 TEPCO released the result of the Muon scan for Unit 1 which showed that no fuel was visible in the RPV, which would suggest that most if not all of the molten fuel had dropped onto the bottom of the PCV - this will change the plan for the removal of the fuel from Unit 1.
Units 4, 5 and 6
Reactor 4 was not operating when the earthquake struck. All fuel rods from Unit 4 had been transferred to the spent fuel pool on an upper floor of the reactor building prior to the tsunami. On 15 March, an explosion damaged the fourth floor rooftop area of Unit 4, creating two large holes in a wall of the outer building. It was reported that water in the spent fuel pool might be boiling. Radiation inside the Unit 4 control room prevented workers from staying there for long periods. Visual inspection of the spent fuel pool on 30 April revealed no significant damage to the rods. A radiochemical examination of the pond water confirmed that little of the fuel had been damaged.
In November 2013, TEPCO started the process of moving the 1533 fuel rods in the Unit 4 cooling pool to the central pool. This process was completed on 22 December 2014.
Units 5 and 6
Reactors 5 and 6 were also not operating when the earthquake struck. Unlike Reactor 4, their fuel rods remained in the reactor. The reactors had been closely monitored, as cooling processes were not functioning well.
Central fuel storage areas
On 21 March, temperatures in the fuel pond had risen slightly, to 61 °C and water was sprayed over the pool. Power was restored to cooling systems on 24 March and by 28 March, temperatures were reported down to 35 °C.
- Sub article: Comparison of Fukushima and Chernobyl nuclear accident with detailed tables inside
Radioactive material was released from the containment vessels for several reasons: deliberate venting to reduce gas pressure, deliberate discharge of coolant water into the sea, and uncontrolled events. Concerns about the possibility of a large scale release led to a 20-kilometre (12 mi) exclusion zone around the power plant and recommendations that people within the surrounding 20–30 km zone stay indoors. Later, the UK, France and some other countries told their nationals to consider leaving Tokyo, in response to fears of spreading contamination. Trace amounts of radioactivity, including iodine-131, caesium-134 and caesium-137, were widely observed.
Between 21 March and mid-July, around 2.7 × 1016 Bq of caesium-137 (about 8.4 kg) entered the ocean, with about 82 percent having flowed into the sea before 8 April. This emission of radioactivity into the sea represents the most important individual emission of artificial radioactivity into the sea ever observed. However, the Fukushima coast has some of the world's strongest currents and these transported the contaminated waters far into the Pacific Ocean, thus causing great dispersion of the radioactive elements. The results of measurements of both the seawater and the coastal sediments led to the supposition that the consequences of the accident, in terms of radioactivity, would be minor for marine life as of autumn 2011 (weak concentration of radioactivity in the water and limited accumulation in sediments). On the other hand, significant pollution of sea water along the coast near the nuclear plant might persist, due to the continuing arrival of radioactive material transported towards the sea by surface water running over contaminated soil. Organisms that filter water and fish at the top of the food chain are, over time, the most sensitive to caesium pollution. It is thus justified to maintain surveillance of marine life that is fished in the coastal waters off Fukushima. Despite caesium isotopic concentration in the waters off of Japan being 10 to 1000 times above concentration prior to the accident, radiation risks are below what is generally considered harmful to marine animals and human consumers.
A monitoring system operated by the Preparatory Commission for the Comprehensive Nuclear-Test-Ban Treaty Organization (CTBTO) tracked the spread of radioactivity on a global scale. Radioactive isotopes were picked up by over 40 monitoring stations.
On 12 March, radioactive releases first reached a CTBTO monitoring station in Takasaki, Japan, around 200 km away. The radioactive isotopes appeared in eastern Russia on 14 March and the west coast of the United States two days later. By day 15, traces of radioactivity were detectable all across the northern hemisphere. Within one month, radioactive particles were noted by CTBTO stations in the southern hemisphere.
In March 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". On 21 March, the first restrictions were placed on the distribution and consumption of contaminated items. As of July 2011[update], the Japanese government was unable to control the spread of radioactive material into the nation's food supply. Radioactive material was detected in food produced in 2011, including spinach, tea leaves, milk, fish and beef, up to 320 kilometres from the plant. 2012 crops did not show signs of radioactivity contamination. Cabbage, rice and beef showed insignificant levels of radioactivity. A Fukushima-produced rice market in Tokyo was accepted by consumers as safe.
On 24 August 2011, the Nuclear Safety Commission (NSC) of Japan published the results of the recalculation of the total amount of radioactive materials released into the air during the accident at the Fukushima Daiichi Nuclear Power Station. The total amounts released between 11 March and 5 April were revised downwards to 130 PBq (petabecquerels, 3.5 megacuries) for iodine-131 and 11 PBq for caesium-137, which is about 11% of Chernobyl emissions. Earlier estimations were 150 PBq and 12 PBq.
In 2011 scientists working for the Japan Atomic Energy Agency, Kyoto University and other institutes, recalculated the amount of radioactive material released into the ocean: between late March through April they found a total of 15 PBq for the combined amount of iodine-131 and caesium-137, more than triple the 4.72 PBq estimated by TEPCO. The company had calculated only the direct releases into the sea. The new calculations incorporated the portion of airborne radioactive substances that entered the ocean as rain.
In the first half of September 2011 TEPCO estimated the radioactivity release at some 200 MBq (megabecquerels, 5.4 millicuries) per hour. This was approximately one four-millionth that of March. Traces of iodine-131 were detected in several Japanese prefectures in November and December 2011.
According to the French Institute for Radiological Protection and Nuclear Safety, between 21 March and mid-July around 27 PBq of caesium-137 entered the ocean, about 82 percent before 8 April. This emission represents the most important individual oceanic emissions of artificial radioactivity ever observed. The Fukushima coast has one of the world's strongest currents (Kuroshio Current). It transported the contaminated waters far into the Pacific Ocean, dispersing the radioactivity. As of late 2011 measurements of both the seawater and the coastal sediments suggested that the consequences for marine life would be minor. Significant pollution along the coast near the plant might persist, because of the continuing arrival of radioactive material transported to the sea by surface water crossing contaminated soil. The possible presence of other radioactive substances, such as strontium-90 or plutonium, has not been sufficiently studied. Recent measurements show persistent contamination of some marine species (mostly fish) caught along the Fukushima coast. Migratory pelagic species are highly effective and rapid transporters of radioactivity throughout the ocean. Elevated levels of 134 Cs appeared in migratory species off the coast of California that were not seen pre-Fukushima.
As of March 2012, no cases of radiation-related ailments had been reported. Experts cautioned that data was insufficient to allow conclusions on health impacts. Michiaki Kai, professor of radiation protection at Oita University of Nursing and Health Sciences, stated, "If the current radiation dose estimates are correct, (cancer-related deaths) likely won't increase."
In May 2012, TEPCO released their estimate of cumulative radioactivity releases. An estimated 538.1 PBq of iodine-131, caesium-134 and caesium-137 was released. 520 PBq was released into the atmosphere between 12–31 March 2011 and 18.1 PBq into the ocean from 26 March – 30 September 2011. A total of 511 PBq of iodine-131 was released into both the atmosphere and the ocean, 13.5 PBq of caesium-134 and 13.6 PBq of caesium-137. TEPCO reported that at least 900 PBq had been released "into the atmosphere in March last year  alone".
In 2012 researchers from the Institute of Problems in the Safe Development of Nuclear Energy, Russian Academy of Sciences, and the Hydrometeorological Center of Russia concluded that "on March 15, 2011, ~400PBq iodine, ~100PBq cesium, and ~400PBq inert gases entered the atmosphere" on that day alone.
As of October 2012 radioactivity was still leaking into the ocean. Fishing in the waters around the site was still prohibited, and the levels of radioactive 134Cs and 137Cs in the fish caught were not lower than immediately after the disaster.
On 26 October 2012 TEPCO admitted that it could not stop radioactive material entering the ocean, although emission rates had stabilised. Undetected leaks could not be ruled out, because the reactor basements remained flooded. The company was building a 2,400-foot-long steel and concrete wall between the site and the ocean, reaching 100 feet below ground, but it would not be finished before mid-2014. Around August 2012 two greenling were caught close to shore. They contained more than 25,000 becquerels (0.67 millicuries) of caesium-137 per kilogram, the highest measured since the disaster and 250 times the government's safety limit.
On 22 July 2013 it was revealed by TEPCO that the plant continued to leak radioactive water into the Pacific Ocean, something long suspected by local fishermen and independent investigators. TEPCO had previously denied that this was happening. Japanese Prime Minister Shinzō Abe ordered the government to step in.
On 20 August, in a further incident, it was announced that 300 metric tons of heavily contaminated water had leaked from a storage tank, approximately the same amount of water as one eighth (1/8) of that found in an Olympic-size swimming pool. The 300 metric tons of water was radioactive enough to be hazardous to nearby staff, and the leak was assessed as Level 3 on the International Nuclear Event Scale.
On 26 August, the government took charge of emergency measures to prevent further radioactive water leaks, reflecting their lack of confidence in TEPCO.
As of 2013, about 400 tonnes per day of cooling water was being pumped into the reactors. Another 400 tonnes of groundwater was seeping into the structure. Some 800 tonnes of water per day was removed for treatment, half of which was reused for cooling and half diverted to storage tanks. Ultimately the contaminated water, after treatment to remove radionuclides other than tritium, may have to be dumped into Pacific. TEPCO intend to create an underground ice wall to reduce the rate contaminated groundwater reaches the sea.
In February 2014, NHK reported that TEPCO was reviewing its radioactivity data, after finding much higher levels of radioactivity than was reported earlier. TEPCO now says that levels of 5 million becquerels (0.12 millicuries) of strontium per liter were detected in groundwater collected in July 2013 and not 900,000 becquerels (0.02 millicuries), as initially reported.
On 10 September 2015, floodwaters driven by Typhoon Etau prompted mass evacuations in Japan and overhelmed the drainage pumps at the stricken Fukushima nuclear plant. A TEPCO spokesperson said that hundreds of tonnes of radioactive water had entered the ocean as a result. Plastic bags filled with contaminated soil and grass were also swept away by the flood waters.
Contamination in the eastern Pacific
In March 2014, numerous news sources, including NBC, began predicting that the radioactive underwater plume traveling through the Pacific Ocean would reach the western seaboard of the continental United States. The common story was that the amount of radioactivity would be harmless and temporary once it arrived. The National Oceanic and Atmospheric Administration measured cesium-134 at points in the Pacific Ocean and models were cited in predictions by several government agencies to announce that the radiation would not be a health hazard for North American residents. Groups, including Beyond Nuclear and the Tillamook Estuaries Partnership, challenged these predictions on the basis of continued isotope releases after 2011, leading to a demand for more recent and comprehensive measurements as the radioactivity made its way east. These measurements were taken by a cooperative group of organizations under the guidance of a marine chemist with the Woods Hole Oceanographic Institution, and it was revealed that total radiation levels, of which only a fraction bore the fingerprint of Fukushima, were not high enough to pose any direct risk to human life and in fact were far less than Environmental Protection Agency guidelines or several other sources of radiation exposure deemed safe. Integrated Fukushima Ocean Radionuclide Monitoring project (InFORM) also failed to show any significant amount of radiation and as result authors received death threats from supporterts of Fukushima-induced "wave of cancer deaths across North America" theory.
Government agencies and TEPCO were unprepared for the "cascading nuclear disaster". The tsunami that "began the nuclear disaster could and should have been anticipated and that ambiguity about the roles of public and private institutions in such a crisis was a factor in the poor response at Fukushima". In March 2012, Prime Minister Yoshihiko Noda said that the 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 taken in by a "safety myth". Noda said "Everybody must share the pain of responsibility."
According to Naoto Kan, Japan's prime minister during the tsunami, the country was unprepared for the disaster, and nuclear power plants should not have been built so close to the ocean. Kan acknowledged flaws in authorities' handling of the crisis, including poor communication and coordination between nuclear regulators, utility officials and the government. He said the disaster "laid bare a host of an even bigger man-made vulnerabilities in Japan's nuclear industry and regulation, from inadequate safety guidelines to crisis management, all of which he said need to be overhauled."
Physicist and environmentalist Amory Lovins said that Japan's "rigid bureaucratic structures, reluctance to send bad news upwards, need to save face, weak development of policy alternatives, eagerness to preserve nuclear power's public acceptance, and politically fragile government, along with TEPCO's very hierarchical management culture, also contributed to the way the accident unfolded. Moreover, the information Japanese people receive about nuclear energy and its alternatives has long been tightly controlled by both TEPCO and the government."
Poor communication and delays
The Japanese government did not keep records of key meetings during the crisis. Data from SPEEDI (System for Prediction of Environmental Emergency Dose Information) were emailed to the prefectural government, but not shared with others. Emails from NISA to Fukushima, covering 12 March 11:54 PM to 16 March 9 AM and holding vital information for evacuation and health advisories, went unread and were deleted. The data was not used because the disaster countermeasure office regarded the data as "useless because the predicted amount of released radiation is unrealistic."
The Investigation Committee on the Accident at the Fukushima Nuclear Power Stations of Tokyo Electric Power Company's interim report stated that Japan's response was flawed by "poor communication and delays in releasing data on dangerous radiation leaks at the facility". The report blamed Japan's central government as well as TEPCO, "depicting a scene of harried officials incapable of making decisions to stem radiation leaks as the situation at the coastal plant worsened in the days and weeks following the disaster". The report said poor planning worsened the disaster response, noting that authorities had "grossly underestimated tsunami risks" that followed the magnitude 9.0 earthquake. The 12.1 metre (40 ft) high tsunami that struck the plant was double the height of the highest wave predicted by officials. The erroneous assumption that the plant's cooling system would function after the tsunami worsened the disaster. "Plant workers had no clear instructions on how to respond to such a disaster, causing miscommunication, especially when the disaster destroyed backup generators."
In February 2012, the Rebuild Japan Initiative Foundation described how Japan's response was hindered by a loss of trust between the major actors: Prime Minister Kan, TEPCO's Tokyo headquarters and the plant manager. The report said that these conflicts "produced confused flows of sometimes contradictory information". According to the report, Kan delayed the cooling of the reactors by questioning the choice of seawater instead of fresh water, accusing him of micromanaging response efforts and appointing a small, closed, decision-making staff. The report stated that the Japanese government was slow to accept assistance from U.S. nuclear experts.
A 2012 report in The Economist said: "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".
From 17 to 19 March 2011, US military aircraft measured radiation within a 45-km radius of the site. The data recorded 125 microsieverts per hour of radiation as far as 25 km (15.5 mi) northwest of the plant. The US provided detailed maps to the Japanese Ministry of Economy, Trade, and Industry (METI) on 18 March and to the Ministry of Education, Culture, Sports, Science and Technology (MEXT) two days later, but officials did not act on the information.
The data were not forwarded to the prime minister's office or the Nuclear Safety Commission (NSC), nor were they used to direct the evacuation. Because a substantial portion of radioactive materials reached ground to the northwest, residents evacuated in this direction were unnecessarily exposed to radiation. According to NSC chief Tetsuya Yamamoto, "It was very regrettable that we didn't share and utilize the information." Itaru Watanabe, from the Science and Technology Policy Bureau, blamed the US for not releasing the data.
After the Americans published their map on 23 March, Japan published fallout maps compiled from ground measurements and SPEEDI the same day. On 19 June 2012, science minister Hirofumi Hirano stated that his "job was only to measure radiation levels on land" and that the government would study whether disclosure could have helped in the evacuation efforts.
The incident was rated 7 on the International Nuclear Event Scale (INES). This scale runs from 0, indicating an abnormal situation with no safety consequences, to 7, indicating an accident causing widespread contamination with serious health and environmental effects. Prior to Fukushima, the Chernobyl disaster was the only level 7 event on record, while the Three Mile Island accident was rated as level 5.
A 2012 analysis of the intermediate and long-lived radioactivity released found about 10-20% of that released from the Chernobyl disaster. Approximately 15 PBq of caesium-137 was released, compared with approximately 85 PBq of caesium-137 at Chernobyl, indicating the release of 24 kilograms (53 lb) of caesium-137.
Unlike Chernobyl, all Japanese reactors were in concrete containment vessels, which limited the release of strontium-90, americium-241 and plutonium, which were among the radioisotopes released by the earlier incident.
Some 500 PBq of iodine-131 were released, compared to approximately 1,760 PBq at Chernobyl. Iodine-131 has a half life of 8.02 days, decaying into a stable nuclide. After ten half lives (80.2 days), 99.9% has decayed to xenon-131, a stable isotope.
Risks from radiation
Very few cancers would be expected as a result of accumulated radiation exposures, even though people in the area worst affected by Japan's Fukushima nuclear accident have a slightly higher risk of developing certain cancers such as leukemia, solid cancers, thyroid cancer and breast cancer.
Estimated effective doses from the accident outside of Japan are considered to be below (or far below) the dose levels regarded as very small by the international radiological protection community.
In 2013 WHO reported that area residents who were evacuated were exposed to so little radiation that radiation induced health impacts were likely to be below detectable levels. The health risks were calculated by applying conservative assumptions, including the conservative linear no-threshold model of radiation exposure, a model that assumes even the smallest amount of radiation exposure will cause a negative health effect. The report indicated that for those infants in the most affected areas, lifetime cancer risk would increase by about 1%. It predicted that populations in the most contaminated areas faced a 70% higher relative risk of developing thyroid cancer for females exposed as infants, and a 7% higher relative risk of leukemia in males exposed as infants and a 6% higher relative risk of breast cancer in females exposed as infants. One-third of involved emergency workers would have increased cancer risks. Cancer risks for fetuses were similar to those in 1 year old infants. The estimated cancer risk to children and adults was lower than infants.
The stated risks were relative and not absolute. The baseline risk of thyroid cancer in females is 0.75%, predicted to increase to 1.25%, a "70% higher relative risk". This implies an estimated increase of only 15 in the number of female thyroid cancer cases (and approximately five male cases). As the five-year non-survival rate for thyroid cancer is 4.2% and falling rapidly (halving each decade), it is more likely than not that the number of eventual deaths will be zero.
These percentages represent estimated relative increases over the baseline rates and are not absolute risks for developing such cancers. Due to the low baseline rates of thyroid cancer, even a large relative increase represents a small absolute increase in risks. For example, the baseline lifetime risk of thyroid cancer for females is just (0.75%) three-quarters of one percent and the additional lifetime risk estimated in this assessment for a female infant exposed in the most affected location is (0.5%)one-half of one percent.
According to a linear no-threshold model (LNT model), the accident would most likely cause 130 cancer deaths. Radiation epidemiologist Roy Shore countered that estimating health effects from the LNT model "is not wise because of the uncertainties".
In April 2014 studies confirmed the presence of radioactive tuna off the coasts of the pacific U.S. Researchers carried out tests on 26 albacore tuna caught prior to the 2011 power plant disaster and those caught after. Although levels were small, less than the amount of radioactivity found naturally in a single banana, evidence is still present on the fish from the Fukushima nuclear disaster.
Thyroid screening program
The World Health Organization stated that a 2013 thyroid ultrasound screening programme was, due to the screening effect, likely to lead to an increase in recorded thyroid cases due to early detection of non-symptomatic disease cases. The overwhelming majority of thyroid growths are benign growths that will never cause symptoms, illness or death, even if nothing is ever done about the growth. Autopsy studies on people who died from other causes show that more than one third of adults technically have a thyroid growth/cancer.
According to the Tenth Report of the Fukushima Prefecture Health Management Survey released in February 2013, more than 40% of children screened around Fukushima prefecture were diagnosed with thyroid nodules or cysts. Ultrasonographic detectable thyroid nodules and cysts are extremely common and can be found at a frequency of up to 67% in various studies. 186 (0.5%) of these had nodules larger than 5.1 mm and/or cysts larger than 20.1 mm and underwent further investigation, while none had thyroid cancer. A Russia Today report into the matter was highly misleading. Fukushima Medical University give the number of children diagnosed with thyroid cancer, as of December 2013, as 33 and concluded "it is unlikely that these cancers were caused by the exposure from I-131 from the nuclear power plant accident in March 2011". Thyroid cancer is one of the most survivable cancers, with an approximate 94% survival rate after first diagnosis. That rate increases to a nearly 100% survival rate if caught early.
Radiation deaths at Chernobyl were also statistically undetectable. Only 0.1% of the 110,645 Ukraninian cleanup workers, included in a 20-year study out of over 500,000 former Soviet clean up workers, had as of 2012 developed leukemia, although not all cases resulted from the accident.
Data from Chernobyl showed that there was a steady then sharp increase in thyroid cancer rates following the disaster in 1986, but whether this data can be directly compared to Fukushima is yet to be determined.
Chernobyl thyroid cancer incidence rates did not begin to increase above the prior baseline value of about 0.7 cases per 100,000 people per year until 1989 to 1991, 3–5 years after the incident in both adolescent and child age groups. From 1989 to 2005, an excess of 4,000 children and adolescent cases of thyroid cancer were observed. Nine of these had died as of 2005, a 99% survival rate.
Effects on evacuees
In the former Soviet Union, many patients with negligible radioactive exposure after the Chernobyl disaster displayed extreme anxiety about radiation exposure. They developed many psychosomatic problems, including radiophobia along with an increase in fatalistic alcoholism. As Japanese health and radiation specialist Shunichi Yamashita noted:
We know from Chernobyl that the psychological consequences are enormous. Life expectancy of the evacuees dropped from 65 to 58 years -- not [predominantly] because of cancer, but because of depression, alcoholism and suicide. Relocation is not easy, the stress is very big. We must not only track those problems, but also treat them. Otherwise people will feel they are just guinea pigs in our research.
A survey by the Iitate local government obtained responses from approximately 1,743 evacuees within the evacuation zone. The survey showed that many residents are experiencing growing frustration, instability and an inability to return to their earlier lives. Sixty percent of respondents stated that their health and the health of their families had deteriorated after evacuating, while 39.9% reported feeling more irritated compared to before the disaster.
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% live away from other family members (including elderly parents) with whom they lived before the disaster. The survey also showed that 34.7% of the evacuees have suffered salary cuts of 50% or more since the outbreak of the nuclear disaster. A total of 36.8% reported a lack of sleep, while 17.9% reported smoking or drinking more than before they evacuated.
Stress often manifests in physical ailments, including behavioral changes such as poor dietary choices, lack of exercise and sleep deprivation. Survivors, including some who lost homes, villages and family members, were found likely to face mental health and physical challenges. Much of the stress came from lack of information and from relocation.
A survey computed that of some 300,000 evacuees, approximately 1,600 deaths related to the evacuation conditions, such as living in temporary housing and hospital closures that had occurred as of August 2013, a number comparable to the 1,599 deaths directly caused by the earthquake and tsunami in the Prefecture. The exact causes of these evacuation related deaths were not specified, because according to the municipalities, that would hinder relatives applying for compensation.
In June 2011, TEPCO stated the amount of contaminated water in the complex had increased due to substantial rainfall. On 13 February 2014, TEPCO reported 37,000 becquerels (1.0 microcurie) of cesium-134 and 93,000 becquerels (2.5 microcuries) of cesium-137 were detected per liter of groundwater sampled from a monitoring well.
According to reinsurer Munich Re, the private insurance industry will not be significantly affected by the disaster. Swiss Re similarly stated, "Coverage for nuclear facilities in Japan excludes earthquake shock, fire following earthquake and tsunami, for both physical damage and liability. Swiss Re believes that the incident at the Fukushima nuclear power plant is unlikely to result in a significant direct loss for the property & casualty insurance industry."[not in citation given]
Energy policy implications
By March 2012, one year after the disaster, all but two of Japan's nuclear reactors had been shut down; some had been damaged by the quake and tsunami. Authority to restart the others after scheduled maintenance throughout the year was given to local governments, who in all cases decided against. According to The Japan Times, the disaster changed the national debate over energy policy almost overnight. "By shattering the government's long-pitched safety myth about nuclear power, the crisis dramatically raised public awareness about energy use and sparked strong anti-nuclear sentiment". An energy white paper, approved by the Japanese Cabinet in October 2011, says "public confidence in safety of nuclear power was greatly damaged" by the disaster and called for a reduction in the nation's reliance on nuclear power. It also omitted a section on nuclear power expansion that was in the previous year's policy review.
Michael Banach, the current Vatican representative to the IAEA, told a conference in Vienna in September 2011 that the disaster created new concerns about the safety of nuclear plants globally. Auxiliary Bishop of Osaka Michael Goro Matsuura said this incident should cause Japan and other countries to abandon nuclear projects. He called on the worldwide Christian community to support this anti-nuclear campaign. Statements from Bishops' conferences in Korea and the Philippines called on their governments to abandon atomic power. Author Kenzaburō Ōe, who received a Nobel prize in literature, urged Japan to abandon its reactors.
The nuclear plant closest to the epicenter of the earthquake, the Onagawa Nuclear Power Plant, successfully withstood the cataclysm. According to Reuters it may serve as a "trump card" for the nuclear lobby, providing evidence that it is possible for a correctly designed and operated nuclear facility to withstand such a cataclysm.
The loss of 30% of the country's generating capacity led to much greater reliance on liquified natural gas and coal. Unusual conservation measures were undertaken. In the immediate aftermath, nine prefectures served by TEPCO experienced power rationing. The government asked major companies to reduce power consumption by 15%, and some shifted their weekends to weekdays to smooth power demand. Converting to a nuclear-free gas and oil energy economy would cost tens of billions of dollars in annual fees. One estimate is that even including the disaster, more lives would have been lost if Japan had used coal or gas plants instead of nuclear.
Many political activists have begun calling for a phase-out of nuclear power in Japan, including Amory Lovins, who claimed, "Japan is poor in fuels, but is the richest of all major industrial countries in renewable energy that can meet the entire long-term energy needs of an energy-efficient Japan, at lower cost and risk than current plans. Japanese industry can do it faster than anyone — if Japanese policymakers acknowledge and allow it". Benjamin K. Sovacool asserted that Japan could have exploited instead its renewable energy base. Japan has a total of "324 GW of achievable potential in the form of onshore and offshore wind turbines (222 GW), geothermal power plants (70 GW), additional hydroelectric capacity (26.5 GW), solar energy (4.8 GW) and agricultural residue (1.1 GW)." Perspective is also required here. To provide all of Japan's energy needs with wind at 2.5 W/m2, and operating 1/3 of the time, it would require 127.3 million multiplied by 7847.8 kWh/yr, which would require wind farms which cover 50,000,000,000/365 m2 or approximately 140,000 km2 or about 40% of Japanese land area at 377,944. km2. Germany’s solar parks in Bavaria produce about 5 W/m2 of land area, and thus 70,000 km2 would be required.
In contrast, others have said that the zero mortality rate from the Fukushima incident confirms their opinion that nuclear fission is the only viable option available to replace fossil fuels. Journalist George Monbiot wrote "Why Fukushima made me stop worrying and love nuclear power." In it he said "As a result of the disaster at Fukushima, I am no longer nuclear-neutral. I now support the technology."
He continues "A crappy old plant with inadequate safety features was hit by a monster earthquake and a vast tsunami. The electricity supply failed, knocking out the cooling system. The reactors began to explode and melt down. The disaster exposed a familiar legacy of poor design and corner-cutting. Yet, as far as we know, no one has yet received a lethal dose of radiation."
In September 2011, Mycle Schneider said that the disaster can be understood as a unique chance "to get it right" on energy policy. "Germany – with its nuclear phase-out decision based on a renewable energy program – and Japan – having suffered a painful shock but possessing unique technical capacities and societal discipline – can be at the forefront of an authentic paradigm shift toward a truly sustainable, low-carbon and nuclear-free energy policy".
On the other hand, climate and energy scientists James Hansen, Ken Caldeira, Kerry Emanuel and Tom Wigley released an open letter calling on world leaders to support development of safer nuclear power systems, stating "There is no credible path to climate stabilization that does not include a substantial role for nuclear power."  In December 2014, an open letter from 75 climate and energy scientists concluding "nuclear power has lowest impact on wildlife and ecosystems — which is what we need given the dire state of the world’s biodiversity."
As of September 2011[update], Japan planned to build a pilot offshore floating wind farm, with six 2 MW turbines, off the Fukushima coast. The first became operational in November 2013. After the evaluation phase is complete in 2016, "Japan plans to build as many as 80 floating wind turbines off Fukushima by 2020." In 2012, Prime Minister Kan said the disaster made it clear to him that "Japan needs to dramatically reduce its dependence on nuclear power, which supplied 30% of its electricity before the crisis, and has turned him into a believer of renewable energy". Sales of solar panels in Japan rose 30.7% to 1,296 MW in 2011, helped by a government scheme to promote renewable energy. Canadian Solar received financing for its plans to build a factory in Japan with capacity of 150 MW, scheduled to begin production in 2014.
As of September 2012, the Los Angeles Times reported that "Prime Minister Yoshihiko Noda acknowledged that the vast majority of Japanese support the zero option on nuclear power", and Prime Minister Noda and the Japanese government announced plans to make the country nuclear-free by the 2030s. They announced the end to construction of nuclear power plants and a 40-year limit on existing nuclear plants. Nuclear plant restarts must meet safety standards of the new independent regulatory authority. The plan requires investing $500 billion over 20 years.
On 16 December 2012, Japan held its general election. The Liberal Democratic Party (LDP) had a clear victory, with Shinzō Abe as the new Prime Minister. Abe supported nuclear power, saying that leaving the plants closed was costing the country 4 trillion yen per year in higher costs. The comment came after Junichiro Koizumi, who chose Abe to succeed him as premier, made a recent statement to urge the government to take a stance against using nuclear power. A survey on local mayors by the Yomiuri Shimbun newspaper in January 2013 found that most of them from cities hosting nuclear plants would agree to restarting the reactors, provided the government could guarantee their safety. More than 30,000 people marched on 2 June 2013, in Tokyo against restarting nuclear power plants. Marchers had gathered more than 8 million petition signatures opposing nuclear power.
In October 2013, it was reported that TEPCO and eight other Japanese power companies were paying approximately 3.6 trillion yen (37 billion dollars) more in combined imported fossil fuel costs compared to 2010, before the accident, to make up for the missing power.
Equipment, facility and operational changes
A number of nuclear reactor safety system lessons emerged from the incident. The most obvious was that in tsunami-prone areas, a power station's sea wall must be adequately tall and robust. At the Onagawa Nuclear Power Plant, closer to the epicenter of 11 March earthquake and tsunami, the sea wall was 14 meters tall and successfully withstood the tsunami, preventing serious damage and radioactivity releases.
Nuclear power station operators around the world began to install Passive Auto-catalytic hydrogen Recombiners ("PARs"), which do not require electricity to operate. PARs work much like the catalytic converter on the exhaust of a car to turn potentially explosive gases such as hydrogen into water. Had such devices been positioned at the top of Fukushima I's reactor and containment buildings, where hydrogen gas collected, the explosions would not have occurred and the releases of radioactive isotopes would arguably have been much less.
Unpowered filtering systems on containment building vent lines, known as Filtered Containment Venting Systems (FCVS), can safely catch radioactive materials and thereby allow reactor core de-pressurization, with steam and hydrogen venting with minimal radioactivity emissions. Filtration using an external water tank system is the most common established system in European countries, with the water tank positioned outside the containment building. In October 2013, the owners of Kashiwazaki-Kariwa nuclear power station began installing wet filters and other safety systems, with completion anticipated in 2014.
For generation II reactors located in flood or tsunami prone areas, a 3+ day supply of back-up batteries has become an informal industry standard. Another change is to harden the location of back-up diesel generator rooms with water-tight, blast-resistant doors and heat sinks, similar to those used by nuclear submarines. The oldest operating nuclear power station in the world, Beznau, which has been operating since 1969, has a 'Notstand' hardened building designed to support all of its systems independently for 72 hours in the event of an earthquake or severe flooding. This system was built prior to Fukushima Daiichi.
Upon a station blackout, similar to the one that occurred after Fukushima's back-up battery supply was exhausted, many that had constructed Generation III reactors adopt the principle of passive nuclear safety. They take advantage of convection (hot water tends to rise) and gravity (water tends to fall) to ensure an adequate supply of cooling water and do not require pumps to handle the decay heat.
Japanese authorities later admitted to lax standards and poor oversight. They took fire for their handling of the emergency and engaged in a pattern of withholding and denying damaging information. Authorities allegedly[dubious ] wanted to "limit the size of costly and disruptive evacuations in land-scarce Japan and to avoid public questioning of the politically powerful nuclear industry". Public anger emerged over an "official campaign[not in citation given] to play down the scope of the accident and the potential health risks".
In many cases, the Japanese government's reaction was judged to be less than adequate by many in Japan, especially those who were living in the region. Decontamination equipment was slow to be made available and then slow to be utilized. As late as June 2011, even rainfall continued to cause fear and uncertainty in eastern Japan because of its possibility of washing radioactivity from the sky back to earth.
To assuage fears, the government enacted an order to decontaminate over a hundred areas with a level contamination greater than or equivalent to one millisievert[clarification needed] of radiation. This is a much lower threshold than is necessary for protecting health. The government also sought to address the lack of education on the effects of radiation and the extent to which the average person was exposed.
Previously a proponent of building more reactors, Kan took an increasingly anti-nuclear stance following the disaster. In May 2011, he ordered the aging Hamaoka Nuclear Power Plant closed over earthquake and tsunami concerns, and said he would freeze building plans. In July 2011, Kan said, "Japan should reduce and eventually eliminate its dependence on nuclear energy". In October 2013, he said that if the worst-case scenario had been realized, 50 million people within a 250-kilometer radius would have had to evacuate.
On 22 August 2011, a government spokesman mentioned the possibility that some areas around the plant "could stay for some decades a forbidden zone". According to Yomiuri Shimbun the Japanese government was planning to buy some properties from civilians to store waste and materials that had become radioactive after the accidents. Chiaki Takahashi, Japan's foreign minister, criticized foreign media reports as excessive. He added that he could "understand the concerns of foreign countries over recent developments at the nuclear plant, including the radioactive contamination of seawater".
Due to frustration with TEPCO and the Japanese government "providing differing, confusing, and at times contradictory, information on critical health issues" a citizen's group called "Safecast" recorded detailed radiation level data in Japan. The Japanese government "does not consider nongovernment readings to be authentic". The group uses off-the-shelf Geiger counter equipment. A simple Geiger counter is a contamination meter and not a dose rate meter. The response differs too much between different radioisotopes to permit a simple GM tube for dose rate measurements when more than one radioisotope is present. A thin metal shield is needed around a GM tube to provide energy compensation to enable it to be used for dose rate measurements. For gamma emitters either an ionization chamber, a gamma spectrometer or an energy compensated GM tube are required. Members of the Air Monitoring station facility at the Department of Nuclear Engineering at the University of Berkeley, California have tested many environmental samples in Northern California.
The international reaction to the disaster was diverse and widespread. Many inter-governmental agencies immediately offered help, often on an ad hoc basis. Responders included IAEA, World Meteorological Organization and the Preparatory Commission for the Comprehensive Nuclear Test Ban Treaty Organization.
In May 2011, UK chief inspector of nuclear installations Mike Weightman traveled to Japan as the lead of an International Atomic Energy Agency (IAEA) expert mission. The main finding of this mission, as reported to the IAEA ministerial conference that month, was that risks associated with tsunamis in several sites in Japan had been underestimated.
In September 2011, IAEA Director General Yukiya Amano said the Japanese nuclear disaster "caused deep public anxiety throughout the world and damaged confidence in nuclear power". Following the disaster, it was reported in the The Economist that the IAEA halved its estimate of additional nuclear generating capacity to be built by 2035.
In the aftermath, Germany accelerated plans to close its nuclear power reactors and decided to phase the rest out by 2022. Italy held a national referendum, in which 94 percent voted against the government's plan to build new nuclear power plants. In France, President Hollande announced the intention of the government to reduce nuclear usage by one third. So far, however, the government has only earmarked one power station for closure - the aging plant at Fessenheim on the German border - which prompted some to question the government's commitment to Hollande's promise. Industry Minister Arnaud Montebourg is on record as saying that Fessenheim will be the only nuclear power station to close.
On a visit to China in December he reassured his audience that nuclear energy was a "sector of the future" and would continue to contribute "at least 50%" of France's electricity output.
Another member of Hollande's Socialist Party, the MP Christian Bataille, says the plan to curb nuclear was hatched as a way of securing the backing of his Green coalition partners in parliament.
Nuclear power plans were not abandoned in Malaysia, the Philippines, Kuwait and Bahrain, or radically changed, as in Taiwan. China suspended its nuclear development program briefly, but restarted it shortly afterwards. The initial plan had been to increase the nuclear contribution from 2 to 4 percent of electricity by 2020, with an escalating program after that. Renewable energy supplies 17 percent of China’s electricity, 16% of which is hydroelectricity. China plans to triple its nuclear energy output to 2020, and triple it again between 2020 and 2030.
New nuclear projects were proceeding in some countries. KPMG reports 653 new nuclear facilities planned or proposed for completion by 2030. By 2050, China hopes to have 400-500 gigawatts of nuclear capacity – 100 times more than it has now. The Conservative Government of the United Kingdom is planning a major nuclear expansion despite widespread public objection. So is Russia. India are also pressing ahead with a large nuclear program, as is South Korea. Indian Vice President M Hamid Ansari said recently 
The Fukushima Nuclear Accident Independent Investigation Commission (NAIIC) was the first independent investigation commission by the National Diet in the 66-year history of Japan's constitutional government.
Fukushima "cannot be regarded as a natural disaster," the NAIIC panel's chairman, Tokyo University professor emeritus Kiyoshi Kurokawa, wrote in the inquiry report. "It was a profoundly man-made disaster – that could and should have been foreseen and prevented. And its effects could have been mitigated by a more effective human response." "Governments, regulatory authorities and Tokyo Electric Power [TEPCO] lacked a sense of responsibility to protect people's lives and society," the Commission said. "They effectively betrayed the nation's right to be safe from nuclear accidents.
The Commission recognized that the affected residents were still struggling and facing grave concerns, including the "health effects of radiation exposure, displacement, the dissolution of families, disruption of their lives and lifestyles and the contamination of vast areas of the environment".
The purpose of the Investigation Committee on the Accident at the Fukushima Nuclear Power Stations (ICANPS) was to identify the disaster's causes and propose policies designed to minimize the damage and prevent the recurrence of similar incidents. The 10 member, government-appointed panel included scholars, journalists, lawyers and engineers. It was supported by public prosecutors and government experts and released its final, 448-page investigation report on 23 July 2012.
The panel's report faulted an inadequate legal system for nuclear crisis management, a crisis-command disarray caused by the government and TEPCO, and possible excess meddling on the part of the Prime Minister's office in the crisis' early stage. The panel concluded that a culture of complacency about nuclear safety and poor crisis management led to the nuclear disaster.
- Comparison of Fukushima and Chernobyl nuclear accidents
- Fukushima disaster cleanup
- Japanese nuclear incidents
- Japanese Nuclear Safety Commission
- List of civilian nuclear accidents
- Lists of nuclear disasters and radioactive incidents
- Nuclear power in Japan
- Timeline of the Fukushima Daiichi nuclear disaster
- Radiation effects from the Fukushima Daiichi nuclear disaster
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|Wikimedia Commons has media related to Fukushima Daichi nuclear disaster.|
- The Fukushima Nuclear Accident Independent Investigation Commission Report website in English
- Executive summary of the Fukushima Nuclear Accident Independent Investigation Commission Report
- Investigation Committee on the accidents at the Fukushima Nuclear Power Station of Tokyo Electric Power Company
- The Radioactive Waters of Fukushima
- Lessons Learned From Fukushima Dai-ichi - Report & Movie
Video, drawings and images
- Webcam Fukushima nuclear power plant I, Unit 1 through Unit 4
- Inside the slow and dangerous clean up of the Fukushima nuclear crisis
- TerraFly Timeline Aerial Imagery of Fukushima Nuclear Reactor after 2011 Tsunami and Earthquake
- In graphics: Fukushima nuclear alert, as provided by the BBC, 9 July 2012
- TEPCO News Releases, Tokyo Electric Power Company
- "Reassessment of Fukushima Nuclear Accident and Outline of Nuclear Safety Reform Plan(Interim Report)" by TEPCO Nuclear Reform Special Task Force.14 December 2012