Fukushima Disaster Cleanup
   HOME

TheInfoList



OR:

The Fukushima disaster cleanup is an ongoing attempt to limit
radioactive contamination Radioactive contamination, also called radiological pollution, is the deposition of, or presence of radioactive substances on surfaces or within solids, liquids, or gases (including the human body), where their presence is unintended or undesirab ...
from the three nuclear reactors involved in the
Fukushima Daiichi nuclear disaster The was a nuclear accident in 2011 at the Fukushima Daiichi Nuclear Power Plant in Ōkuma, Fukushima, Japan. The proximate cause of the disaster was the 2011 Tōhoku earthquake and tsunami, which occurred on the afternoon of 11 March 2011 and ...
that followed the earthquake and tsunami on 11 March 2011. The affected reactors were adjacent to one another and accident management was made much more difficult because of the number of simultaneous hazards concentrated in a small area. Failure of emergency power following the tsunami resulted in loss of coolant from each reactor, hydrogen explosions damaging the reactor buildings, and water draining from open-air
spent fuel pool Spent fuel pools (SFP) are storage pools (or "ponds" in the United Kingdom) for spent fuel from nuclear reactors. They are typically 40 or more feet (12 m) deep, with the bottom 14 feet (4.3 m) equipped with storage racks designed to hold f ...
s. Plant workers were put in the position of trying to cope simultaneously with core meltdowns at three reactors and exposed fuel pools at three units. Automated cooling systems were installed within 3 months from the accident. A fabric cover was built to protect the buildings from storms and heavy rainfall. New detectors were installed at the plant to track emissions of
xenon Xenon is a chemical element with the symbol Xe and atomic number 54. It is a dense, colorless, odorless noble gas found in Earth's atmosphere in trace amounts. Although generally unreactive, it can undergo a few chemical reactions such as the ...
gas. Filters were installed to reduce contaminants from escaping the area of the plant into the area or atmosphere. Cement has been laid near to the seabed to control contaminants from accidentally entering the ocean. Michio Aoyama, a scientist at Fukushima University's Institute of Environmental Radioactivity, estimated that the meltdowns and explosions released 18,000
terabecquerel The becquerel (; symbol: Bq) is the unit of radioactivity in the International System of Units (SI). One becquerel is defined as the activity of a quantity of radioactive material in which one nucleus decays per second. For applications relatin ...
(TBq) of caesium 137 (equivalent to roughly ), mostly into the Pacific Ocean. He also estimated that two years after the accident, the stricken plant was still releasing 30
gigabecquerel The becquerel (; symbol: Bq) is the unit of Radioactive decay, radioactivity in the International System of Units (SI). One becquerel is defined as the activity (radioactivity), activity of a quantity of radioactive material in which one atomic n ...
(30 GBq, or approximately 0.8
curie In computing, a CURIE (or ''Compact URI'') defines a generic, abbreviated syntax for expressing Uniform Resource Identifiers (URIs). It is an abbreviated URI expressed in a compact syntax, and may be found in both XML and non-XML grammars. A CURIE ...
equivalent to roughly ) of caesium 137 and the same amount (in terms of activity, not in terms of mass - the mass of amounts to roughly ) of
strontium 90 Strontium-90 () is a radioactive isotope of strontium produced by nuclear fission, with a half-life of 28.8 years. It undergoes β− decay into yttrium-90, with a decay energy of 0.546 MeV. Strontium-90 has applications in medicine and ...
into the ocean daily. For comparison, the
LD50 In toxicology, the median lethal dose, LD50 (abbreviation for "lethal dose, 50%"), LC50 (lethal concentration, 50%) or LCt50 is a toxic unit that measures the lethal dose of a toxin, radiation, or pathogen. The value of LD50 for a substance is the ...
of Caesium-137 in mice (through acute radiation syndrome) has been reported at 245 μg/kg body weight whereas experiments in the 1970s yielded a lethal dose in dogs of 44 μg/kg body weight. In a adult human, this would imply doses of and respectively. In September 2013, it was reported that the level of strontium-90 detected in a drainage ditch located near a water storage tank from which around 300 tons of water was found to have leaked was believed to have exceeded the threshold set by the government.The Mainichi Shimbun (13 September 2013
Toxic water has leaked into Pacific Ocean: TEPCO
Efforts to control the flow of contaminated water have included trying to isolate the plant behind a 30-meter-deep, 1.5-kilometer-long "ice wall" of frozen soil, which has had limited success.
Decommissioning Decommissioning is a general term for a formal process to remove something from an active status, and may refer to: Infrastructure * Decommissioned offshore * Decommissioned highway * Greenfield status of former industrial sites * Nuclear decommi ...
the plant is estimated to cost tens of billions of dollars and last 30–40 years.Fukushima radiation levels 18 times higher than previously thought
The Guardian ''The Guardian'' is a British daily newspaper. It was founded in 1821 as ''The Manchester Guardian'', and changed its name in 1959. Along with its sister papers ''The Observer'' and ''The Guardian Weekly'', ''The Guardian'' is part of the Gu ...
1 September 2013
While radioactive particles were found to have contaminated rice harvested near Fukushima City in the autumn of 2011, fears of contamination in the soil have receded as government measures to protect the food supply have appeared to be successful. Studies have shown that soil contamination in most areas of Fukushima was not serious. In 2018, Dr. Aoyama of Fukushima University released a report saying that contaminated water was still flowing into the Pacific Ocean, but at a greatly diminished rate of 2 GBq per day.Note: this probably means two billion disintegrations per day, and is thus 23 kBq (disintegrations per second) over the whole daily effluent volume of about 200 tons per day.


Overview

At the time of the initial event, 50
TEPCO , also known as or TEPCO, is a Japanese electric utility holding company servicing Japan's Kantō region, Yamanashi Prefecture, and the eastern portion of Shizuoka Prefecture. This area includes Tokyo. Its headquarters are located in Uchisaiw ...
employees remained onsite in the immediate aftermath to work to stabilize the plant and begin cleanup. Initially, TEPCO did not put forward a strategy to regain control of the situation in the reactors. Helmut Hirsch, a German physicist and nuclear expert, said "they are improvising with tools that were not intended for this type of situation". On 17 April 2011, however, TEPCO appeared to put forward the broad basis of a plan that included: (1) reaching "cold shutdown in about six to nine months;" (2) "restoring stable cooling to the reactors and spent fuel pools in about three months;" (3) putting "special covers" on Units 1, 3, and 4 starting in June; (4) installing "additional storage containers for the radioactive water that has been pooling in the turbine basements and outside trenches;"TEPCO Announces a "Roadmap to restoration" at Fukushima Dai-1 - IEEE Spectrum
Spectrum.ieee.org. Retrieved on 30 April 2011.
(5) using radio-controlled equipment to clean up the site; and (6) using
silt Silt is granular material of a size between sand and clay and composed mostly of broken grains of quartz. Silt may occur as a soil (often mixed with sand or clay) or as sediment mixed in suspension with water. Silt usually has a floury feel when ...
fences to limit ocean contamination. Previously, TEPCO publicly committed to installing new emergency generators 20 m above sea level, twice the height of the generators destroyed by the 11 March tsunami. Toshiba and Hitachi had both proposed plans for shuttering the facility.NTI: Global Security Newswire – Japan plant emits more radiation after cooling lapse
Global Security Newswire (14 April 2011). Retrieved on 30 April 2011.
"Cold shutdown" was accomplished on 11 December 2011. From that point active cooling was not needed anymore, but water injection was still required due to large water leaks. Long-term plans for Units 5 and 6 have not been announced, "but they too may need to be decommissioned".Tabuchi, Hirok

NY Times, 14 April 2011.
On 5 May 2011, workers were able to enter reactor buildings for the first time since the accident.Workers enter reactor building
NHK, 5 May 2011
The workers began to install air filtration systems to clean air of radioactive materials to allow additional workers to install water cooling systems. In 2017, TEPCO announced that remote-controlled robots sent into the destroyed Unit 3 reactor buildings had finally found the reactor's melted uranium fuel, which had burned through the floor of the reactor vessel and settled in clumps on the concrete floor below.


Scope of cleanup

Japanese reactor maker Toshiba said it could decommission the earthquake-damaged Fukushima nuclear power plant in about 10 years, a third quicker than the American Three Mile Island plant. As a comparison, at Three Mile Island the vessel of the partially melted core was first opened 11 years after the accident, with cleanup activities taking several more years. TEPCO announced it restored the automated cooling systems in the damaged reactors in about three months, and had the reactors put into cold shutdown status in six months. First estimates included costs as high as (), as cited by the Japanese Prime Minister at the time,
Yoshihiko Noda is a Japanese politician who was Prime Minister of Japan from 2011 to 2012. He was a member of the Democratic Party, and a member of the House of Representatives (lower house) in the Diet (national legislature). He was named to succeed Naoto K ...
(野田 佳彦). This estimate was made before the scope of the problem was known, however. It seems that the contamination was less than feared. No strontium is detectable in the soil, and though the crops of the year of the disaster were contaminated, the crops produced by the area now are safe for human consumption. In 2016, Japan's
Ministry of Economy, Trade and Industry The or METI, is a ministry of the Government of Japan. It was created by the 2001 Central Government Reform when the Ministry of International Trade and Industry (MITI) merged with agencies from other ministries related to economic activities, ...
estimated the total cost of dealing with the Fukushima disaster at (), almost twice the previous estimate of (). A rise in compensation for victims of the disaster from () to () was expected, with decontamination costs estimated to rise from () to (), costs for interim storage of radioactive material to increase from () to (), and costs of decommissioning reactors to increase from () to ().


Working conditions at the plant

There has been concern that the plant would be dangerous for workers. Two workers suffered skin burns from radiation, but no serious injuries or fatalities have been documented to have been caused by radiation at Fukushima Dai-ichi.


Workers in dorms exposed to radiation

Two shelters for people working at the Fukushima site were not listed as part of the radiation management zones although radiation levels in the shelters exceeded the legal limits. The consequence was, that the workers did not get paid the extra "danger allowance" that was paid to workers in these "radiation management zones". The shelters were constructed by
Toshiba Corporation , commonly known as Toshiba and stylized as TOSHIBA, is a Japanese multinational conglomerate corporation headquartered in Minato, Tokyo, Japan. Its diversified products and services include power, industrial and social infrastructure system ...
and the
Kajima Corporation is one of the oldest and largest construction companies in Japan. Founded in 1840, the company has its headquarters in Motoakasaka, Minato, Tokyo. The company is known for its DIB-200 proposal. The company stock is traded on four leading Jap ...
at a place some 2 kilometers west of the damaged reactors, just outside the plant compound, but quite near to the reactors 1 to 4. The shelters were built after the shelters at the plant compound became overcrowded. At 7 October 2011, radiation levels were between 2 and 16 microsieverts per hour in the Toshiba building, and 2 to 8.5 in the Kajima dorm. The Industrial Safety and Health Law on the prevention of health damage through ionizing radiation had set the limit for accumulated radiation dosage in radiation management zones at 1.3 millisieverts over three months, so the maximum level is 2.6 microsieverts/hour. In both dorms, the radiation levels were higher. These doses are, however, well below the level to affect human health. According to the law, the "business operator" is responsible for "managing radiation dosage and the prevention of contamination", Toshiba and Kajima said that TEPCO was responsible, but a TEPCO official made the comment: "From the perspective of protecting workers from radiation, the business operators (that constructed the shelters) are managing radiation dosage and the prevention of contamination" in this way suggesting that Toshiba and Kajima had to take the care for the zone management.


Preventing hydrogen explosions

On 26 September 2011, after the discovery of hydrogen in a pipe leading to the containment vessel of reactor no.1, NISA instructed TEPCO to check whether hydrogen was building up in reactor no. 2 and 3 as well. TEPCO announced that measurements of hydrogen would be done in reactor no. 1, before any nitrogen was injected to prevent explosions. When hydrogen would be detected at the other reactors, nitrogen injections would follow. After the discovery of hydrogen concentrations between 61 and 63 percent in pipes of the containment of reactor no. 1, nitrogen injections were started on 8 October. On 10 October, TEPCO announced that the concentrations were, at that moment, low enough to prevent explosions, and even if the concentration would rise again, it would not exceed 4 percent, the lowest level that would pose the risk of an explosion. On the evening of 9 October, two holes were drilled into the pipe to install a filter for radioactive substances inside the containment vessel; this was 2 weeks behind the schedule TEPCO had set for itself. This filter should be in operation as soon as possible.


Investigations inside the reactors

On 19 January 2012, the interior of the primary containment vessel of reactor 2 was inspected with an industrial endoscope. This device, 8.5 millimeters in diameter, is equipped with a 360 degrees-view camera and a thermometer to measure the temperature at this spot and the cooling water inside, in an attempt to calibrate the existing temperature measurements that could have an error margin of 20 degrees. The device was brought in by a hole at 2.5 meter above the floor where the vessel is located. The whole procedure lasted 70 minutes. The photos showed parts of the walls and pipes inside the containment vessel. But they were unclear and blurred, most likely due to water vapors and the radiation inside. According to TEPCO the photos showed no serious damage. The temperature measured inside was 44.7 degrees Celsius, and did not differ much from the 42.6 degrees measured outside the vessel.


Inspections of the suppression chambers reactor no. 2 and 3

On 14 March 2012, for the first time after the accidents, six workers were sent into the basements of reactor no. 2 and 3, to examine the suppression chambers. Behind the door of suppression chamber in the no.2 building, 160 millisieverts/hour was measured. The door to the suppression chamber in the no. 3 reactor building was damaged and could not be opened. In front of this door, the radiation level measurement was 75 millisieverts/hour. For reactors to be decommissioned, access to the suppression chambers is vital for conducting repairs to the containment structures. According to TEPCO, this work should be done with robots, because these places with high levels of radiation could be hostile to humans. TEPCO released some video footage of the work at the suppression chambers of the No. 2 and 3 reactors.NHK-world (15 March 201
Radiation high near suppression chambers
/ref>JAIF (15 March 201
Earthquake report 374: Radiation high near suppression chambers
/ref> On 26 and 27 March 2012, the inside of the containment vessel of reactor 2 was inspected with a 20 meter long endoscope. With this, a dosimeter was brought into the vessel to measure the radiation levels inside. At the bottom of the primary containment structure, 60 centimeters of water was found, instead of the 3 meters expected at that place. The radiation level measured was 72.9 sieverts per hour. Because of this, the endoscope could only function a few hours at this place. For reactors number 1 and 3, no endoscopic survey was planned at that time, because the actual radiation levels at these places were too high for humans.


Management of contaminated water

Continued cooling of the melted reactor cores is required in order to remove excess heat. Due to damage to the integrity of the reactor vessels, radioactive water accumulates inside the reactor and turbine buildings. To decontaminate the contaminated water, TEPCO installed radioactive water treatment systems. The Japanese government had initially requested the assistance of the
Russia Russia (, , ), or the Russian Federation, is a List of transcontinental countries, transcontinental country spanning Eastern Europe and North Asia, Northern Asia. It is the List of countries and dependencies by area, largest country in the ...
n floating water decontamination plant ''
Landysh ''Landysh'' (russian: Ландыш, lit=Lily of the Valley; known as ''Suzuran'' in Japan) is a floating facility for processing contaminated water produced when decommissioning nuclear submarines. It was built in Russia with funds from Japan as p ...
'' to process the radioactive water from the damaged reactors, but negotiations with the Russian government were an extremely slow process and it is unclear if the plant was ever sent to Fukushima. ''Landysh'' was built by Russia with funding from Japan to process liquid wastes produced during the
decommissioning Decommissioning is a general term for a formal process to remove something from an active status, and may refer to: Infrastructure * Decommissioned offshore * Decommissioned highway * Greenfield status of former industrial sites * Nuclear decommi ...
of
nuclear submarines A nuclear submarine is a submarine powered by a nuclear reactor, but not necessarily nuclear-armed. Nuclear submarines have considerable performance advantages over "conventional" (typically diesel-electric) submarines. Nuclear propulsion, ...
. As of early September 2011, the operating rate of the filtering system exceeded the target of 90 percent for the first time. 85,000 tons of water were decontaminated by September 11, with over 100,000 tons of waste water remaining to be treated at the time. The nuclear waste generated by the filters had already filled almost 70 percent of the 800 cubic meters of storage space available at the time. TEPCO had to figure out how to cool the reactors with less than 15 tons of water per day in order to reduce the growth of waste water and nuclear waste to more manageable levels.


Installation of circulating water cooling system

In order to remove decay heat of the severe damaged cores of Unit 1–3, TEPCO injected cooling water into the reactors. As the reactors appear to have holes around the bottom, the water dissolved the water-soluble fission products, which then accumulated in the basement of the turbine building (the adjacent diagram #2) through any leaks from the water-injected reactor buildings (#1). Since the accumulated radioactive water was a risk, TEPCO tried to transfer it. As the accumulated water in the basement (see the tunnel below diagram #2) of the turbine building of Units 2 and 3 was radioactive, TEPCO needed to remove it. They had initially planned to pump the water to the condenser (the large black vessel in diagram #1)."Fukushima Daiichi Nuclear Accident Update (27 March, 03:00 UTC)". International Atomic Energy Agency. 27 March 2011. Retrieved 27 March 2011., records(2011) pp.249-250 TEPCO had to abandon that plan after discovering that the condensers on both units were already full of water. Pumps capable of processing 10–25 tons of water per hour were used to transfer condenser water into other storage tanks, freeing up condenser storage for the water in the basements. Since both the storage tanks and the condensers were nearly full, TEPCO also considered using floating tankers ships as a temporary storage location for the radioactive water. Regardless of the availability of offshore storage for radioactive-contaminated water, TEPCO decided to discharge 11,500 tons of its least contaminated water (which was still approximately 100 times the legal limit for radioactivity) into the sea on April 5 in order to free up storage space.asahi.com(朝日新聞社):Radiation fallout from Fukushima plant will take "months" to stop - English
Asahi.com (4 April 2011). Retrieved on 30 April 2011.
At the same time, on 5 April, TEPCO began pumping water from the condensers of units 1–3 to their respective condensation storage tanks to free room for the trench water (see below).


Removal of accumulated water in seawater piping trench

The Fukushima Daiichi NPS has several seawater piping trenches that were originally designed to house pipes and cables running from the Unit 2–4 turbine buildings to their seaside, which doesn't directly connect to the sea. Inside the trench, radioactive contaminated water has been accumulating since the accident. Due to the risk of soil or ocean contamination from these trenches, TEPCO has been trying to remove the accumulated water in the trenches by pumping it back into the turbine buildings, as well as backfilling the trenches to reduce or prevent further incursion of contaminated water.


Groundwater contamination

On 5 July 2013, TEPCO found 9 kBq/L of 134Cs and 18 kBq/L of 137Cs in a sample taken from a monitoring well close to the coastline. Compared with samples taken three days earlier, the levels were 90 times higher. The cause was unknown. The monitoring well is situated close to another monitoring well that had previously leaked radioactive water into the sea in April 2011. A sample of groundwater from another well situated about 100 meters south of the first well showed that the radioactivity had risen by 18 times over the course of 4 days, with 1.7 kBq/L of strontium and other radioactive substances. A day later the readings in the first well were 11 kBq/L of 134Cs and 22 kBq/L of 137Cs, 111 times and 105 times greater than the samples of 5 July. TEPCO did not know the reasons for the higher readings, but the monitoring was to be intensified. More than a month after the groundwater contamination was discovered, TEPCO started to contain the radioactive groundwater. They assumed that the radioactivity had escaped early in the beginning of the disaster in 2011, but NRA experts had serious doubts about their assumption. According to them, other sources could not be excluded. Numerous pipes were running everywhere on the reactor grounds to cool the reactors and decontaminate the water used, and leaks could be anywhere. TEPCO's solution resulted in redirection of the groundwater flows, which could have spread the radioactive contamination further. Besides that, TEPCO had plans for pumping groundwater. At that time the turbine buildings of units 2 and 3 contained 5000 and 6000 cubic meters of radioactive water. With wells in contact with the turbine buildings, this could spread the radioactivity into the ground. The NRA announced that it would form a task force to find the leaks and to block the flow of the groundwater to the coastline, because the NRA suspected that the groundwater was leaking into the sea.


Timeline of contaminated water treatment

; 2011 :; On March 27 :: TEPCO announced that radioactive water had accumulated in the basement of the Unit 2 turbine building.Japanese nuclear firm admits error on radiation reading
''The Guardian'', 27 March 2011.
:; On March 28 :: The
Japanese Nuclear Safety Commission Japan's was a commission established within the Cabinet of Japan as an independent agency to play the main role in nuclear safety administration. Commissioners are appointed by the Prime Minister of Japan on Diet approval. The commission has s ...
advised TEPCO to take all possible measures to avoid the accumulated water in the Unit 2 turbine building leaking into the ground and the sea.(hereinafter called "the JNSC advice") :; On April 2 :: TEPCO announced the outflow of fluid containing radioactive materials to the ocean from areas near the intake channel of Unit 2. The fluid source was a 20 cm crack on the concrete lateral of the pit that appeared to have been created by the earthquake. TEPCO attempted to inject fresh concrete, polymeric water absorbent, sawdust, and shredded newspapers into the crack; this approach failed to slow the leak. After an investigation of the water flow, TEPCO began to inject
sodium silicate Sodium silicate is a generic name for chemical compounds with the formula or ·, such as sodium metasilicate , sodium orthosilicate , and sodium pyrosilicate . The anions are often polymeric. These compounds are generally colorless transparent ...
on April 5th, and the outflow was stopped on April 6th. The total amount and radioactivity of the outflow from the crack was estimated to be approximately 520 m3 and approximately 4.7 PBq respectively. :; On April 17 :: TEPCO announced the Roadmap towards Restoration from the Accident at Fukushima Daiichi Nuclear Power Station. :; On April 27 :: In order to prevent the outflow of the highly radioactive water at the turbine building of Unit 2, the water was transferred to the Centralized Radiation Waste Treatment Facility since April 19th. TEPCO planned to install facilities for processing the stored water and reusing treated water to inject it into the reactors. :; On May 11 :: TEPCO investigated possible leakage of radioactive water to the outside from around the intake canal of Unit 3 in response to the employees' report of water flowing into the pit via power cable pipe lines. :; On May 23 ::
Nuclear and Industrial Safety Agency The was a Japanese nuclear regulatory and oversight branch of the Agency for Natural Resources and Energy under the Ministry of Economy, Trade and Industry (METI). It was created in 2001 during the 2001 Central Government Reform. Especially aft ...
began to use the term "Contaminated Water" as the water with high concentration of radioactive materials. :; On June 17 :: TEPCO began the operation of the cesium adsorption apparatus (Kurion) and the decontamination apparatus (AREVA). :; On August 17 :: TEPCO began the (test) operation of SARRY, which is the second cesium adsorption apparatus (TOSHIBA). :; On August 28 :: 2 TEPCO workers at the plant were exposed to radiation by mistake while they were replacing parts of the contaminated water processing system. The next Wednesday 31 August two other workers were sprayed with highly contaminated water when the water splashed from a container with a leaking valve that did not close. It was found that they were exposed to 0.16 and .14 millisieverts. The last man wore a raincoat. No immediate symptoms were found. :; On December 21 :: TEPCO announced Mid-and-long-Term Roadmap towards the Decommissioning of Fukushima Daiichi Nuclear Power Units 1-4. ; 2012 :; On April 5 :: A leaking pipe was found at 1.00 AM. The leakage stopped an hour after the valves were closed. 12,000 liters water with high levels of radioactive strontium were lost, according to TEPCO much of this water escaped through a nearby sewer system into the ocean. Investigations should reveal how much water was lost into the ocean, and how the joint could fail. A similar leakage in at the same facility happened on 26 March 2012. :; On September 19 ::
Nuclear Regulation Authority The is an administrative body of the Cabinet of Japan established to ensure nuclear safety in Japan as part of the Ministry of the Environment. Established on September 19, 2012, its first head was Shunichi Tanaka. Background The NRA was forme ...
(NRA) was established. ; 2013 (The year to the social problem) :; On March 30 :: TEPCO began the operation of ALPS, which is the multi-nuclide removal equipment. :; On July 22 :: With announcing the situation on seawater and groundwater, TEPCO admitted that contaminated groundwater had been leaking into the ocean since March 2011. :; On July 27 :: TEPCO announced that extremely high levels of tritium and cesium were found in a pit containing about 5000 cubic meters water on the sea side of the Unit 2 reactor building. 8.7
MBq ''MBQ'' is an original English-language manga created by Tokyopop's Rising Stars of Manga second-place winner Felipe Smith. ''MBQ'' is an expansion of his second-place winning entry in the third Rising Stars competition. It is the story of a you ...
/liter of tritium and 2.35 GBq/liter of cesium was measured. The NRA was concerned that leaks from the pit could release high tritium levels into the sea and that there was still water flowing from the reactor into the turbine building and into the pit. TEPCO believed that this pollution was there from the first days in 2011, and had stayed there. Nevertheless, TEPCO would control the site for leaks, and seal the soil around the pit. :; On May 30 :: The Government of Japan decided the policy to prevent the groundwater flowing in the reactor buildings. A frozen soil wall (Land-side Impermeable Wall) was scheduled for introduction to block the flow of groundwater and prevent its mixing with contaminated water. :; On August 19 :: Contaminated water leakage from a flange type tank was found in the H4 area. The incident was finally evaluated by the NRA as a provisional rating Level 3 on the eight-level
INES Ines or INES may refer to: People * Ines (name), a feminine given name, also written as Inés or Inês * Saint Ines or Agnes (), Roman virgin–martyr * Eda-Ines Etti (stage name: ''Ines''; born 1981), Estonian singer Places * Doña Ines, a vo ...
. In response to this incident, NRA recommended that TEPCO should replace the flange type tank, which is prone to leak water, with a welded type tank. :; On August 28 :: A subcontractor employee was contaminated on his face, head and chest while transferring water from the damaged tank. After decontamination, 5,000 cpm were still measured on his head; the readings from prior to decontamination were not released. The man was released, but ordered to have a whole-body radiation count later. :; On September 2 :: It was reported that radiation near another tank was measured at 1.8 Sv/h, 18 times higher than previously thought. TEPCO had initially recorded radiation at about 100 mSv/h, but later admitted that that was because the equipment they were using could only read measurements up to that level. The latest reading came from a more advanced device capable of measuring higher levels. The buildup of water at the site is close to becoming unmanageable and experts say that TEPCO will soon be left with no choice but to release the water into the ocean or evaporate it. :; On September 3 :: The Nuclear Emergency Response Headquarters published "the Government’s Decision on Addressing the Contaminated Water Issue at TEPCO’s Fukushima Daiichi NPS". :; On September 9 :: TEPCO started cleaning the draining ditch at the north side of the leaking tank one day before Tokyo was selected as host of the 2020 Olympic Games. Radiation monitoring data were masked after that day for some time. :; On September 12 :: Contaminated water leakage from storage tanks was found in the H4 area.


Suggestions of dumping cooling water

In September 2019, the contaminated cooling water had almost reached storage capacity. Japan's environment minister Yoshiaki Harada suggested, that there was only one recourse: "release it into the ocean and dilute it... there are no other options." A day later, Yoshiaki Harada was taken out of his function, after protests. His successor Shinjiro Koizumi apologized to the fishermen in Fukushima at a meeting in Iwaki City. The new minister promised to take a strong few on the facts, and to push for reconstruction. In 2020, the storage of contaminated water reached over a million tons, stored in large containers at the grounds of the plant. In 2022, the storage capacity could be exceeded. Therefore, a proposal was made in spring 2020 to start discharging the cooling water into the ocean. Hiroshi Kishi, the president of JF Zengyoren, the headman of many fishermen cooperations, strongly opposed this proposal at a meeting with Japanese government representatives. According to Kishi, any release of cooling water could prompt other countries to reinforce restrictions on imports of Japanese fishery products, reversing a recent trend toward easing.


Radioactive waste

Cooling the reactors with recirculated and decontaminated water from the basements proved to be a success, but as a consequence, this
radioactive waste Radioactive waste is a type of hazardous waste that contains radioactive material. Radioactive waste is a result of many activities, including nuclear medicine, nuclear research, nuclear power generation, rare-earth mining, and nuclear weapons r ...
was piling up in the temporary storage facility at the plant. TEPCO decided in the first week of October to use the "Sally" decontamination system built by Toshiba Corporation and keep the Kurion/Areva system as backup. On 27 September, after three months operation, some 4,700 drums with
radioactive waste Radioactive waste is a type of hazardous waste that contains radioactive material. Radioactive waste is a result of many activities, including nuclear medicine, nuclear research, nuclear power generation, rare-earth mining, and nuclear weapons r ...
had piled up at the plant. The Kurion and Sally systems both utilized
zeolite Zeolites are microporous, crystalline aluminosilicate materials commonly used as commercial adsorbents and catalysts. They mainly consist of silicon, aluminium, oxygen, and have the general formula ・y where is either a metal ion or H+. These pos ...
s to concentrate cesium. After the zeolite was saturated, the vessels with the zeolite were turned into nuclear waste. By now, 210 Kurion-made vessels with a total of 307 cubic meters, each vessel measuring 0.9 meters in diameter and 2.3 meters in height had accumulated at the plant. The Areva-filters used sand to absorb radioactive materials and chemicals were used to reactivate the filters. In this way, 581 cubic meters of highly contaminated sludge were produced. According to Professor Akio Koyama of the Kyoto University Research Reactor Institute, the density of high-level decontaminated water was believed to contain 10 gigabecquerel per liter, but if this is condensed to polluted sludge and zeolites, this density could increase 10,000 fold. These densities could not be dealt using conventional systems.


Spent fuel pools

On August 16, 2011, TEPCO announced the installation of desalination equipment in the spent fuel pools of reactor 2, 3, and 4. These pools had been cooled with seawater for some time, and TEPCO feared the salt would corrode the stainless steel pipes and pool wall liners. The Unit 4 spent fuel pool was the first to have the equipment installed, the spent fuel pools of reactor 2 and 3 came next. TEPCO expected to achieve removal of 96% of the salt in the spent fuel pools within two months.


Unit 4 spent fuel removal

On December 22, 2014, TEPCO crews completed the removal of all fuel assemblies from the spent fuel pool of reactor 4. 1331 spent fuel assemblies were moved to the ground-level common spent fuel pool, and 204 unused fuel assemblies were moved to the spent fuel pool of reactor 6 (Unit 4 was out of service for refueling at the time of the 2011 accident, so the spent fuel pool contained a number of unused new fuel assemblies).


Debris removal

On 10 April 2011, TEPCO began using remote-controlled, unmanned heavy equipment to remove debris from around reactors 1–4. The debris and rubble, caused by hydrogen explosions at reactors 1 and 3, was impeding recovery operations both by being in the way and emitting high radioactivity. The debris will be placed into containers and kept at the plant.


Proposed building protections

Because the
monsoon A monsoon () is traditionally a seasonal reversing wind accompanied by corresponding changes in precipitation but is now used to describe seasonal changes in atmospheric circulation and precipitation associated with annual latitudinal oscil ...
season begins in June in Japan, it became urgent to protect the damaged reactor buildings from
storm A storm is any disturbed state of the natural environment or the atmosphere An atmosphere () is a layer of gas or layers of gases that envelop a planet, and is held in place by the gravity of the planetary body. A planet retains an atmos ...
s,
typhoon A typhoon is a mature tropical cyclone that develops between 180° and 100°E in the Northern Hemisphere. This region is referred to as the Northwestern Pacific Basin, and is the most active tropical cyclone basin on Earth, accounting for a ...
s, and heavy rainfall. As a short-term solution, TEPCO envisaged to apply a light cover on the remaining structures above the damaged reactors. As of mid-June, TEPCO released its plan to use automated cranes to move structures into place over the reactor. This strategy is an attempt to keep as many people away from the reactors as possible, while still covering the damaged reactors.


Proposed sarcophagus

On 18 March 2011, Reuters reported that Hidehiko Nishiyama, Japan's nuclear agency spokesman when asked about burying the reactors in sand and concrete, said: "That solution is in the back of our minds, but we are focused on cooling the reactors down." Considered a last-ditch effort since it would not provide cooling, such a plan would require massive reinforcement under the floor, as for the
Chernobyl Nuclear Power Plant sarcophagus , image = Chernobylreactor 1.jpg , caption = The sarcophagus in 2006. The tall chimney is an original part of the reactor building. , location = Covering Reactor 4 of the Chernobyl Nuclear Power Plant, within the C ...
.


Scrapping reactor Daiichi 1, 2, 3, 4

On 7 September 2011, TEPCO president Toshio Nishizawa said that the 4 damaged reactors will be scrapped. This announcement came at a session of the Fukushima Prefectural Assembly, which was investigating the accident at the plant. Whether the six other remaining reactors (Daiichi 5, 6, Daini 1, 2, 3, 4) should be abolished too would be decided based on the opinions of local municipalities. On 28 October 2011, the Japanese Atomic Energy Commission presented a timetable in a draft report, titled ''“how to scrap the Fukushima reactors”''. Within 10 years, a start should be made with the retrieval of the melted fuel within the reactors. First, the containment vessels of reactors 1, 2 and 3 should be repaired, then all should be filled with water to prevent radiation releases. Decommissioning would take more than 30 years, because the pressure vessels of the reactor vessels are damaged also. After the accident at Three Mile Island in 1979, some 70 percent of the fuel rods had melted. There, the retrieval of the fuel was started in 1985, and completed in 1990. The work at Fukushima was expected to take significantly longer because of the far greater damage and the fact that 4 reactors would need to be decommissioned all at the same time. After discussions were started in August 2011, on 9 November, a panel of experts of Japan's Atomic Energy Commission completed a schedule for scrapping the damaged reactors. The panel's conclusions were: * The scrapping will take 30 years or longer. * First, the containment vessels needed to be repaired, then filled with water to block radiation. * The reactors should be in a state of stable cold shutdown. * Three years later, a start would be made to take all spent fuel from the 4 damaged reactors to a pool within the compound. * Within 10 years, the removal of the melted fuel inside the reactors could begin. This scheme was partly based on the experience gained from the 1979 Three Mile Island accident. In Fukushima, however, with three meltdowns at one site, the damage was much more extensive. It could take 30 years or more to remove the nuclear fuel, dismantle the reactors, and remove all the buildings. Research institutions all over the world were asked to participate in the construction of a research site to examine the removal of fuel and other nuclear wastes. The official publication of the report was planned at the end of 2011.NHK-world (9 November 2011
Commission releases report on scrapping N-plant


Protection systems installed

Since the disaster, TEPCO has installed sensors, a fabric cover over the reactors and additional filters to reduce the emission of contaminants.


Sensors for xenon and temperature changes to detect critical reactions

After the detection of radioactive xenon gas in the containment vessel of the No. 2 reactor on 1 and 2 November 2011 TEPCO was not able to determine whether this was a sustained fission process or only spontaneous fission. Therefore, TEPCO installed detection devices for radioactive xenon to single out any occurrence of nuclear criticality. Next to this TEPCO installed temperature sensors to control temperature changes in the reactors, another indicator of possible critical fission reactions.JAIF (10 November 2011
Earthquake-report 261
/ref>


New filters

On 20 September the Japanese government and TEPCO announced the installation of new filters to reduce the amount of radioactive substances released into the air. In the last week of September 2011 these filters were to be installed at reactor 1, 2 and 3. Gases out of the reactors would be decontaminated before they would be released into the air. Mid October the construction of the polyester shield over the No.1 reactor should be completed. In the first half of September the amount of radioactive substances released from the plant was about 200 megabecquerel per hour, according to TEPCO, that was about one-four millionths of the level of the initial stages of the accident in March.


Fabric cover over Unit 1

An effort has been undertaken to fit the three damaged reactor buildings with fabric covers and filters to limit radioactive contamination release. On 6 April 2011, sources told Kyodo News that a major construction firm was studying the idea, and that construction wouldn't "start until June". The plan has been criticized for potential only having "limited effects in blocking the release of radioactive substances into the environment".
English.kyodonews.jp. Retrieved on 30 April 2011.
On 14 May, TEPCO announced that it had begun to clear debris to create a space to install a cover over the building of reactor 1. In June, a large crane was erected near Reactor 1 to begin construction of the fabric cover. From mid August to mid September 2011, a rectangular steel frame entirely surrounding the reactor building was constructed. Starting September 9th, the crane was used to attach polyester panels to the frame. On 20 September 2011, TEPCO announced that within three weeks they hoped to complete the construction of the polyester shield over the No.1 reactor. By that time the steel frame for the fabric cover had been completed. By 7 October, the roof of the structure was being added. On 9 October, the walls of the cover appeared to be placed, and by 13 October the roof had been completed.JAIF (20 September 2011
Earthquake-report 211: A new plan set to reduce radiation emissions


Metal cover over Unit 3

In June 2016, preparation work began to install a metal cover over the Unit 3 reactor building. In conjunction with this, a crane is to be installed to assist with the removal of the fuel rods from the storage pool. After inspection and cleaning, the removed fuel is expected to be stored in the site's communal storage facility. By February 2018 the dome-shaped roof had been completed in preparation of the removal of the fuel rods.


Cleanup of neighboring areas

Significant efforts are being taken to clean up radioactive material that escaped the plant. This effort combines washing down buildings and scraping away topsoil. It has been hampered by the volume of material to be removed and the lack of adequate storage facilities. There is also a concern that washing surfaces will merely move the radioactive material without eliminating it. After an earlier decontamination plan only to clean all areas with radiation levels above 5 millisievert per year, had raised protests, the Japanese government revealed, on 10 October 2011, in a meeting with experts, a revised decontamination plan. This plan included: * all areas with radiation levels above 1 millisievert per year would be cleaned. * no-entry zones and evacuation zones designated by the government would be the responsibility of the government. * the rest of the areas would be cleaned by local authorities. * in areas with radiation levels above 20 millisievert per year, decontamination would be done step by step. * within two years, radiation levels between 5 and 20 millisieverts should be cut down to 60%. * the Japanese government would help local authorities with disposing the enormous amount of
radioactive waste Radioactive waste is a type of hazardous waste that contains radioactive material. Radioactive waste is a result of many activities, including nuclear medicine, nuclear research, nuclear power generation, rare-earth mining, and nuclear weapons r ...
. On 19 December 2011, the Japanese Ministry of Environment published more details about these plans for decontamination: the work would be subsidized in 102 villages and towns. Opposition against the plan came from cattle farmers in the prefecture Iwate and the tourist industry in the city of
Aizuwakamatsu is a city in Fukushima Prefecture, Japan. , the city had an estimated population of 118,159 in 50,365 households, and a population density of 310 persons per km2. The total area of the city was . Geography Aizuwakamatsu is located in the west ...
, because of fears that cattle sales might drop or tourism would be hurt to the town, when the areas would be labeled to be contaminated. Areas with lower readings complained that their decontamination would not be funded. In a Reuters story from August 2013, it was noted " ny have given up hope of ever returning to live in the shadow of the Fukushima nuclear plant. A survey in June showed that a third of the former residents of Iitate, a lush village famed for its fresh produce before the disaster, never want to move back. Half of those said they would prefer to be compensated enough to move elsewhere in Japan to farm." In addition, despite being allowed to return home, some residents say the lack of an economy continues to make the area de facto unlivable. Compensation payments to those who have been evacuated are stopped when they are allowed to return home, but , decontamination of the area has progressed more slowly than expected. There have also been revelations of additional leaks (see above: storage tanks leaking contaminated water).


Cementing the seabed near the water intake

On 22 February 2012, TEPCO started cementing the seabed near the plant to prevent the spread of radioactive materials into the sea. Some 70000 square meters of seabed around the intake of cooling water would be covered with 60 centimeters thick cement. The work should be finished within 4 months time, and prevent the spread of contaminated mud and sand at that place for at least 50 years.


New definition of the no-entry zones introduced

On 18 December 2011, Fukushima Gov. Yuhei Sato and representatives of 11 other municipal governments near the plant were notified at a meeting at the city of Fukushima the three ministers in charge of handling the crises, Yokio Edano, minister of Economy, Trade and Industry, Goshi Hosono, nuclear disaster minister, and Tatsuo Hirano, minister in charge of reconstruction of the government plan to redesign the classification of the no-entry zones around the Fukushima nuclear plant. From 1 April 2012, a three level system would be introduced, by the Japanese government: ; no-entry zones, with an annual radiation exposure of 50 millisieverts or more : at these places habitation would be prohibited ; zones with annual radiation exposures between 20 and 50 millisievert : here former residents could return, but with restrictions ; zones with exposures of less than 20 millisievert per year : in these zones the residents would be allowed to return to their houses Decontamination efforts were planned in line with this newly designed order, to help the people to return to places where the radiation levels would be relatively low.


Costs of the cleanup operations

Mid December 2011, the local authorities in
Fukushima may refer to: Japan * Fukushima Prefecture, Japanese prefecture ** Fukushima, Fukushima, capital city of Fukushima Prefecture, Japan ***Fukushima University, national university in Japan *** Fukushima Station (Fukushima) in Fukushima, Fukushim ...
had spent already around 1.7 billion yen ($21 million) on the costs of decontamination works in the cities of
Fukushima may refer to: Japan * Fukushima Prefecture, Japanese prefecture ** Fukushima, Fukushima, capital city of Fukushima Prefecture, Japan ***Fukushima University, national university in Japan *** Fukushima Station (Fukushima) in Fukushima, Fukushim ...
and
Date Date or dates may refer to: *Date (fruit), the fruit of the date palm (''Phoenix dactylifera'') Social activity *Dating, a form of courtship involving social activity, with the aim of assessing a potential partner ** Group dating *Play date, a ...
and the village of Kawauchi. The total cleanup costs were estimated to be between 50.5 and 71 trillion yen ($470 to $660 billion). For the cleanup, only 184.3 billion yen was reserved in the September supplementary budget of prefecture Fukushima, and some funds in the central government's third supplementary budget of 2011. Whenever needed, the central government would be asked for extra funding. In 2016,
University of Oxford , mottoeng = The Lord is my light , established = , endowment = £6.1 billion (including colleges) (2019) , budget = £2.145 billion (2019–20) , chancellor ...
researcher and author Peter Wynn Kirby wrote that the government had allocated the equivalent of US$15 billion for the regional cleanup and described the josen (decontamination) process, with "provisional storage areas (kari-kari-okiba) ... ndmore secure, though still temporary, storage depots (kari-okiba)". Kirby opined the effort still would be better called "transcontamination" because it was moving the contaminated material around without long-term safe storage planned or executed. He also saw little progress on handling the more intense radiation waste of the destroyed power plant site itself; or on handling the larger issue of the national nuclear program's waste, particularly given the earthquake-risk of Japan relative to secure long-term storage.


Lessons learned to date

The Fukushima Daiichi nuclear disaster revealed the dangers of building multiple nuclear reactor units close to one another. This proximity triggered the parallel, chain-reaction accidents that led to hydrogen explosions blowing the roofs off reactor buildings and water evaporating from open-air
spent fuel pool Spent fuel pools (SFP) are storage pools (or "ponds" in the United Kingdom) for spent fuel from nuclear reactors. They are typically 40 or more feet (12 m) deep, with the bottom 14 feet (4.3 m) equipped with storage racks designed to hold f ...
s—a situation that was potentially more dangerous than the loss of reactor cooling itself. Because of the proximity 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".


See also

*
Tritiated water Tritiated water is a radioactive form of water in which the usual protium atoms are replaced with tritium. In its pure form it may be called tritium oxide (T2O or 3H2O) or super-heavy water. Pure T2O is corrosive due to self-radiolysis. Dilut ...
*
Human decontamination Human decontamination is the process of removing hazardous materials from the human body, including chemicals, radioactive substances, and infectious material. General principle People suspected of being contaminated are usually separated b ...


Notes


References


Sources

* ; Management of contaminated water * * * * *


External links


PM Information on contaminated water leakage at TEPCO's Fukushima Daiichi Nuclear Power Station
Prime Minister of Japan and His Cabinet

Ministry of Foreign Affairs In many countries, the Ministry of Foreign Affairs is the government department responsible for the state's diplomacy, bilateral, and multilateral relations affairs as well as for providing support for a country's citizens who are abroad. The entit ...

TEPCO News Releases
Tokyo Electric Power Company , also known as or TEPCO, is a Japanese electric utility holding company servicing Japan's Kantō region, Yamanashi Prefecture, and the eastern portion of Shizuoka Prefecture. This area includes Tokyo. Its headquarters are located in Uchisaiw ...

NRA, Japan
Nuclear Regulation Authority The is an administrative body of the Cabinet of Japan established to ensure nuclear safety in Japan as part of the Ministry of the Environment. Established on September 19, 2012, its first head was Shunichi Tanaka. Background The NRA was forme ...

NISA
Nuclear and Industrial Safety Agency The was a Japanese nuclear regulatory and oversight branch of the Agency for Natural Resources and Energy under the Ministry of Economy, Trade and Industry (METI). It was created in 2001 during the 2001 Central Government Reform. Especially aft ...
, former organization
Fukushima Diary
News site of a concerned Japanese man in Europe

* ttp://www.meti.go.jp/english/earthquake/nuclear/decommissioning/index.html Mid-and-Long-Term Roadmap towards the Decommissioning of TEPCO's Fukushima Daiichi Nuclear Power Station Units 1-4 {{2011 Tōhoku earthquake and tsunami Fukushima Daiichi nuclear disaster Ecological restoration Fukushima Prefecture Radioactively contaminated areas