Jump to content

Sellafield

Coordinates: 54°25′14″N 3°29′51″W / 54.4205°N 3.4975°W / 54.4205; -3.4975
From Wikipedia, the free encyclopedia
(Redirected from Dirty thirty (Sellafield))

Sellafield nuclear site
2005 view of the site
Map
Official nameSellafield Site. Known 1956-1971 as Windscale & Calder Works, known 1947-1956 as Windscale Works.
CountryUnited Kingdom
LocationSeascale, Cumbria
Coordinates54°25′14″N 3°29′51″W / 54.4205°N 3.4975°W / 54.4205; -3.4975
StatusOperational
Commission dateWindscale Piles (non-power generating): 1950
Calder Hall: 1956
Windscale AGR: 1962
OwnerNuclear Decommissioning Authority
OperatorSellafield Ltd
Employees10,000+
Nuclear power station
Reactor typeMagnox (Calder Hall)
AGR prototype (Windscale)
Power generation
Units operationalNo nuclear power generation since 2003.
Processes still active: spent fuel storage, waste processing and storage, and plant decommissioning.
Units decommissionedUnits taken out of service: Calder Hall: 4 x 60 MWe (gross)
Windscale AGR: 1 x 36 MWe.
Final decommissioning for complete site 2120
External links
CommonsRelated media on Commons

grid reference NY034036

Sellafield, formerly known as Windscale, is a large multi-function nuclear site close to Seascale on the coast of Cumbria, England. As of August 2022, primary activities are nuclear waste processing and storage and nuclear decommissioning. Former activities included nuclear power generation from 1956 to 2003, and nuclear fuel reprocessing from 1952 to 2022.

The licensed site covers an area of 265 hectares (650 acres),[1] and comprises more than 200 nuclear facilities and more than 1,000 buildings.[2] It is Europe's largest nuclear site and has the most diverse range of nuclear facilities in the world on a single site.[3] The site's workforce size varies, and before the COVID-19 pandemic was approximately 10,000 people. The UK's National Nuclear Laboratory has its Central Laboratory and headquarters on the site.

Originally built as a Royal Ordnance Factory in 1942, the site briefly passed into the ownership of Courtaulds for rayon manufacture following WW2, but was re-acquired by the Ministry of Supply in 1947 for the production of plutonium for nuclear weapons which required the construction of the Windscale Piles and the First Generation Reprocessing Plant, and it was renamed "Windscale Works". Subsequent key developments have included the building of Calder Hall nuclear power station - the world's first nuclear power station to export electricity on a commercial scale to a public grid, the Magnox fuel reprocessing plant, the prototype Advanced Gas-cooled Reactor (AGR) and the Thermal Oxide Reprocessing Plant (THORP). Decommissioning projects include the Windscale Piles,[4] Calder Hall nuclear power station, and a number of historic reprocessing facilities and waste stores.

The site is owned by the Nuclear Decommissioning Authority (NDA) which is a non-departmental public body of the UK government. Following a period 2008–2016 of management by a private consortium, the site was returned to direct government control by making the Site Management Company, Sellafield Ltd, a subsidiary of the NDA. Decommissioning of legacy facilities, some of which date back to the UK's first efforts to produce an atomic bomb, is planned for completion by 2120 at a cost of £121 billion.[5]

Sellafield was the site in 1957 of one of the world's worst nuclear incidents. This was the Windscale fire which occurred when uranium metal fuel ignited inside Windscale Pile no.1. Radioactive contamination was released into the environment, which it is now estimated caused around 240 cancers in the long term, with 100 to 240 of these being fatal.[6][7][8] The incident was rated 5 out of a possible 7 on the International Nuclear Event Scale.[6]

Site development

[edit]

Royal Ordnance Factory

[edit]

The site was established with the creation of Royal Ordnance Factory ROF Sellafield by the Ministry of Supply in 1942; built by John Laing & Son[9] at the hamlet of Low Sellafield.[10] The nearby sister factory, ROF Drigg, had been constructed in 1940, 3 miles (5 km) to the south-east near the village of Drigg.[11] Both sites were classed as Explosive ROFs, producing high-explosive at ROF Drigg, and propellant at ROF Sellafield. They were built in this location to be remote from large centres of population because of the hazardous nature of the process, and to reduce the risk of WW2 enemy air attack. There were also existing rail links, and a good supply of high quality water from Wastwater. Production ceased at both factories immediately following the defeat of Japan.

Start of nuclear activity

[edit]
The site in 1956. In foreground Calder Hall cooling towers and two Magnox reactors. Background L to R: First Generation reprocessing plant, Windscale pile chimneys.

After WW2, the Sellafield site was briefly in the ownership of Courtaulds for development as a rayon factory, but was re-acquired by the Ministry of Supply for the production of plutonium for nuclear weapons. Construction of the nuclear facilities commenced in September 1947 and the site was renamed Windscale Works. The building of the nuclear plant was a huge construction project, requiring a peak effort of 5,000 workers. The two air-cooled and open-circuit, graphite-moderated Windscale reactors (the "Windscale Piles") and the associated First Generation Reprocessing Plant, producing the first British weapons grade plutonium-239, were central to the UK nuclear weapons programme of the 1950s.

Windscale Pile No.1 became operational in October 1950, just over three years from the start of construction, and Pile No.2 became operational in June 1951.

Calder Hall power station

[edit]
Queen Elizabeth II officially opening Calder Hall nuclear power station on 17 October 1956

With the creation of the United Kingdom Atomic Energy Authority (UKAEA) in 1954, ownership of Windscale Works passed to the UKAEA. At this time the site was being expanded across the River Calder where four Magnox reactors were being built to create the world's first commercial-scale nuclear power station. This became operational in 1956 and was the world's first nuclear power station to export electricity on a commercial scale to a public grid. The whole site became known as "Windscale and Calder Works".

British Nuclear Fuels Ltd (BNFL)

[edit]

Following the break-up of the UKAEA into a research division (UKAEA) and a newly created company for nuclear production British Nuclear Fuels Ltd (BNFL) in 1971, a major part of the site was transferred to BNFL ownership and management. In 1981 BNFL's Windscale and Calder Works was renamed Sellafield as part of a major reorganisation of the site and there was a consolidation of management under one head of the entire BNFL Sellafield site. The remainder of the site remained in the hands of the UKAEA and was still called Windscale.[12]

Reprocessing

[edit]

Sellafield was the centre of UK nuclear reprocessing operations, which separated the uranium and plutonium from minor actinides and fission products present in spent nuclear fuel.[13] The uranium could be used in the manufacture of new nuclear fuel, or in applications where its density was an asset. The plutonium was originally used for weapons, and later in the manufacture of mixed oxide fuel (MOX) for thermal reactors. Reprocessing ceased on 17 July 2022, when the Magnox Reprocessing Plant completed its last batch of fuel after 58 years of operation.[14]

Sellafield Site has had three separate fuel reprocessing facilities:

  1. First Generation (Windscale): 1951–1973 – production of Plutonium for weapons. 750 tonnes fuel per year
  2. Magnox: 1964–2022 – Magnox national reactor fleet fuel reprocessing
  3. Thermal Oxide Reprocessing Plant (THORP): 1994–2018 – National AGR fleet oxide fuel reprocessing

Magnox and THORP had a combined annual capacity of nearly 2,300 tonnes.

Despite the end of reprocessing, Sellafield is still the central location which receives and stores used fuel from the UK's fleet of gas cooled reactor stations.[15][16] The site has also processed overseas spent fuel from several countries under contract. There had been concern that Sellafield would become a repository for unwanted international nuclear material. However, contracts agreed since 1976 with overseas customers required that all High Level Waste be returned to the country of origin. The UK retained low and intermediate level waste resulting from that reprocessing, and in substitution shipped out a radiologically equivalent amount of its own HLW. The policy was designed to be environmentally neutral by expediting, and reducing the volume, of shipments.[17]

Decommissioning

[edit]

Nuclear decommissioning is the process whereby a nuclear facility is dismantled to the point that it no longer requires measures for radiation protection.[18] Sellafield's highest priority nuclear decommissioning challenges are mainly the legacy of the early nuclear research and nuclear weapons programmes.[19] There is a considerable inventory of buildings which have ceased operating but are in "care and maintenance" awaiting final decommissioning.

The 2018–2021 NDA business plan for Sellafield decommissioning is focused on older legacy high hazard plants and includes the following key activities in the area of Legacy Ponds and Silos;[20]

  • Pile Fuel Storage Pond (PFSP): Sustain sludge exports and prepare for de-watering
  • Pile Fuel Cladding Silo (PFCS): Complete commissioning of Box Encapsulation Plant to receive silo contents, and begin retrievals.
  • First Generation Magnox Storage Pond (FGMSP): Continue to retrieve fuel and sludge.
  • Magnox Swarf Storage Silo (MSSS): Begin retrievals from the silo.

Also:

  • Continue demolition of Pile No.1 chimney

Defuelling and removal of most buildings at Calder Hall is expected to take until 2032, followed by a care and maintenance phase from 2033 to 2104. Demolition of reactor buildings and final site clearance is planned for 2105 to 2114.[21]

As of March 2021, the NDA reported that they had:[22]

  • Removed significant quantities of bulk fuel and over 300 tonnes of solid intermediate level waste (ILW) from the PFSP
  • Removed more than 100 cubic metres (3,500 cu ft) of sludge from the FGMSP
  • Installed the first of the 400-tonne silo emptying plants in the MSSS. The retrievals started in June 2022;[23] it is estimated this phase will continue for 20 years.
  • Created new access and equipment installed for waste retrieval from the PFCS

In August 2023, work started to retrieve waste from the PFCS, which had been created in the 1950s to store cladding from used Windscale Piles nuclear fuel, described as "a momentous milestone in the decommissioning story at Sellafield as the first batch of waste was successfully retrieved from the site’s oldest waste store" and "one of the most complex and difficult decommissioning challenges in the world".[24]

Management model following the Energy Act 2004

[edit]

Following ownership by BNFL, since 1 April 2005 the site has been owned by the Nuclear Decommissioning Authority (NDA), a non-departmental public body of the UK government created by the Energy Act 2004 as part of government policy to introduce competition into the nuclear industry to better control decommissioning costs. In 2008, the NDA awarded Nuclear Management Partners (NMP) the position of Parent Body Organisation of Sellafield Ltd under their standard management model for NDA sites; this gave them complete responsibility for operating and managing the NDA-owned assets, the direct workforce and the site. This consortium, composed of US company URS, British company AMEC and French company Areva, was initially awarded a contract for five years, with extension options to 17 years, and in November 2008, NMP took over management of the site.[25] In October 2008, it was revealed that the British government had agreed to issue the managing body for Sellafield an unlimited indemnity against future accidents; according to The Guardian, "the indemnity even covers accidents and leaks that are the consortium's fault." The indemnity had been rushed through prior to the summer parliamentary recess without notifying parliament.[26]

On 13 January 2015, the NDA announced that NMP would lose the management contract for Sellafield as the "complexity and technical uncertainties presented significantly greater challenges than other NDA sites", and the site was therefore "less well suited" to the NDA's existing standard management model.[27] The new structure, which came into effect on 1 April 2016, saw Sellafield Ltd. become a subsidiary of the NDA.

Decommissioning cost estimates

[edit]
NDA increasing estimates of remaining cost of decommissioning and clean-up[28][29]
Year of
estimate
Sellafield* Other NDA sites Total
(£ billions, discounted)
2006–07 21.9 11.7 33.6[30]
2007–08 24.8 15.9 40.7[30]
2009–10 25.2 19.9 45.1
2010–11 32.7 16.5 49.2
2011–12 37.2 15.6 52.9
2012–13 42.0 16.9 58.9
2013–14 47.9 17.0 64.9
2014–15 53.2 12.5 65.7[31]
2015–16 117.4 43.3 160.7
2018–19 97.0 21.3 118.3[32]
* Sellafield includes Calder Hall and Windscale,
and Energy Trading
Chart of the estimated growing decommission cost for Sellafield versus other sites 2005-2120 (undiscounted), revisions until 2019

Sellafield accounts for most of the NDA's decommissioning budget and the increases in future cost estimates. Its share (discounted, including Calder Hall and Windscale; excluding Capenhurst) increased from 21.9 billion (65%) in 2007[30] to 97.0 billion (82%) in 2019.[32]

In 2013, the UK Government Public Accounts Committee issued a critical report stating that NMP had failed to reduce costs and delays. Between 2005 and 2013, the annual costs of operating Sellafield had increased from £900 million to about £1.6 billion. The estimated lifetime undiscounted cost of dealing with the Sellafield site increased to £67.5 billion.[33][34][35] NMP management was forced to apologise after projected clean-up costs passed the £70 billion mark in late 2013.[36] In 2014, the final undiscounted decommissioning cost projection for Sellafield was increased to £79.1 billion,[37] and in 2015 to £117.4 billion.[29] The annual operating cost was projected to be £2 billion in 2016.[38] In 2018, it was revealed that the cost could be £121 billion by 2120.[5]

The cost does not include the costs for future geological disposal (GDF). These include research, design, construction, operation and closure. The undiscounted lifetime costs for a GDF were estimated £12.2 billion in 2008. The NDA's share of this is £10.1 billion, which results in a discounted amount of about £3.4 billion.[30],p. 27

Major plants

[edit]

Windscale Piles

[edit]
1985 view. L to R; The "Golf Ball" WAGR reactor, the Windscale Piles with their large exhaust stacks. The water vapour is from the Calder Hall cooling towers.

Following the decision taken by the British government in January 1947 to develop nuclear weapons, Sellafield was chosen as the location of the plutonium production plant, consisting of the Windscale Piles and accompanying reprocessing plant to separate plutonium from the spent nuclear fuel. Unlike the early US nuclear reactors at Hanford, which consisted of a graphite core cooled by water, the Windscale Piles consisted of a graphite core cooled by air. Each pile contained almost 2,000 tonnes (1,968 L/T) of graphite, and measured over 7.3 metres (24 ft) high by 15.2 metres (50 ft) in diameter. Fuel for the reactor consisted of rods of uranium metal, approximately 30 cm (12 inches) long by 2.5 cm (0.98 inches) in diameter, and clad in aluminium.[39] The initial fuel was loaded into the Windscale Piles in July 1950.[40][41] By July 1952 the separation plant was being used to separate plutonium and uranium from spent fuel.[citation needed]

On 10 October 1957, the Windscale Piles were shut down following a fire in Pile 1 during a scheduled graphite annealing procedure. The fire badly damaged the pile core and released an estimated 750 terabecquerels (20,000 curies) of radioactive material, including 22 TBq of Cs-137 and 740 TBq of I-131 into the shafts.[42] Thanks to innovative filters installed by Nobel laureate Sir John Cockcroft 95% of the material was captured.[43][44] As a precautionary measure, milk from surrounding farming areas was destroyed. However, no residents from the surrounding area were evacuated or informed of the danger of the radiation leakage. It is now believed that there have been 100 to 240 cancer deaths as a result of the release of radioactive material.[6][7][8] Following the fire, Pile 1 was unserviceable, and Pile 2, although undamaged by the fire, was shut down as a precaution.[39]

In the 1990s, the United Kingdom Atomic Energy Authority started to implement plans to decommission, disassemble and clean up both piles. In 2004, Pile 1 still contained about 15 tonnes (14.76 L/T) of uranium fuel, and final completion of the decommissioning is not expected until at least 2037.[39]

In 2014, radioactive sludge in the Pile Fuel Storage Pond (PFSP), built between 1948 and 1952, started to be repackaged in drums to reduce the "sludge hazard" and to allow the pond to be decommissioned.[45][46] Decommissioning will require retrieval of sludge and solids, prior to dewatering and deconstruction, with retrievals planned for completion in 2016.[47]

First Generation Reprocessing Plant

[edit]

The first generation reprocessing plant was built to extract the plutonium from spent fuel to provide fissile material for the UK's atomic weapons programme, and for exchange with the United States through the US-UK Mutual Defence Agreement.[48]

The Butex process was used (a forerunner to the more efficient Purex process) [49] and the plant operated from 1951 until 1964, with an annual capacity of 300 tonnes (295 L/T) of pile spent fuel, or 750 tonnes (738 L/T) of low burn-up fuel. It was first used to reprocess fuel from the Windscale Piles but was later repurposed to process fuel from UK Magnox reactors. Following the commissioning of the dedicated Magnox Reprocessing Plant, it became a pre-handling plant to allow oxide fuel to be reprocessed in the Magnox reprocessing plant. It was closed in 1973 after a violent reaction within the plant contaminated the entire plant and 34 workers with ruthenium-106.[50][51]

Magnox Reprocessing Plant

[edit]

In 1964, the Magnox reprocessing plant came on stream to reprocess spent nuclear fuel from the national Magnox reactor fleet.[52] The plant used the "plutonium uranium extraction" (Purex) method for reprocessing spent fuel, with tributyl phosphate in odourless kerosene and nitric acid as extraction agents. The Purex process produces uranium, plutonium and fission products as separated chemical output streams.[53]

Magnox fuel has to be reprocessed in a timely fashion since the cladding corrodes if stored underwater, and routes for dry storage have not yet been proven, so it has been necessary to keep the plant running to process all the Magnox fuel inventory.[54]

Magnox fuel reprocessing ceased on 17 July 2022, when the reprocessing plant completed its last batch of fuel after 58 years of operation. A total of 55,000 tonnes of fuel had been processed during those years.[14]

The First Generation Magnox Storage Pond (FGMSP)

[edit]
FGMSP - showing spent fuel skips stored underwater

This was built to support reprocessing of fuel from UK Magnox power stations through the Magnox Reprocessing Plant.[55] It was initially planned to be used to keep fuel rods in for three months before they were reprocessed,[56] but was used for operations between 1959 until 1985.[57] The pond is 20 m (66 ft) wide, 150 m (490 ft) long and 6 m (20 ft) deep. Originally called B30 (and nicknamed 'Dirty 30'), the pond was renamed in 2018.[56]

As of 2014, the FGMSP remains as a priority decommissioning project. As well as nuclear waste, the pond holds about 1,200 cubic metres (42,000 cu ft) of radioactive sludge of unknown characteristics and 14,000 cubic metres (490,000 cu ft) of contaminated water.[58] Decommissioning requires retrieval of the radioactive sludge into a newly built Sludge Packaging Plant, as well as fuel and skip retrieval. Completion of this will allow the dewatering and dismantling of the remaining structure.

Future work will immobilise the sludge for long-term storage, and process solids through the Fuel Handling Plant for treatment and storage.[59]

Magnox Swarf Storage Silo (MSSS)

[edit]
The Magnox Swarf Storage silo pictured from the air on the Sellafield Site. At the time the photo was taken, the silo had undergone significant modernisation work to facilitate the retrieval operations.

The Magnox Swarf Storage Silo is a large building on the Sellafield Site which contains intermediate level fuel cladding swarf waste arising from reprocessing Magnox reactor fuel. Once expended fuel was removed from the Magnox reactors, the magnesium cladding was removed prior to the chemical processing of the fuel rod. To accomplish this, the fuel can was fed through a machine known as a "decanner" which stripped the cladding off the inner rod creating the swarf of broken magnesium alloy cladding as a waste product. Since the start of commercial Magnox reprocessing in 1964 (the same year MSSS began operations), this waste was deposited into individual water-filled compartments within the MSSS. As they became full, more were added between the 1960s and 1983 totalling 22 compartments. In the early 1990s, the wet storage of this waste was no longer seen as the most effective way to store the material, and in later years was replaced with a dry storage method. The long-term storage and subsequent degradation of the magnesium alloy swarf in water causes an exothermic reaction which releases hydrogen gas. Normal operating procedures and overall design of the silo allowed for hydrogen gas to be safely vented before it could accumulate, and the heat can be removed through re-circulation of the water. The Magnox Swarf Storage Silo ceased being filled in 2000.[60]

Many of the historic Sellafield operating practices have been superseded by better and safer alternatives.[61] Consequently, since 2000 the Magnox Encapsulation Plant on site has been responsible for the safe processing and dry storage of Magnox cladding swarf.[62] This still left the problem of removing waste material that has been stored in hazardous conditions in the MSSS. To accomplish this complex task, Sellafield Ltd has partnered with commercial firms to design, construct and operate a remotely operated waste retrieval facility called the Silo Emptying Plant (SEP). This is designed to retrieve waste from the MSSS which will be processed in other specially designed site facilities, and then placed in interim storage at Sellafield. Longer term it is hoped such waste would be consigned to a deep geological repository for permanent storage.[63] The radioactive inventory and lack of modern standards in the silo has made it the most complicated and highest-priority mission in the NDA estate nationally. Preparations for removing the 11,000m3 of historic waste from the silos and storing safely have taken over 20 years.[64]

On 10 June 2022, Sellafield Ltd announced the commencement of waste retrievals which will take approximately 20 years. Once this radiological hazard has been removed, the MSSS structure can be demolished.[23]

Calder Hall nuclear power station

[edit]
Calder Hall, United Kingdom – The world's first industrial-scale nuclear power station. The four reactors have two shared turbine halls between 1 & 2 and between 3 & 4.[65]

Calder Hall was first connected to the grid on 27 August 1956 and officially opened by Queen Elizabeth II on 17 October 1956.[66][67] It was the world's first nuclear power station to provide electricity on a commercial scale to a public grid.[68][note 1]

The Calder Hall design was codenamed PIPPA (Pressurised Pile Producing Power and Plutonium) by the UKAEA to denote the plant's dual commercial and military role. Construction started in 1953.[69] Calder Hall had four Magnox reactors capable of generating 60 MWe (net) of power each, reduced to 50 MWe in 1973.[70][71] The reactors also supplied steam to the whole site for process and other purposes. The reactors were supplied by UKAEA, the turbines by C. A. Parsons and Company,[71] and the civil engineering contractor was Taylor Woodrow Construction.[72]

In its early life Calder Hall primarily produced weapons-grade plutonium, with two fuel loads per year; electricity production was a secondary purpose.[73] From 1964 it was mainly used on commercial fuel cycles; in April 1995 the UK Government announced that all production of plutonium for weapons purposes had ceased.[citation needed]

The station was closed on 31 March 2003, the first reactor having been in use for nearly 47 years.[74] decommissioning started in 2005. The plant should be in save storage, called "care and maintenance" (C&M), by 2027 or later.[75]

Calder Hall had four cooling towers, each 88 metres (289 ft) in height, which were highly-visible landmarks. Plans for a museum involving renovating Calder Hall and preserving the towers were formulated, but the costs were too high.[76] The cooling towers were demolished by controlled implosions on 29 September 2007. A period of 12 weeks was required to remove asbestos in the towers' rubble.[77]

Windscale Advanced Gas Cooled Reactor (WAGR)

[edit]

The WAGR was a prototype for the UK's second generation of reactors,[78] the advanced gas-cooled reactor or AGR, which followed on from the Magnox stations. The station had a rated thermal output of approximately 100 MW and 30 MWe. The WAGR spherical containment, known colloquially as the "golfball", is one of the iconic buildings on the site. Construction was carried out by Mitchell Construction and completed in 1962.[79] This reactor was shut down in 1981, and is now part of a pilot project to demonstrate techniques for safely decommissioning a nuclear reactor.[citation needed]

Thermal Oxide Reprocessing Plant (THORP)

[edit]

Between 1977 and 1978 an inquiry, chaired by Mr Justice Parker, was held into an application by BNFL for outline planning permission to build a new plant to reprocess irradiated oxide nuclear fuel from both UK and foreign reactors. The inquiry was used to answer three questions:

"1. Should oxide fuel from United Kingdom reactors be reprocessed in this country at all; whether at Windscale or elsewhere?
2. If yes, should such reprocessing be carried on at Windscale?
3. If yes, should the reprocessing plant be about double the estimated site required to handle United Kingdom oxide fuels and be used as to the spare capacity, for reprocessing foreign fuels?"
[80]

The result of the inquiry was that the new plant, the Thermal Oxide Reprocessing Plant (THORP) was given the go ahead in 1978, although it did not go into operation until 1994.[citation needed]

In 2003, it was announced that THORP would be closed in 2010, but this was later extended to 2018 to allow completion of agreed contracts. Originally predicted to make profits for BNFL of £500 million, by 2003 it had made losses of over £1 billion.[81] THORP was closed for almost two years from 2005, after a leak had been undetected for nine months. Production eventually restarted at the plant in early 2008, but almost immediately had to be put on hold again, as an underwater lift that takes the fuel for reprocessing needed to be repaired.[82]

On 14 November 2018 it was announced that operations had ended at THORP. The facility will be used to store spent nuclear fuel until the 2070s.[83]

Highly Active Liquor Evaporation and Storage

[edit]

Highly Active Liquor Evaporation and Storage (HALES) is a department at Sellafield. It conditions nuclear waste streams from the Magnox and Thorp reprocessing plants, prior to transfer to the Waste Vitrification Plant.[84]

Waste Vitrification Plant

[edit]
Sellafield Waste Vitrification Plant

In 1990 the Waste Vitrification Plant (WVP), which seals high-level radioactive waste in glass, was opened. In this plant, liquid wastes are mixed with glass and melted in a furnace, which when cooled forms a solid block of glass.[84]

The plant has three process lines and is based on the French AVM procedure. The plant was built with two lines, commissioned during 1989, with a third added in 2002.[84] The principal item is an inductively heated melting furnace, in which the calcined waste is mixed with glass frit (fragments of smashed glass) The melt is poured into waste containers which are welded shut, allowed to cool slowly in a heater to facilitate a monolithic product (single large block of glass with minimal cracks or small crystals to facilitate long term stability), their outsides decontaminated in WVP, then again in the connected building Residue Export Facility (REF), and then placed in the air-cooled Vitrified Product Store.[85]

This storage consists of 800 vertical storage tubes each capable of storing ten containers.[citation needed] The total storage capacity is 8000 containers, and 6000 containers had been stored by 2016.[85]

Vitrification should ensure safe storage of waste in the UK for the medium- to long-term, with the objective of eventual placement in a deep geological repository. As of 2007 studies of durability and leach rates were being carried out.[85][86]

Sellafield MOX Plant

[edit]

Construction of the Sellafield MOX fuel Plant (SMP) was completed in 1997, and operations began in October 2001.[87] Although designed with a production capacity of 120 tonnes/year, the plant achieved a total output of only 5 tonnes during its first five years of operation.[87] Consequently, in 2008 orders for the plant had to be fulfilled at COGEMA in France,[88] and the plant was reported in the media as "failed"[89][90] with a total construction and operating cost by 2009 of £1.2 billion.[91] On 12 May 2010, an agreement was reached with existing Japanese customers on future MOX supplies.[92]

In July 2010 Areva was contracted to design and supply a new rod line to improve reliability and production rate. However, on 3 August 2011 the Nuclear Decommissioning Authority announced that the MOX Plant would close, due to the loss of the Japanese orders following the Fukushima Daiichi nuclear disaster. The NDA stated that the plant "had suffered many years of disappointing performance", and it was reported that the total cost to date had been £1.4 billion.[93][94] Although Japanese orders for MOX fuel re-commenced on 17 April 2013, they were supplied from France by COGEMA.[95]

Enhanced Actinide Removal Plant (EARP)

[edit]

Since its early days, Sellafield has discharged low-level radioactive waste into the sea, using a flocculation process to remove radioactivity from liquid effluent before discharge. Metals dissolved in acidic effluents were made to produce a metal hydroxide flocculant precipitate following the addition of ammonium hydroxide. The suspension was then transferred to settling tanks where the precipitate would settle out, and the remaining clarified liquid, or supernate, would be discharged to the Irish Sea. As an improvement to that process, in 1994 the Enhanced Actinide Removal Plant (EARP) became operational.[citation needed] In EARP the effectiveness of the process is enhanced by the addition of reagents to remove the remaining soluble radioactive species. EARP was enhanced further in 2004 to further reduce the quantities of technetium-99 released to the environment.[96]

Radioactive waste stores

[edit]

Sellafield has a number of radioactive waste stores, mostly working on an interim basis while a deep geological repository plan is developed and implemented.

The stores include: [97]

  • Legacy Ponds and Silos – Storage of historic waste
  • Sludge packaging plant – Treatment and interim storage of sludges from legacy ponds
  • Sellafield product and residue store – Site store for plutonium and plutonium residues – The plutonium stockpile now estimated (November 2013) at 100 tonnes.[98]
  • Engineered drum stores – Site stores for plutonium-contaminated material
  • Encapsulated product stores – Site stores for grouted wastes
  • Vitrified product store – Vitrified high level waste

The UK's main Low Level Waste Repository for nuclear waste is 6 kilometres (3.7 mi) south east of Sellafield at Drigg. A paper published in 1989 said that 70% of the waste received at Drigg originated from Sellafield.[99]

Fellside Power Station

[edit]

Fellside Power Station is a 168 MWe CHP gas-fired power station adjacent to the Sellafield site, which it supplies with process and heating steam. It is run as Fellside Heat and Power Ltd, is wholly owned by Sellafield Ltd and is operated & managed by PX Ltd. It was built in 1993, in anticipation of the closure of the Calder Hall generating station, which supplied these services. It was originally equally owned by BNFL and Scottish Hydro Electric (which became Scottish and Southern Energy in December 1998). BNFL bought SSE's 50% share in January 2002.[citation needed]

The station uses three General Electric Frame 6001B gas turbines, with power entering the National Grid via a 132 kV transformer. The turbines at Fellside are normally natural gas fired but are also able to run on distillate (diesel) fuel.[100]

In May 2023, Sellafield Ltd removed a set of large, now redundant steel tanks at the Fellside power station that were no longer being used. Their original purpose has been fulfilled by newer tanks.[101]

National Nuclear Laboratory headquarters

[edit]

The Central Laboratory at Sellafield is the headquarters of the National Nuclear Laboratory (NNL).[102] It supports newly built reactors, operation of reactors, operations of fuel processing plants and decommissioning and clean-up. The NNL's Central Laboratory can undertake a wide range of radioactive and non-radioactive experimental programmes.[citation needed]

It undertakes a wide range of analytical services, with customers ranging from Government and the NDA to site licence companies, utilities, nuclear specialists and universities. Smaller experiments are undertaken at Sellafield and larger experiments and rigs are assembled off site, in non-radioactive areas prior to active testing in a radioactive setting.[citation needed]

Sellafield and the local community

[edit]

Employment

[edit]
2005 view of the site, with the Calder Hall cooling towers still standing. The Irish Sea is in the background.

Sellafield directly employs around 10,000 people[103] and is one of the two largest non-governmental employers in West Cumbria (along with BAE Systems at Barrow-in-Furness),[104] with approximately 90% of the employees coming from West Cumbria.[105]

Because of the increase in local unemployment following any run down of Sellafield operations, the Nuclear Decommissioning Authority (and HMG) is concerned that this needs to be managed.[106]

West Cumbria Sites Stakeholder Group (WCSSG)

[edit]

The WCSSG is an independent body whose role is to provide public scrutiny of the nuclear industry in West Cumbria.[107]

The WCSSG replaced the Sellafield Local Liaison Committee (SLLC) to cover all the nuclear licensed sites in the area, not just Sellafield Site, and this change is intended to emphasise the importance of engagement with the community; encouraging input in discussions and consultations from all stakeholders. With the change of organisation and ownership of licensed sites, the WCSSG has consequently changed and re-organised its sub-committees, but the objective remains the same. The meetings of the main group and its sub-committees are held in West Cumbria and are open to the public.[107]

Sellafield Visitor Centre

[edit]
The Sellafield Visitor Centre in the late 1980s; it is now demolished.

The £5 million centre was opened by Prince Philip on 6 June 1988,[108] and at its peak it attracted an average of 1,000 people per day.[109] However, despite a large refurbishment in 1995, and the transfer of creative control to the Science Museum in 2002,[110][111] its popularity deteriorated, prompting the change from a tourist attraction to a conference facility in 2008. This facility completely closed in 2015, was briefly used by the Civil Nuclear Constabulary as a training facility, and as of 2019 the building has been completely demolished. The story of Sellafield is now being told through a permanent exhibition at the Beacon Museum in Whitehaven.[108][110]

Incidents

[edit]

Radiological releases

[edit]

Between 1950 and 2000, there were 21 serious incidents or accidents involving off-site radiological releases that warranted a rating on the International Nuclear Event Scale, one at level 5, five at level 4 and fifteen at level 3. Additionally, during the 1950s and 1960s there were protracted periods of known, deliberate discharges to the atmosphere of plutonium and irradiated uranium oxide particulates.[112]

In the effort to build the independent British nuclear weapon in the 1940s and 1950s, diluted radioactive waste was discharged by pipeline into the Irish Sea.[113] Greenpeace claims that the Irish Sea remains one of the most heavily contaminated seas in the world because of these discharges.[114] Ocean scientist David Assinger has challenged this general suggestion, and cites the Dead Sea as the most radioactive sea in the world.[115] The Convention for the Protection of the Marine Environment of the North-East Atlantic (OSPAR Convention) reports an estimated 200 kg (440 lb) of plutonium has been deposited in the marine sediments of the Irish Sea.[116]

Most of the area's long-lived radioactive technetium came from the reprocessing of spent nuclear fuel at the Sellafield facility.[117] Technetium-99 is a radioactive element which is produced by nuclear fuel reprocessing, and also as a by-product of medical facilities (for example Ireland is responsible for the discharge of approximately 11 grams or 6.78 gigabecquerels of technetium-99 each year despite not having a nuclear industry).[118] Because it is almost uniquely produced by nuclear fuel reprocessing, technetium-99 is an important element as part of the OSPAR Convention since it provides a good tracer for discharges into the sea.[citation needed] In itself, the technetium discharges do not represent a significant radiological hazard,[119] and in 2000, a study noted "...that in the most recently reported dose estimates for the most exposed Sellafield group of seafood consumers (FSA/SEPA 2000), the contributions from technetium-99 and actinide nuclides from Sellafield (<100 μSv) was less than that from 210Po attributable to discharges from the Whitehaven phosphate fertiliser plant and probably less than the dose from naturally occurring background levels of 210Po."[120]

Because of the need to comply with the OSPAR Convention, British Nuclear Group commissioned a new process in which technetium-99 was removed from the waste stream and vitrified in glass blocks in the new Vitrification Plant on site.[121]

Discharges into the sea of radioactive effluents – mainly caesium-137 – from Sellafield amounted to 5200 TBq during the peak year, 1975.[122]

In 1983 radioactive discharges to sea containing ruthenium and rhodium-106, both beta-emitting isotopes, resulted in temporary warnings against swimming in the sea along a 10-mile (16 km) stretch of coast between St. Bees and Eskmeals.[123][124] BNFL received a fine of £10,000 for this discharge.[125] 1983 was also the year in which Yorkshire Television produced a documentary "Windscale: The Nuclear Laundry", which claimed that the low levels of radioactivity that are associated with waste streams from nuclear plants such as Sellafield did pose a non-negligible risk.[126]

Windscale fire

[edit]

The Windscale fire of October 1957 stands as the most severe incident in the history of the Sellafield site. This event, rated at level 5 out of 7 on the International Nuclear Event Scale, ranks among the world's most significant nuclear accidents, with only three events having received higher ratings. The incident involved a fire in the Windscale Piles, facilities used for plutonium production, which resulted in a substantial release of radioactive fallout into the environment.[7] The consequences of this event were far-reaching. Surrounding agricultural areas, particularly dairy farms, experienced radioactive contamination. Of notable concern was the release of significant quantities of the iodine-131 isotope, a known contributor to thyroid cancer risk.[127] The scale and impact of this incident have made it a subject of ongoing study and discussion in the field of nuclear safety.

The UK government downplayed the events for some time and the original reports on the fire were subject to heavy censorship, as Prime Minister Harold Macmillan feared the incident would harm British-American nuclear relations.[8] It has since come to light that small but significant amounts of the highly dangerous radioactive isotope polonium-210 were also released, though knowledge of this was excluded from government reports until 1983.[128]

The Windscale fire remains Britain's worst nuclear accident, and the worst nuclear accident in the West.[8][43] The release would have been much worse if it had not been for the filter at the top of the Pile's exhaust chimney.[6]

A 1988 UK government estimate stated that 100 people "probably" died as a result of exposure to the radioactive fallout from the Windscale fire.[129][130] In 2007, the 50-year anniversary of the fire, new academic research concluded that the amount of radioactive fallout released was twice the existing estimates and it spread further east than thought.[8][7][6] The study concluded that 240 people were given cancer in the surrounding areas, and that 100 to 240 of these cancer cases were fatal.[6][7][8]

Plutonium Recovery Plant criticality

[edit]

On 24 August 1970, a criticality incident occurred in the Plutonium Recovery Plant.[131]

The plant recovered plutonium from miscellaneous sources and was considered tightly controlled. Plutonium was dissolved and transferred into a solvent extraction column through a transfer vessel and backflow trap. Unexpectedly, 2.15 kg (4.7 lb) of plutonium had accumulated in the transfer vessel and backflow trap and become just sub-critical. As an organic solvent was added to the aqueous solution in the vessel, the organic and aqueous phases separated out with the organic layer on top. This solvent extracted plutonium from the aqueous solution with sufficient concentration and geometry to create a criticality.[132]

Two plant workers were exposed to radiation.[133]

First Generation Magnox Storage Pond Deterioration

[edit]

Due to algae forming in the pond and a buildup of radioactive sludge, it was impossible to determine exactly how much radioactive waste was stored in the FGMSP. British authorities had not been able to provide the Euratom inspectors with precise data and the European Commission took action against Great Britain in the European Court of Justice in 2004.[134][135] According to Greenpeace there was an expected 1300 kg of plutonium, 400 kg of which was in mud sediments.[136]

Radiation around the pool could get so high that a person was not allowed to stay more than 2 minutes, seriously affecting decommissioning.[137] The pool was not watertight; time and weather had created cracks in the concrete, letting contaminated water leak.[138] In 2014 photographs of the storage ponds were leaked to the media, showing they were in poor condition with cracked concrete, vegetation growing amongst machinery and seagulls bathing in the pools.[139]

MOX fuel quality data falsification

[edit]

The MOX Demonstration Facility was a small-scale plant to produce commercial quality MOX fuel for light water reactors. The plant was commissioned between 1992 and 1994, and until 1999 produced fuel for use in Switzerland, Germany and Japan.[140]

In 1999 it was discovered that the plant's staff had been falsifying quality assurance data since 1996.[141] A Nuclear Installations Inspectorate (NII) investigation concluded four of the five work-shifts were involved in the falsification, though only one worker admitted to falsifying data, and that "the level of control and supervision ... had been virtually non-existent.". The NII stated that the safety performance of the fuel was not affected as there was also a primary automated check on the fuel. Nevertheless, "in a plant with the proper safety culture, the events described in this report could not have happened" and there were systematic failures in management.[142]

BNFL had to pay compensation to the Japanese customer, Kansai Electric, and take back a flawed shipment of MOX fuel from Japan.[143] BNFL's Chief Executive John Taylor resigned,[144] after initially resisting resignation when the NII's damning report was published.[145][146]

Plutonium records discrepancy

[edit]

On 17 February 2005, the UK Atomic Energy Authority reported that 29.6 kilograms (65 lb) of plutonium was unaccounted for in auditing records at the Sellafield nuclear fuel reprocessing plant. The operating company, the British Nuclear Group, described this as a discrepancy in paper records and not as indicating any physical loss of material. They pointed out that the error amounted to about 0.5%, whereas International Atomic Energy Agency regulations permit a discrepancy up to 1% as the amount of plutonium recovered from the reprocessing process never precisely matches the pre-process estimates.[citation needed]

The inventories in question were accepted as satisfactory by Euratom, the relevant regulatory agency.[147][148]

Waste Vitrification Plant sabotage

[edit]

In 2000, wires on six robotic arms that moved vitrified glass blocks were deliberately cut by staff, putting the vitrification plant out of operation for three days.[149]

2005 THORP plant leak

[edit]

On 19 April 2005, around 83,000 litres (18,000 imperial gallons; 22,000 US gallons) of hot nitric acid containing dissolved radioisotopes was discovered to have leaked in the THORP reprocessing plant from a cracked pipe into a huge stainless steel-lined concrete sump chamber built to contain leaks.

A discrepancy between the amount of material entering and exiting the THORP processing system had first been noted in August 2004. Operations staff did not discover the leak until safeguards staff reported the discrepancies. Nineteen tonnes of uranium and 160 kg (350 lb) of plutonium dissolved in nitric acid has been pumped from the sump vessel into a holding tank.[150]

No radiation was released to the environment, and no one was injured by the incident, but because of the large escape of radioactivity to the secondary containment the incident was given an International Nuclear Event Scale level 3 categorisation. Sellafield Limited was fined £500,000 for breaching health and safety law. In January 2007, Sellafield was given consent to restart THORP.[150]

Organ removal inquiry

[edit]

In 2007, an inquiry was launched into the removal of tissue from a total of 65 dead nuclear workers, some of whom worked at Sellafield.[151] It has been alleged that the tissue was removed without seeking permission from the relatives of the late workers. Michael Redfern QC was appointed to lead the investigation.[152] At the same time The Observer revealed that official documents showed that during the 1960s volunteer workers at Sellafield had participated in secret Cold War experiments to assess the biological effect of exposure to radioactive substances, such as from ingesting caesium-134.[153]

The inquiry final report was published in November 2010,[154] reporting that "...body parts had been removed between 1961 and 1992. The deaths of 76 workers – 64 from Sellafield and 12 from other UK nuclear plants – were examined, although the scope of the inquiry was later significantly widened."[155] The person behind this scheme was Dr Geoffrey Schofield, who became BNFL's Company chief medical officer, and who died in 1985. Sellafield staff did not breach any legal obligation, did not consider their actions untoward, and published the scientific information obtained in peer-reviewed scientific journals. It was the hospital pathologists, who were profoundly ignorant of the law, who breached the Human Tissue Act 1961 by giving Sellafield human organs, without any consents, under an informal arrangement.[154]

2023 hacking and radioactive leak

[edit]

In December 2023, it emerged that Sellafield was the victim to cyber hacking by groups closely linked to Russia and China[156] It was first reported by UK newspaper The Guardian, it is unknown if the malware has yet been eradicated. It is still unknown to the extent of the attack and what the long term effects are.

The Guardian has since revealed that the Sellafield site has a "worsening leak from a huge silo of radioactive waste" that is likely to continue until 2050.[157] The silo in question is the Magnox swarf storage silo and it was reported that scientists were still trying to estimate the risk to the public using statistical modelling.[157]

Health studies in Cumbria and Seascale

[edit]

In 1983, the Medical Officer of West Cumbria, is said by Paul Foot to have announced that cancer fatality rates were lower around the nuclear plant than elsewhere in Great Britain.[158] In the early 1990s, concern was raised in the UK about apparent clusters of leukaemia near nuclear facilities.[159]

A 1997 Ministry of Health report stated that children living close to Sellafield had twice as much[quantify] plutonium in their teeth as children living more than 100 miles (160 km) away. Health Minister Melanie Johnson said the quantities were minute and "presented no risk to public health". This claim, according to a book written by Stephanie Cooke, was challenged by Professor Eric Wright, an expert on blood disorders at the University of Dundee, who said that even microscopic amounts of plutonium might cause cancer.[160]

Studies carried out by the Committee on Medical Aspects of Radiation in the Environment (COMARE) in 2003 reported no evidence of raised childhood cancer in general around nuclear power plants, but did report an excess of leukaemia (cancer of the blood or bone) and non-Hodgkin's lymphoma (NHL, a blood cancer) near two other nuclear installations including Sellafield, the Atomic Weapons Establishment Burghfield and UKAEA Dounreay. COMARE's conclusion was that "the excesses around Sellafield and Dounreay are unlikely to be due to chance, although there is not at present a convincing explanation for them".[161] In earlier reports COMARE had suggested that "a mechanism involving infection may be a significant factor."[162] The clusters have disappeared in the early 1990s.[159]

The main finding of the new report was that there was no significantly increased leukaemia and non-Hodgkin lymphoma around Sellafield or Dounreay for the period 1991‐2006

— Dr Chris Gibson, chair of COMARE

In a study published in the British Journal of Cancer, which also did not find an increase in any other cancers other than Leukemia, the authors of which attempted to quantify the effect population mixing might have on the Seascale leukaemia cluster. In the analysis of childhood leukaemia/NHL in Cumbria, excluding Seascale, they noted that if both parents were born outside the Cumbrian area (incomers), there was a significantly higher rate of leukaemia/NHL in their children. 1181 children were born in the village of Seascale between 1950 and 1989, in children aged 1–14 during this period, the Seascale cluster of 6 observed cases of NHL were noted. Two similarly aged children, born between 1950 and 1989, outside Seascale were also diagnosed with ALL/NHL before the end of 1992. The origin of birth of 11 of the 16 parents of these eight children was known, and found to be; 3 had parents born outside Cumbria and 3 had one parent born outside the UK. The study's authors strongly supported the hypothesis that the risk of ALL/NHL, in particular in the younger age group, increases with increased exposure to population mixing during gestation or early in life. Although they determined that the exact mechanism by which it causes these malignancies, apart from Kinlen's infection aetiology[163] that was mentioned, remained unknown, concluding that the possibility of additional risk factors in Seascale remains.[164]

In an examination of all causes of stillbirth and infant mortality in Cumbria taken as a whole, between 1950 and 1993, 4,325 stillbirths, 3,430 neonatal death and 1,569 lethal congenital anomalies, occurred among 287,993 births. Overall, results did not infer an increased risk of still birth or neonatal death in Cumbria, the rate of these negative outcomes were largely in line with the British baseline rate. However, there was a cautioned connection between a small excess of increased risk of death from lethal congenital anomalies and proximity to municipal waste incinerators and chemical waste crematoriums being noted. With two examples of the latter crematoriums operating in both Barrow-in-Furness and further afield at Carlisle, crematoriums which may have emitted various chemical dioxins during their operation.[165]

Objections to reprocessing

[edit]

Republic of Ireland

[edit]
An unopened box of potassium iodate tablets

Potassium iodate tablets were distributed to every household in Ireland in the wake of 9/11 in case of a terror attack on reprocessing plants and nuclear power stations in Britain. Upon later expert Irish examination in 2007, this was found not to have been justified.[166][167] The Irish Department of Health advised in 2021 that the tablets could be disposed of with municipal waste.[167]

Sellafield has been a matter of consternation in Ireland, with the Irish Government and some of the population concerned at the risk that such a facility may pose to the country. The Irish government has made formal complaints about the facility, and in 2006 came to an agreement with the British Government about the matter, as part of which the Radiological Protection Institute of Ireland and the Garda Síochána (the Irish police force) are now allowed access to the site.[168]

Isle of Man

[edit]

The Government of the Isle of Man has also registered protests due to the risk posed by radioactive contamination, due to the proximity of the Isle of Man. The Manx government has called for the site to be shut down.[169]

The Irish and Manx governments have collaborated on this issue, and brought it to the attention of the British-Irish Council.[170]

Norway

[edit]

Similar objections to those held by the Irish government have been voiced by the Norwegian government since 1997. Monitoring undertaken by the Norwegian Radiation Protection Authority has shown that the prevailing sea currents transport radioactive materials leaked into the sea at Sellafield along the entire coast of Norway and water samples have shown up to tenfold increases in such materials as technetium-99.[171] The Norwegian government is also seeking closure of the facility.[172]

Proposal to establish adjacent power station

[edit]

In February 2009, NuGeneration (NuGen), a consortium of GDF Suez, Iberdrola and Scottish and Southern Energy (SSE), announced plans to build a new nuclear power station of up to 3.6 GW capacity adjacent to Sellafield. In October 2009, NuGen purchased an option to acquire land around Sellafield from the NDA for £70 million.[173]

In October 2010, the UK government announced that Sellafield was one of the eight possible sites it considered suitable for future nuclear power stations.[174] In June 2011, the government confirmed the suitability of the site, and hoped an electricity generating company would choose to build a power station near Sellafield at Moorside by 2025.[175] In 2018, this project was terminated when Toshiba decided to close Nugen and withdraw from nuclear power plant construction in the UK.[176]

In June 2020, the UK government along with EDF together with Rolls-Royce announced that Sellafield has been chosen as a site which will house various types of clean nuclear technologies such as EDF's leading EPR reactor together with Rolls-Royce SMR reactors. The site would serve to produce both electricity and clean hydrogen. EDF has stated plans to construct a twin-EPR station similar in design to Hinkley Point C and Sizewell C.[177] The site will house some of the 16 planned 440 Mwe SMRs to be deployed across the UK.[178]

[edit]

Kraftwerk mentions Sellafield in the intro of the 1991 version of the song "Radioactivity" together with Chernobyl, Harrisburg and Hiroshima. On their 2005 live album Kraftwerk preface a live performance of Radioactivity with a vocoder voice announcing: "Sellafield 2 will produce 7.5 tons of plutonium every year. 1.5 kilogram of plutonium make a nuclear bomb. Sellafield 2 will release the same amount of radioactivity into the environment as Chernobyl every 4.5 years. One of these radioactive substances, Krypton 85, will cause death and skin cancer."[179]

The Windscale fire of 1957 at the Sellafield site was the subject of a 1983 documentary by Yorkshire Television, entitled Windscale – the Nuclear Laundry. It alleged that the clusters of leukaemia in children around Windscale were attributable to the radioactive fallout from the fire.[180]

The Windscale fire has also been the subject of three BBC documentaries. The first, shown originally in 1990, was entitled Our Reactor is on Fire, and was part of the Inside Story series.[181] A 30-minute drama-documentary about the incident was then released in 1999 as part of the BBC's Disaster series; the episode was entitled Atomic Inferno – The Windscale Fire and was later released on DVD.[182] During the 50-year anniversary of the incident in 2007, another documentary was released by the BBC entitled Windscale: Britain's Biggest Nuclear Disaster.[183] All three of these documentaries include interviews with key plant workers and Tom Tuohy, the deputy general manager of Windscale at the time of the accident and the man who risked his life to extinguish the flames.

Fallout, a 2006 drama shown on the Irish national TV station RTÉ, based on the false premise that parts of Ireland would need to be evacuated following a serious accident at Sellafield, showed that following the accident there are evacuation riots, societal collapse and widespread health impacts.[184] Dr Ann McGarry, chief executive of the Radiological Protection Institute of Ireland, said: "The scenario envisaged in the programme is not realistic and grossly exaggerates the amount of radioactivity that could reach Ireland. The RPII cannot envisage any realistic scenario that would cause the radiation levels in Ireland to reach the concentrations as what was depicted in the drama".[184] The Radiological Protection Institute of Ireland (RPII) said that "the scenario as depicted in tonight's RTÉ drama, Fallout, could not happen. The RPII, who viewed the drama...has analysed the scenario as depicted and has concluded that it is not possible for such an accident to occur in Sellafield."[185]

A 2015 BBC Four documentary, Britain's Nuclear Secrets: Inside Sellafield, examined the various radiation leaks and incidents that have occurred at Sellafield over the years and the health risks that have arisen as a result.[186]

In 2016, Sellafield featured in an episode of the BBC series Panorama (TV series). The 30-minute documentary documented the many dangerous accidents and incidents that have occurred at the site over the years, and featured interviews with a mysterious whistleblower.[187]

Notable employees

[edit]

See also

[edit]

Notes

[edit]
  1. ^ A 5 MWe experimental reactor at Obninsk in the Soviet Union had been connected to the public supply in 1954, though the main task was to carry out experimental studies, and it was on a small scale.

References

[edit]
  1. ^ NDA draft strategy, August 2020
  2. ^ Sellafield Ltd, annual report 2017-2018, retrieved Sept 2019
  3. ^ Sellafield context plan, published May 2017 by assets.publishing.service.gov.uk, retrieved Sept 2019
  4. ^ Kragh, Helge (1999). Quantum Generations: A History of Physics in the Twentieth Century. Princeton NJ: Princeton University Press. pp. 286. ISBN 978-0-691-09552-3.
  5. ^ a b Sellafield nuclear decommissioning work ‘significantly’ delayed and nearly £1bn over budget, report reveals. Independent, 31 Oct 2018. Archived
  6. ^ a b c d e f Black, Richard (18 March 2011). "Fukushima – disaster or distraction?". BBC News. Archived from the original on 11 April 2020. Retrieved 30 June 2020.
  7. ^ a b c d e Ahlstrom, Dick (8 October 2007). "The unacceptable toll of Britain's nuclear disaster". The Irish Times. Archived from the original on 25 October 2021. Retrieved 15 June 2020.
  8. ^ a b c d e f Highfield, Roger (9 October 2007). "Windscale fire: 'We were too busy to panic'". The Telegraph. Archived from the original on 15 June 2020. Retrieved 15 June 2020.
  9. ^ Ritchie, p. 102
  10. ^ Historic England. "Royal Ordnance Factory Sellafield (1075104)". Research records (formerly PastScape). Retrieved 21 August 2015.
  11. ^ Historic England. "Royal Ordnance Factory Drigg (1075121)". Research records (formerly PastScape). Retrieved 21 August 2015.
  12. ^ Cassidy, Nick, and Patrick Green. 1993. Sellafield: The contaminated legacy. London: Friends of the Earth.
  13. ^ Openshaw, Stan, Steve Carver, and John Fernie. 1989. Britain's nuclear waste: Siting and safety. London: Bellhaven Press.
  14. ^ a b "Sellafield plant safely completes its mission". www.gov.uk. Retrieved 20 July 2022.[title missing]
  15. ^ "Sellafield Ltd". 23 June 2023.
  16. ^ "Processing of Used Nuclear Fuel - World Nuclear Association".
  17. ^ "INTERMEDIATE LEVEL RADIOACTIVE WASTE SUBSTITUTION" (PDF). DTI. Archived from the original (PDF) on 9 December 2006. Retrieved 23 August 2006.
  18. ^ Invernizzi, Diletta Colette; Locatelli, Giorgio; Velenturf, Anne; Love, Peter ED.; Purnell, Phil; Brookes, Naomi J. (1 September 2020). "Developing policies for the end-of-life of energy infrastructure: Coming to terms with the challenges of decommissioning". Energy Policy. 144: 111677. doi:10.1016/j.enpol.2020.111677. hdl:11311/1204791. ISSN 0301-4215.
  19. ^ McKie, Robin (19 April 2009). "Sellafield: the most hazardous place in Europe". The Observer. Archived from the original on 12 November 2019. Retrieved 9 June 2020.
  20. ^ NDA Business Plan 2018–2021, retrieved Sept 2019
  21. ^ "The 2010 UK Radioactive Waste Inventory: Main Report" (PDF). Nuclear Decommissioning Agency/Department of Energy & Climate Change. February 2011. Archived from the original (PDF) on 25 March 2012. Retrieved 22 May 2012.
  22. ^ "Ponds and Silos at Sellafield". GOV.UK. Retrieved 24 January 2023.
  23. ^ a b "Waste removal starts at Sellafield facility". World Nuclear News. 10 June 2002. Retrieved 9 January 2023.
  24. ^ "Sellafield begins waste removal from 70-year-old silo". Nuclear Engineering International. 17 August 2023. Retrieved 24 August 2023.
  25. ^ "NMP Company Profile". Nuclear Management Partners. Archived from the original on 4 August 2010. Retrieved 19 June 2010.
  26. ^ The Guardian, 27 October 2008, MP's anger as state bears cost of any Sellafield disaster Archived 5 March 2017 at the Wayback Machine
  27. ^ "UK to change way Sellafield is managed". World Nuclear News. Archived from the original on 5 July 2015. Retrieved 4 July 2015.
  28. ^ Nuclear Decommissioning Authority – Progress on the Sellafield site: an update (PDF) (Report). National Audit Office. March 2015. Archived (PDF) from the original on 2 April 2015. Retrieved 16 March 2015.
  29. ^ a b "Nuclear Provision: the cost of cleaning up Britain's historic nuclear sites". NDA. 1 September 2016. Archived from the original on 26 February 2017. Retrieved 26 February 2017.
  30. ^ a b c d Annual Report and Accounts 2007/08. NDA, July 2008 (2.6 MB). See table on p. 29.
  31. ^ Nuclear Decommissioning Authority: Strategy, Appendix B, p. 129. March 2016. Via
  32. ^ a b Nuclear Provision: the cost of cleaning up Britain’s historic nuclear sites. NDA, Update 4 July 2019
  33. ^ "Sellafield clean-up cost reaches 67.5bn, says report". BBC. 4 February 2013. Archived from the original on 8 February 2013. Retrieved 19 February 2013.
  34. ^ Terry Macalister (4 February 2013). "Sellafield management sharply criticised by Commons committee". The Guardian. Archived from the original on 8 January 2014. Retrieved 19 February 2013.
  35. ^ Nuclear Decommissioning Authority: Managing risk at Sellafield (PDF). Committee of Public Accounts (Report). House of Commons. 23 January 2013. Archived (PDF) from the original on 4 February 2013. Retrieved 19 February 2013.
  36. ^ Macalister, Terry (4 December 2013). "Sellafield bosses forced to say sorry over £70bn-plus cleanup costs". theguardian.com. Archived from the original on 5 December 2013. Retrieved 5 December 2013.
  37. ^ Gosden, Emily (23 June 2014). "Britain's nuclear clean-up bill soars to £110bn". The Telegraph. Archived from the original on 13 January 2015. Retrieved 13 January 2015.
  38. ^ "UK decommissioning agency lays out plans to 2019". World Nuclear News. 6 January 2016. Archived from the original on 26 February 2017. Retrieved 26 February 2017.
  39. ^ a b c George Coupe (14 May 2004). "Getting to the core issue". The Engineer. Archived from the original on 5 September 2008. Retrieved 23 October 2008.
  40. ^ Sutyagin, Igor (1996). "The Role of Nuclear Weapons And Its Possible Future Missions". NATO. pp. I.3. The Great Britain. Archived from the original on 17 September 2008. Retrieved 23 October 2008.
  41. ^ unattributed (n.d.). "Sellafield Ltd Timeline". Sellafield Ltd. Archived from the original on 5 October 2008. Retrieved 23 October 2008.
  42. ^ F. R. Farmer, J. R. Beattie (1976). Ernest J. Henley, Jeffery Lewins (ed.). "Nuclear Power Reactors and the Evaluation of Population Hazards". Advances in Nuclear Science and Technology. 9. New York: Academic Press: 1–69. ISBN 9781483215662. Archived from the original on 25 October 2021. Retrieved 30 August 2020.
  43. ^ a b Leatherdale, Duncan (4 November 2014). "Windscale Piles: Cockcroft's Follies avoided nuclear disaster". BBC. Archived from the original on 14 August 2015. Retrieved 12 August 2015.
  44. ^ Leatherdale, Duncan (4 November 2014). "Windscale Piles: Cockcroft's Follies avoided nuclear disaster". BBC. Archived from the original on 14 August 2015. Retrieved 12 August 2015.
  45. ^ "Sellafield's oldest nuclear waste being 'repackaged'". BBC. 12 July 2014. Archived from the original on 13 July 2014. Retrieved 13 July 2014.
  46. ^ "Sellafield's oldest nuclear storage pond to be decommissioned". BBC. 12 June 2014. Archived from the original on 13 November 2014. Retrieved 13 July 2014.
  47. ^ "Risk & Hazard Reduction: Pile Fuel Storage Pond". Sellafield Ltd. Archived from the original on 6 July 2015. Retrieved 4 July 2015.
  48. ^ "Additional Information Concerning Underground Nuclear Weapon Test of Reactor-Grade Plutonium". US Department of Energy. June 1994. Archived from the original on 8 August 2014. Retrieved 15 March 2007.
  49. ^ "Reminiscences of an atom pioneer". H.G. Davey, Works General Manager Windscale and Calder Works 1947-1958. Edited, Margaret Gowing, published Ca 1960 UKAEA, Risley, Lancs.
  50. ^ "Reprocessing plant B204". Archived from the original on 24 November 2005. Retrieved 7 January 2006.
  51. ^ "Risk & Hazard Reduction: First Generation Reprocessing Plants". Sellafield Ltd. Archived from the original on 6 July 2015. Retrieved 4 July 2015.
  52. ^ "History of Sellafield". Sellafield Web Page. Archived from the original on 16 July 2011. Retrieved 21 August 2006.
  53. ^ Berkhout, Frans (1997). "The International Civilian Reprocessing Business" (PDF). Energy and Security. Institute for Energy and Environmental Research. Archived (PDF) from the original on 14 December 2015. Retrieved 10 May 2015.
  54. ^ "RWMAC's Advice to Ministers on the Radioactive Waste Implications of Reprocessing". RWMAC. Archived from the original on 19 August 2006. Retrieved 21 August 2006.
  55. ^ Julian Turner (1 May 2014). "Making Sellafield safe: counting the cost of nuclear decommissioning". Power Technology. Retrieved 5 December 2023.
  56. ^ a b Alex Lawson; Anna Isaac (5 December 2023). "'Dirty 30' and its toxic siblings: the most dangerous parts of the Sellafield nuclear site". The Guardian. Retrieved 5 December 2023.
  57. ^ Martin Forwood (July 2008). "The Legacy of Reprocessing in the United Kingdom" (PDF). International Panel on Fissile Materials. p. 24. Retrieved 5 December 2023.
  58. ^ "The cold probe for sampling at Sellafield". Nuclear Engineering International. 22 January 2014. Archived from the original on 22 February 2014. Retrieved 8 February 2014.
  59. ^ "Risk & Hazard Reduction: First Generation Magnox Storage Pond". Sellafield Ltd. Archived from the original on 6 July 2015. Retrieved 4 July 2015.
  60. ^ Le Clere, Stephen (17 August 2012). Magnox Swarf Storage Silo Liquor Effluent Management: Sellafield Site, Cumbria, UK. 14th International Conference on Environmental Remediation and Radioactive Waste Management. Reims, France: American Society of Mechanical Engineers. pp. 67–75. doi:10.1115/ICEM2011-59271. Retrieved 27 September 2022.
  61. ^ "Sellafield Magnox Swarf Storage Silo Liquor Level Management - ITI". Itigroup.co.uk. Retrieved 11 June 2022.
  62. ^ "The Magnox Swarf Storage Silo: Making our most hazardous facility safer". YouTube. 21 June 2019. Retrieved 11 June 2022.
  63. ^ "Loss of liquor from the Magnox Swarf Storage Silo original building primary containment". IAEA. 6 January 2020.
  64. ^ "A step forward for Sellafield's most hazardous building". GOV.UK. Retrieved 24 January 2023.
  65. ^ "Osborne hails UK nuclear deal with China as 'new dawn'". FT. 17 October 2013. Archived from the original on 31 March 2020. Retrieved 25 October 2014. the country that built the first civil nuclear power station
  66. ^ "History of Sellafield". Sellafield Web Page. Archived from the original on 16 July 2011. Retrieved 21 August 2006.
  67. ^ The Atom Joins the Grid. British Pathe. 22 October 1956. Retrieved 5 March 2011.
  68. ^ "Calder Hall Power Station". The Engineer. 5 October 1956. Archived from the original on 3 September 2014. Retrieved 27 October 2013. Brief description, with link to very detailed article.
  69. ^ "The Nuclear Businesses". Archived from the original on 27 September 2007.
  70. ^ "United Kingdom of Great Britain and Northern Ireland: Nuclear Power Reactors". PRIS database. International Atomic Energy Agency. Archived from the original on 28 June 2011. Retrieved 5 March 2011.
  71. ^ a b "nuclear-uk". Archived from the original on 19 July 2009.
  72. ^ "Calder Hall Nuclear Power Station". Engineering Times. Archived from the original on 7 March 2012. Retrieved 19 September 2010.
  73. ^ Peter Hayes. "Should the United States supply light water reactors to Pyongyang?". Nautilus Pacific Research. Archived from the original on 7 March 2006. Retrieved 21 August 2006.
  74. ^ Brown, Paul (14 April 2003). "First nuclear power plant to close". The Guardian. London. Archived from the original on 25 October 2021. Retrieved 21 August 2006.
  75. ^ Decommissioning the world’s first commercial nuclear power station. NDA, 3 Sep 2019. Archived
  76. ^ Feasibility Study with many pictures of Calder Hall: Calder Hall Nuclear Power Station Feasibility Study. NDA/ATKINS, March 2007
  77. ^ "Sellafield towers are demolished". BBC News. 29 September 2007. Archived from the original on 25 October 2021. Retrieved 29 September 2007.
  78. ^ "Project WAGR". Archived from the original on 1 October 2011.
  79. ^ Indictment: Power & Politics in the Construction Industry, David Morrell, Faber & Faber, 1987, ISBN 978-0-571-14985-8
  80. ^ "Windscale Inquiry". BOPCRIS – Unlocking Key British Government Publications. Archived from the original on 12 February 2006. Retrieved 21 August 2006.
  81. ^ "Sellafield reprocessing plant to close by 2010]". The Times. 26 August 2003. Archived from the original on 12 June 2011.
  82. ^ Geoffrey Lean, 'Shambolic' Sellafield in crisis again after damning safety report Archived 17 February 2017 at the Wayback Machine, The Independent, 3 February 2008.
  83. ^ "Reprocessing ceases at UK's Thorp plant". World Nuclear News. 14 November 2018. Archived from the original on 14 November 2018. Retrieved 15 November 2018.
  84. ^ a b c Harrison, Mike (31 December 2014). "Vitrification of High Level Waste in the UK". Procedia Materials Science. 7: 10–15. doi:10.1016/j.mspro.2014.10.003. Archived from the original on 25 October 2021. Retrieved 24 September 2019.
  85. ^ a b c Temperton, James (17 September 2016). "Inside Sellafield: how the UK's most dangerous nuclear site is cleaning up its act". Wired. Archived from the original on 18 October 2019. Retrieved 25 September 2019.
  86. ^ B F Dunnett (30 March 2007). Review of the Development of UK High Level Waste Vitrified Product. Nexia Solutions (Report). Archived from the original on 24 September 2019. Retrieved 24 September 2019.
  87. ^ a b Malcolm Wicks (22 February 2008). "Hansard, Written Answers: Sellafield". Hansard. 22 February 2008 : Column 1034W. Archived from the original on 13 March 2008. Retrieved 12 March 2008.
  88. ^ Geoffrey Lean (9 March 2008). "'Dirty bomb' threat as UK ships plutonium to France". "The Independent. London. Archived from the original on 29 April 2008. Retrieved 12 March 2008.
  89. ^ Geoffrey Lean (9 March 2008). "Minister admits total failure of Sellafield 'MOX' plant". The Independent. London. Archived from the original on 13 April 2008. Retrieved 12 March 2008.
  90. ^ "MOX Fuel Output for Shikoku Electric Power to Begin in March". The Japan Corporate News Network. 29 February 2008. Archived from the original on 5 August 2009. Retrieved 12 March 2008.
  91. ^ Jon Swaine (7 April 2009). "Nuclear recycling plant costs £1.2 billion and still doesn't work". The Daily Telegraph. London. Archived from the original on 11 April 2009. Retrieved 7 April 2009.
  92. ^ "Areva will supply new rod line at Sellafield MOX plant". Nuclear Engineering International. 2 July 2010. Archived from the original on 13 June 2011. Retrieved 6 July 2010.
  93. ^ "Sellafield Mox nuclear fuel plant to close". The Guardian. 3 August 2011. Archived from the original on 19 October 2021. Retrieved 25 October 2021.
  94. ^ "UK MOX plant to close". Nuclear Engineering International. 3 August 2011. Archived from the original on 29 May 2012. Retrieved 3 August 2011.
  95. ^ <http://www.forepoint.co.uk>, Forepoint. "Mox fuel shipment from France to Japan departs – PNTL – Pacific Nuclear Transport Ltd". Archived from the original on 18 October 2013. Retrieved 22 May 2013.
  96. ^ Ben Irons. "Treating a 50-year-old legacy of radioactive sludge waste". Engineer Live. Archived from the original on 26 January 2007. Retrieved 21 August 2006.
  97. ^ Sellafield Site Summary – 2006/07 Lifetime Plan (Rev. A Issue 2). British Nuclear Group (Report). Nuclear Decommissioning Authority. 20 April 2006. Archived from the original on 10 November 2007. Retrieved 16 August 2010.
  98. ^ "delegates focus on use of plutonium". Whitehavennews. 25 June 2014. Archived from the original on 4 December 2013.
  99. ^ "BNF shows its rubbish dump". The Journal. Newcastle upon Tyne, UK: Newcastle Chronicle and Journal Ltd: 18. 25 January 1989.
  100. ^ "British Nuclear Fuels plc's completed acquisition of Fellside Heat and Power Limited" (PDF). OFGEM. March 2002. Archived (PDF) from the original on 19 December 2008. Retrieved 8 December 2008.
  101. ^ "Sellafield Ltd - Fellside combined Heat and Power Plant - Tank demolition". YouTube.
  102. ^ "National Nuclear Laboratory". nnl.co.uk. Archived from the original on 4 October 2021. Retrieved 25 October 2021.
  103. ^ "Site Statistics". NuclearSites Web Site. Archived from the original on 27 September 2007. Retrieved 21 August 2006.
  104. ^ "THE ECONOMY OF CUMBRIA: THE SIGNIFICANCE OF MAJOR EMPLOYERS" (PDF). Centre for Regional Economic Development. Archived from the original (PDF) on 21 February 2007. Retrieved 21 August 2006.
  105. ^ "Nuclear decommissioning at Sellafield". BBC News. Archived from the original on 16 July 2006. Retrieved 21 August 2006.
  106. ^ "Government pledges to safeguard West Cumbria's future". Government News Network. 1 November 2004. GNN ref 104585P.[permanent dead link]
  107. ^ a b "West Cumbria Stakeholder Group Website". wcssg.co.uk. Archived from the original on 26 September 2019. Retrieved 26 September 2019.
  108. ^ a b Rosina Robinson (10 May 2019). "A trip down memory lane". Nuclear Decommissioning Authority. Retrieved 5 December 2023.
  109. ^ James Temperton (17 September 2016). "Inside Sellafield: how the UK's most dangerous nuclear site is cleaning up its act". Wired. Retrieved 5 December 2023.
  110. ^ a b Jenny Barwise (5 March 2019). "Sellafield Visitors' Centre to be demolished". In Cumbria. Retrieved 5 December 2023.
  111. ^ "Science Museum to run BNFL site". Leisure Opportunities. Retrieved 5 December 2023.
  112. ^ G A M Webb (March 2006). "Classification of events with an off-site radiological impact at the Sellafield site between 1950 and 2000, using the International Nuclear Event Scale". Journal of Radiological Protection. 26 (1): 33–49. Bibcode:2006JRP....26...33W. doi:10.1088/0952-4746/26/1/002. PMID 16522943. S2CID 37975977.
  113. ^ C.Michael Hogan. 2011. Irish Sea. eds. P.Saundry & C.Cleveland. Encyclopedia of Earth. National Council for Science and the Environment. Washington DC Archived 2 June 2013 at the Wayback Machine
  114. ^ "Sellafield nuclear reprocessing facility – Greenpeace UK". Archived from the original on 3 March 2016.
  115. ^ http://www.challenger-society.org.uk/node/95 Archived 18 October 2013 at the Wayback Machine The Irish Sea: Not the Most Radioactive Sea in the World.
  116. ^ "Quality Status Report 2000 for the North East-Atlantic (Regional QSR III, Chapter 4 Chemistry, p66" (PDF). OSPAR Commission. Archived from the original (PDF) on 27 September 2007. Retrieved 3 June 2007.
  117. ^ "Technetium-99 Behavior in the Terrestrial Environment – Field Observations and Radiotracer Experiments-" (PDF). Journal of Nuclear and Radiochemical Sciences, Vol. 4, No.1, pp. A1-A8, 2003. Archived from the original (PDF) on 24 July 2006. Retrieved 23 August 2006.
  118. ^ "Report of Ireland on the Implementation of the OSPAR Strategy with regard to Radioactive Substances (June 2001)" (PDF). Department of Environment, Heritage and Local Government. pp. 2 para.9. Archived from the original (PDF) on 30 May 2008. Retrieved 4 April 2008.
  119. ^ "News Release: MINISTERS ANNOUNCE DECISION ON TECHNETIUM-99". Department for Environment, Food and Rural Affairs. Archived from the original on 12 September 2006. Retrieved 23 August 2006.
  120. ^ J D Harrison; et al. "Gut transfer and doses from environmental technetium". J. Radiol. Prot. 21 9-11. Retrieved 23 August 2006.
  121. ^ "44 years of discharges prevented after early end to Sellafield waste programme". Latest News: British Nuclear Group, 26 January 2006. Archived from the original on 20 May 2006. Retrieved 23 August 2006.
  122. ^ "State of the Environment Norway : Releases of caesium-137 from Sellafield". Norwegian Radiation Protection Authority. 20 November 2011. Archived from the original on 26 July 2014. Retrieved 1 September 2013.
  123. ^ Morris, Michael (18 February 1984). "Warnings go up on nuclear site beaches". The Guardian. UK: Guardian Newspapers: 3.
  124. ^ Please add first missing authors to populate metadata. (22 December 1983). "Sellafield". Hansard. Archived from the original on 21 September 2011. Retrieved 17 March 2011.
  125. ^ "Written answers for Friday 5th May 2000". Hansard. Archived from the original on 11 July 2006. Retrieved 21 August 2006.
  126. ^ "Science: Leukaemia and nuclear power stations". New Scientist. Archived from the original on 4 January 2008. Retrieved 21 August 2006.
  127. ^ Morelle, Rebecca (6 October 2007). "Windscale fallout underestimated". BBC News. Archived from the original on 9 August 2017. Retrieved 4 July 2020.
  128. ^ Arnold, Lorna (1995). Windscale 1957: Anatomy of a Nuclear Accident (Second ed.). London: Palgrave Macmillan UK. p. 147. ISBN 9781349240081.
  129. ^ Arnold, Lorna (1995). Windscale 1957: Anatomy of a Nuclear Accident (Second ed.). London: Palgrave Macmillan UK. p. 152. ISBN 9781349240081.
  130. ^ Brown, Paul (26 August 1999). "Windscale's terrible legacy". The Guardian. Archived from the original on 30 June 2020. Retrieved 30 June 2020.
  131. ^ Daniels, J; et al. "Criticality Incident – August 24, 1970" (PDF). International Developments in Criticality Safety: 35–36. Archived (PDF) from the original on 12 April 2020. Retrieved 12 April 2020.
  132. ^ McLaughlin; et al. (2000). A Review of Criticality Accidents. Los Alamos National Laboratory. pp. 43–44.
  133. ^ Significant Incidents in Nuclear Fuel Cycle Facilities (PDF). IAEA. 1996. p. 36. Archived (PDF) from the original on 12 April 2020. Retrieved 12 April 2020.
  134. ^ "European Commission – PRESS RELEASES – Press release – Nuclear safeguards: the Commission imposes binding measures to put an end to an infringement at the Sellafield site in the United Kingdom". Archived from the original on 25 October 2021. Retrieved 25 October 2021.
  135. ^ "Windscale, une passoire nucléaire rebaptisée Sellafield". www.dissident-media.org. Archived from the original on 26 November 2010. Retrieved 12 March 2011.
  136. ^ "B30 Main Points" (PDF). Greenpeace. Archived from the original (PDF) on 7 March 2012. Retrieved 12 March 2011.
  137. ^ BBC. "So what the heck is this Sellafield thing all about?". Archived from the original on 2 October 2018. Retrieved 25 December 2019.
  138. ^ "Plutonium Investigation". www.wise-paris.org. Archived from the original on 26 September 2018. Retrieved 25 October 2021.
  139. ^ John Vidal; Rob Edwards (29 October 2014). "Photographs of Sellafield nuclear plant prompt fears over radioactive risk". The Guardian. Archived from the original on 25 September 2019. Retrieved 25 September 2019.
  140. ^ "Nuclear Development in the United Kingdom". World Nuclear Association. 2016. Retrieved 12 December 2021.
  141. ^ Watts, Jonathan; Paul Brown (15 September 1999). "Japan launches inquiry into BNFL". Guardian Newspapers. p. 9.
  142. ^ Nuclear Installations Inspectorate (18 February 2000). "An Investigation into the Falsification of Pellet Diameter Data in the MOX Demonstration Facility at the BNFL Sellafield Site and the Effect of this on the Safety of MOX Fuel in Use". Archived from the original on 24 September 2006. Retrieved 18 November 2006.
  143. ^ "BNFL ends Japan nuclear row". BBC. 11 July 2000. Archived from the original on 17 July 2004. Retrieved 18 November 2006.
  144. ^ "Safety overhaul at Sellafield". BBC. 17 April 2000. Archived from the original on 18 April 2003. Retrieved 18 November 2006.
  145. ^ "BNFL chief determined to stay despite damning safety report". Daily Telegraph. 19 February 2000. Archived from the original on 20 November 2002. Retrieved 18 November 2006.
  146. ^ Nolan Fell (1 April 2000). "BNFL in crisis". Nuclear Engineering International. Archived from the original on 19 May 2013. Retrieved 17 January 2014.
  147. ^ "Missing plutonium 'just on paper'". BBC News. 17 February 2005. Archived from the original on 25 December 2006. Retrieved 22 August 2006.
  148. ^ Taylor, Andrew (18 February 2005). "Auditors clear BNFL over missing plutonium". Financial Times. Archived from the original on 10 December 2022. Retrieved 27 February 2017.
  149. ^ Brown, Paul (24 March 2000). "Sabotage spurs Swiss to join Sellafield exodus". The Guardian. Archived from the original on 24 September 2019. Retrieved 24 September 2019.
  150. ^ a b Nuclear Directorate. "Thermal Oxide Reprocessing Plant (THORP) leak investigation and consent to restart". Health and Safety Executive. Archived from the original on 8 July 2012. Retrieved 9 June 2012.
  151. ^ "Sellafield organ removal inquiry". BBC News. 18 April 2007. Archived from the original on 5 May 2007. Retrieved 18 May 2007.
  152. ^ Walker, Peter (10 July 2007). "Sellafield body parts scandal". The Guardian. London. Archived from the original on 5 October 2014. Retrieved 25 September 2008.
  153. ^ Doward, Jamie (22 April 2007). "Revealed: UK nuclear tests on workers". The Observer. London. Archived from the original on 31 August 2013. Retrieved 17 November 2010.
  154. ^ a b Michael Redfern (16 November 2010). The Redfern Inquiry into human tissue analysis in UK nuclear facilities (Report). The Stationery Office. ISBN 978-0-10-296618-3. Archived from the original on 21 November 2010. Retrieved 18 November 2010.
  155. ^ Brown, Jonathan (17 November 2010). "How Sellafield 'mutilated' its workers' bodies". The Independent. London. Archived from the original on 29 September 2017. Retrieved 11 September 2017.
  156. ^ Isaac, Anna; Lawson, Alex (4 December 2023). "Sellafield nuclear site hacked by groups linked to Russia and China". The Guardian. ISSN 0261-3077. Retrieved 4 December 2023.
  157. ^ a b Isaac, Anna; Lawson, Alex (5 December 2023). "Revealed: Sellafield nuclear site has leak that could pose risk to public". The Guardian. ISSN 0261-3077. Retrieved 5 December 2023.
  158. ^ Foot, Paul, London Review of Books, "Nuclear Nightmares", August 1988
  159. ^ a b "Sellafield, radiation and childhood cancer – shedding light on cancer clusters near nuclear sites". Cancer Research UK – Science blog. 31 October 2016. Archived from the original on 14 September 2019. Retrieved 26 December 2019.
  160. ^ Stephanie Cooke (2009). In Mortal Hands: A Cautionary History of the Nuclear Age, Black Inc., p. 356.
  161. ^ "COMARE 10th Report: The incidence of childhood cancer around nuclear installations in Great Britain". Committee on Medical Aspects of Radiation in the Environment. Archived from the original on 6 October 2006. Retrieved 25 August 2006.
  162. ^ "Summary of the work of COMARE as published in its first six reports" (PDF). Committee on Medical Aspects of Radiation in the Environment. Archived (PDF) from the original on 26 September 2006. Retrieved 25 August 2006.
  163. ^ Kinlen, LJ (1997). "Infection and childhood leukaemia near nuclear sites". The Lancet. 349 (9066): 1702. doi:10.1016/S0140-6736(05)62679-7. PMID 9186413. S2CID 32746968.
  164. ^ Dickinson, HO; Parker, L (1999). "Quantifying the effect of population mixing on childhood leukaemia risk: the Seascale cluster". British Journal of Cancer. 81 (1): 144–151 [146, 149]. doi:10.1038/sj.bjc.6690664. PMC 2374359. PMID 10487626.
  165. ^ Dummer, T J B (2003). "Adverse pregnancy outcomes around incinerators and crematoria in Cumbria, north west England, 1956–93". J Epidemiol Community Health. 57 (6): 456–461. doi:10.1136/jech.57.6.456. PMC 1732475. PMID 12775795.
  166. ^ Radiological Protection Institute of Ireland | Media | Press releases | Radioactivity released from Wylfa nuclear power plant is extremely low and of no health significance[https://web.archive.org/web/20131017221002/http://www.rpii.ie/Site/Media/Press-Releases/Radioactivity-released-from-Wylfa-nuclear-power-pl.aspx Archived 17 October 2013 at the Wayback Machine
  167. ^ a b "Decision to Discontinue the Future Distribution of Iodine Tablets". www.gov.ie. 3 April 2008. Archived from the original on 25 October 2021. Retrieved 25 October 2021.
  168. ^ "Irish Sellafield appeal ruled illegal". The Guardian. 30 May 2006. Archived from the original on 29 October 2013. Retrieved 27 October 2013.
  169. ^ "Celtic League join call to close down Sellafield". Isle of Man Today. 23 November 2009. Archived from the original on 15 September 2012.
  170. ^ "MANNON/ISLE OF MAN: SELLAFIELD – OPPOSITION RESTATED BY MANX GOVERNMENT". agencebretagnepresse.com. 18 April 2009. Archived from the original on 1 August 2013. Retrieved 12 December 2018.
  171. ^ Brown, Paul (20 December 1997). "Norway fury at UK nuclear waste flood". The Guardian. UK: Guardian Newspapers: 11.
  172. ^ "Norway concerned over reopening of THORP facility at Sellafield". norway.org.uk. Archived from the original on 23 November 2008. Retrieved 8 January 2009.
  173. ^ "Our plans". NuGeneration. Archived from the original on 6 November 2011. Retrieved 15 November 2011.
  174. ^ "Nuclear power: Eight sites identified for future plants". BBC News. BBC. 18 October 2010. Archived from the original on 19 October 2010. Retrieved 18 October 2010.
  175. ^ "New UK nuclear plant sites named". BBC News. BBC. 23 June 2011. Archived from the original on 24 June 2011. Retrieved 23 June 2011.
  176. ^ Theconstruction index.co.uk, pub August 2018. retrieved Sept 2019
  177. ^ "Moorside: Nuclear power schemes proposed for Cumbria site - BBC News". BBC News. July 2020. Retrieved 11 June 2022.
  178. ^ "Nuclear at heart of proposed Moorside clean energy hub : New Nuclear". World Nuclear News. 30 June 2020. Retrieved 11 June 2022.
  179. ^ "Radioactivity video". Minimum-Maximum. Daily Motion. 7 February 2010. Archived from the original on 22 September 2012. Retrieved 22 May 2013.
  180. ^ Arnold, Lorna (1995). Windscale 1957: Anatomy of a Nuclear Accident (Second ed.). London: Palgrave Macmillan UK. pp. 147–8. ISBN 9781349240081.
  181. ^ "Our Reactor Is on Fire (1990)". BFI. BBC TV. Archived from the original on 5 July 2020. Retrieved 4 March 2021.
  182. ^ "Disaster – Series 3". bbcactivevideoforlearning.com. 1999. Archived from the original on 9 March 2012. Retrieved 4 March 2021.
  183. ^ "Windscale – Britain's Biggest Nuclear Disaster". BBC Two. The BBC. Archived from the original on 1 October 2020. Retrieved 4 July 2020.
  184. ^ a b "Irish battle fallout from nuclear TV show". edie.net. Archived from the original on 25 October 2021. Retrieved 25 October 2021.
  185. ^ "RTE's docudrama scenario could not happen according to RPII". Radiological Protection Institute of Ireland. Archived from the original on 15 October 2013. Retrieved 17 October 2013.
  186. ^ "Britain's Nuclear Secrets: Inside Sellafield". BBC Four. The BBC. Archived from the original on 5 July 2020. Retrieved 4 July 2020.
  187. ^ "Sellafield safety concerns uncovered by BBC Panorama". 5 September 2016. Archived from the original on 15 July 2020. Retrieved 14 July 2020.

Sources

[edit]
  • Ritchie, Berry (1997). The Good Builder: The John Laing Story. James & James.

Further reading

[edit]
  1. Sellafield, Erik Martiniussen, Bellona Foundation, December 2003, ISBN 82-92318-08-9
  2. Technetium-99 Behaviour in the Terrestrial Environment – Field Observations and Radiotracer Experiments, Keiko Tagami, Journal of Nuclear and Radiochemical Sciences, Vol. 4, No.1, pp. A1-A8, 2003
  3. The excess of childhood leukaemia near Sellafield: a commentary on the fourth COMARE report, L J Kinlen et al. 1997 J. Radiol. Prot. 17 63–71
[edit]

1957 fire

[edit]

2005 leak

[edit]

Other

[edit]