Ajka alumina plant accident
Spill site and affected localities[1]
LocationAjka, Hungary
Coordinates47°5′19″N 17°29′45″E / 47.08861°N 17.49583°E / 47.08861; 17.49583
Date4 October 2010 (2010-10-04)
Cause
CauseInconclusive
Casualties10 deaths, 406 injured (120 seriously)[2]
OperatorMAL Hungarian Aluminium
Spill characteristics
Volumeca. 1 million m3
(35 million cu. ft.)
Area40 km2 (15 sq mi)

An industrial accident at a caustic waste reservoir chain took place at the Ajkai Timföldgyár alumina plant in Ajka, Veszprém County, in western Hungary.[3][4] On 4 October 2010, at 12:25 CEST (10:25 UTC),[5] the northwestern corner of the dam of reservoir number 10 collapsed, freeing approximately one million cubic metres (35 million cubic feet) of liquid waste from red mud lakes. The mud was released as a 1–2 m (3–7 ft) wave, flooding several nearby localities, including the village of Kolontár[3][4] and the town of Devecser.[3][4][6] Ten people died, and 150 people were injured.[5][6][7][8] About 40 square kilometres (15 sq mi) of land were initially affected. The spill reached the Danube on 7 October 2010.

It was not initially clear how the containment at the reservoir had been breached, although the accident came after a particularly wet summer in Hungary, as in other parts of central Europe.[7] Police have seized documents from the Ajkai Timföldgyár plant, although a spokesman for MAL Hungarian Aluminium (MAL Magyar Alumínium Termelő és Kereskedelmi Zrt.), the company that operates the plant, said the last inspection of the pond had shown "nothing untoward".[7] Hungarian Prime Minister Viktor Orbán stated that the cause of the spill was presumably human error.[9]

Origin of the mud

The red mud involved in the accident is a waste product of the Bayer process, which refines bauxite into a form of aluminium oxide called alumina. The mud primarily contains non-aluminium compounds present in the bauxite ore and left as residues after its refining along with sodium hydroxide used to dissolve aluminium oxide. Iron(III) oxide, the compound from which the red colour originates, is the main component, but it also contains other compounds.[10] The mud, which is highly alkaline when it is first produced, is stored in large open-air ponds; It is thought that there are about 30 million tonnes of red mud stored around the Ajkai Timföldgyár plant.[6] According to a press release by MAL, the mud had the following chemical percentage make-up (which expresses the amounts of different elements, not necessarily the actual solids).[11]

Metal oxidePercentageNotes
Fe2O3 (iron(III) oxide)40–45%Gives the red colour of the mud
Al2O3 (aluminium oxide)10–15%Unextracted aluminium oxide
SiO2 (silicon dioxide)10–15%Present as sodium- or calcium-alumino-silicate
CaO (calcium oxide)  6–10 %See also portlandite
TiO2 (titanium dioxide)  4–5 %Impurity present in bauxite
Na2O (bound sodium oxide)  5–6 %Responsible for the high (alkaline) pH and the chemical burns

Unlike many other mine tailings, red mud does not contain very high levels of heavy metals, although still about seven times the levels in normal soil.[12] Analyses of the mud at Kolontár on behalf of Greenpeace showed levels of chromium 660 mg/kg, arsenic 110 mg/kg and mercury 1.2 mg/kg.[13] The Hungarian government has stated that the mud is "not poisonous",[12] and the Hungarian Academy of Sciences stated that the heavy metal concentrations were not considered dangerous for the environment.[13] In a different news article, the taskforce established to sample the red mud reported high levels of heavy metals in certain samples, but concluded no locations were "dangerously high."[14] The main damage caused by the accident first arose from the high pH of the mud, which was responsible for both severe chemical burns to humans and animals and killing specimens in the rivers and in the contaminated soils. However, after dissipation of acute effects by dilution and progressive carbonation of the sodium hydroxide by CO2 from the air, the chronic toxicity of heavy metal traces is expected to be limited by their low solubility and high sorption under slightly alkaline conditions.

Effects

The wave of mud flooded streets in Kolontár, where seven people were confirmed dead, and Devecser, where the flow was powerful enough to move cars and vans.[6][7] The cause of death of the Kolontár victims has not been formally confirmed; a spokesman for the National Directorate General for Disaster Management (NDGDM, Országos Katasztrófavédelmi Főigazgatóság) said that they had probably drowned.[7] A further six people were still missing 24 hours after the accident.[6]

The NDGDM said that the high-pH mud was considered hazardous and would cause an alkaline reaction on contact if not washed off with clean water.[7] The mayor of Devecser said that 80–90 people had been taken to hospital with chemical burns.[7] Péter Jakabos, a doctor in the hospital in Győr where many of the injured had been taken, said on Magyar Televízió that it might take days for the full extent of any burns to be realised.[6] Magyar Alumínium (MAL) said that the mud was not considered to contain toxic elements according to EU standards.[7] Initial measurements by the NDGDM showed the sludge to be extremely basic, with a pH value of 13.[15]

The waste initially resulted in massive death to wildlife in and around the Marcal river. The spill reached the Danube on 7 October, prompting countries located further down the river (Croatia, Serbia, Romania, Bulgaria) to develop emergency plans in response.[16] The long term effects on sediments in the Tornar and Marcal rivers are considered minor.[17]

On 11 October, the Hungarian government announced that the managing director of MAL had been arrested, to be charged with "criminal negligence leading to a public catastrophe".[18] Also on the 11th, the government took control of MAL, appointing a commissioner to manage the company.[18] The government planned to focus on compensation for the incident, job security, and identifying further locations at risk of accidents.[18]

Containment and cleanup

Apart from the immediate effects of the wave of red mud, there was also concern for a possible contamination of Hungary's waterways. The Torna (Hungarian pronunciation: [ˈtornɒ]) river runs through the affected area, and emergency workers were pouring tonnes of plaster into the waterway to try to bind the sludge and prevent it from continuing downstream.[6] The Torna joins the Marcal (Hungarian pronunciation: [ˈmɒrt͡sɒl]) river at Karakó, in Vas County; the Marcal joins the Rába river just above Győr, in Győr-Moson-Sopron County, while the Rába itself joins the Danube at Győr.

The day after the accident, Environmental State Secretary Zoltán Illés ordered the suspension of the alumina production at the plant and the reconstruction of the dam.[19] The following day, the chairman of the company said in a radio interview that he would like to restart production over the weekend (5–6 days after the Monday accident);[20] the plant reopened on 15 October, with full production expected to resume by the 19th.[21]

The Hungarian government initially estimated that cleanup would take at least a year and cost tens of millions of dollars.[22]

The Hungarian Government activated the EU Civil Protection Mechanism for urgent international assistance at 7:36PM on 7 October.[23] The European Union Monitoring and Information Centre (MIC) communicated the request for expert assistance to the 30 participating countries (27 EU member states, Iceland, Liechtenstein, Norway).[23]

The former director of the MAL plant, Zoltán Bakonyi, and 14 other employees were arrested over charges of negligence, violations of waste management and environmental pollution on 11 October 2010, but were acquitted of all charges in January 2016.[24]

By 12 October 2010, a secondary dam beyond the remainder of the original had been almost entirely completed, after being built to contain additional sludge that was expected to overflow after another portion of the original dam collapsed.[25]

On 13 October, the government nationalized the company, the bill making this possible having been passed by the Parliament one day earlier.[26]

In 2019, a criminal negligence case closed with the conviction of 10 people - managerial staff and employees - who were found guilty for security protocol infractions relating to waste storage and processing.[27]

See also

References

  1. BM Országos Katasztrófavédelmi Főigazgatóság Archived 12 October 2010 at the Wayback Machine (in Hungarian)
  2. Tóth, János I. (2013). "Key actors of the red sludge disaster in Hungary". In Westra, Laura; Taylor, Prue; Michelot, Agnès (eds.). Confronting Ecological and Economic Collapse:: Ecological Integrity for Law, Policy and Human Rights. Routledge. p. 146. ISBN 978-0415825252.
  3. 1 2 3 Day, Matthew (5 October 2010), Hungary threatened by 'ecological catastrophe' as toxic sludge escapes factory, Telegraph (UK)
  4. 1 2 3 Red sludge floods towns in Hungary, Associated Press, 4 October 2010
  5. 1 2 Red mud spill in Veszprém County (in Hungarian), www.index.hu, 5 October 2010
  6. 1 2 3 4 5 6 7 "Hungary declares a state of emergency after sludge disaster", The Guardian, 5 October 2010.
  7. 1 2 3 4 5 6 7 8 Deadly sludge escape kills three in western Hungary, BBC News, 5 October 2010.
  8. Nyolc halott: megtalálták az utolsó eltűnt holttestét is Devecseren Archived 27 October 2010 at the Wayback Machine Hirado.hu, 11 October 2010. 15:34 (in Hungarian)
  9. "Toxic Red Sludge Spill From Hungarian Aluminum Plant 'An Ecological Disaster'", David Gura, NPR, 5 October 2010
  10. Greenwood, Norman N.; Earnshaw, Alan (1984). Chemistry of the Elements. Oxford: Pergamon Press. p. 245. ISBN 978-0-08-022057-4. states, "Typical compositions for industrially used bauxites are Al2O3 40–60%, combined H2O 12–30%, SiO2 free and combined 1–15%, Fe2O3 7–30%, TiO2 3–4%, F, P2O5, V2O5, etc., 0.05–0.2%"
  11. "Announcement of MAL Hungarian Aluminium". MAL. Archived from the original on 9 October 2010. Retrieved 7 October 2010.
  12. 1 2 Redsludge and detoxification, Government of Hungary, retrieved 9 October 2010.
  13. 1 2 "Danube 'neutralising toxic sludge'", The Independent, 8 October 2010.
  14. Enserink, M. (2010). "After red mud flood, scientists try to halt wave of fear and rumors". Science. 330 (6003): 432–433. Bibcode:2010Sci...330..432E. doi:10.1126/science.330.6003.432. ISSN 0036-8075. PMID 20966220. Archived from the original on 30 October 2010. Retrieved 24 October 2010.
  15. "Sludge-hit Hungarian villagers demand compensation", Atlanta Journal-Constitution, 6 October 2010.
  16. "Hungarian chemical sludge spill reaches Danube", BBC, 7 October 2010.
  17. "Hungarian red mud spill did little long-term damage". Retrieved 14 December 2018.
  18. 1 2 3 "Hungary Arrests Official, Citing Role in Red Sludge". The New York Times. 11 October 2010. Retrieved 13 October 2010.
  19. State Secretary Suspends Production (in Hungarian), MTI, 5 October 2010
  20. "Hungary firm wants to restart production after spill". Reuters. 6 October 2010.
  21. "Hungary toxic spill plant reopens as villagers return". BBC News Online. 15 October 2010. Archived from the original on 16 October 2010. Retrieved 16 October 2010.
  22. "Eyewitness: Hungary's toxic spill". BBC. 6 October 2010.
  23. 1 2 "Hungary activates the EU Civil Protection Mechanism and requests technical expertise to combat mud pollution". europa.eu (Press release). European Commission. 8 October 2010. Retrieved 4 October 2018.
  24. "Outrage as plant bosses acquitted over fatal toxic spill in Hungary". The Guardian. 29 January 2016. Retrieved 28 January 2016 via AFP.
  25. "Hungary emergency toxic sludge dam 'almost completed'". BBC News Online. 12 October 2010. Archived from the original on 13 October 2010. Retrieved 13 October 2010.
  26. Company producing catastrophe nationalized in Hungary, actmeadia
  27. "Court convicts 10 after 2010 Hungarian alumina plant toxic sludge leak". 4 February 2019.
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