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Oil shale in Estonia

February 02, 2023

There are two kinds of oil shale in Estonia, both of which are sedimentary rocks laid down during the Ordovician geologic period.[1] Graptolitic argillite is the larger oil shale resource, but, because its organic matter content is relatively low, it is not used industrially. The other is kukersite, which has been mined for more than a hundred years. Kukersite deposits in Estonia account for 1% of global oil shale deposits.[2]

Outcrop of Ordovician kukersite oil shale, northern Estonia

Oil shale (Estonian: põlevkivi; literally: burning rock) has been defined as a strategic energy resource in Estonia[3] and the oil shale industry in Estonia is one of the most developed in the world.[4] Historically, most of mined oil shale was used for electricity generation. Of all the oil shale fired power stations in the world, the two largest are in Estonia.[5] Although its share decreased in the decade to 2022,[6] direct and indirect use of oil shale still generates about half of Estonia's electricity. About half of mined oil shale is used to produce shale oil, a type of synthetic oil extracted from oil shale by pyrolysis, which is sufficient to keep Estonia as the second largest shale oil producer in the world after China. In addition, oil shale and its products are used in Estonia for district heating and as a feedstock material for the cement industry.

In the 18th and 19th centuries, Estonian oil shale was described by several scientists and used as a low-grade fuel. Its use in industry commenced in 1916. Production of shale oil began in 1921 and oil shale was first used to generate electrical power in 1924.[7] Shortly thereafter, systematic research into oil shale and its products began, and in 1938 a department of mining was established at Tallinn Technical University. After World War II, Estonian oil shale gas was used in Saint Petersburg (then called Leningrad) and in northern cities in Estonia as a substitute for natural gas. Increased need for electricity in the north-west of the Soviet Union led to the construction of large oil shale-fired power stations. Oil shale extraction peaked in 1980. Subsequently, the launch of nuclear reactors in Russia, particularly the Leningrad Nuclear Power Station, reduced demand for electricity produced from oil shale, and, along with a post-Soviet restructuring of the industry in the 1990s, led to a decrease in oil shale mining. After decreasing for two decades, oil shale mining started to increase again at the beginning of the 21st century. Most oil-shale fuelled electricity generation is planned to be phased-out by 2030.

The industry continues to have a serious impact on the environment producing ordinary and hazardous waste and greenhouse gas emissions, lowering groundwater levels, altering water circulation, and spoiling water quality. Leachates from waste heaps pollute surface and groundwater. Former and current oil shale mines cover about one percent of Estonia's territory.

Resource

Graptolitic argillite

Main article: Graptolitic argillite
 
A specimen of graptolite argillite containing pyrite (FeS2) from the Türisalu cliff, an outcrop of the Türisalu Formation
 
An isopach map of the Ordovician graptolitic argillite deposits in northern Estonia, indicating thickness in meters

Estonian graptolitic argillite (also known as dictyonema argillite, dictyonema oil shale, dictyonema shale or alum shale) is a marine-type of black shale, belonging to the marinite-type of oil shales.[8][9] Although the name dictyonema argillite is widely used instead of graptolitic argillite, it is now considered a misnomer as the graptolite fossils in the rock, earlier considered dictyonemids, were reclassified during the 1980s as members of the genus Rhabdinopora.[9][10][11]

Graptolitic argillite was formed some 480 million years ago during the Early Ordovician under a marine environment.[12] In mainland Estonia, it occurs at the foot of the North Estonian Klint, ranging from the Pakri Peninsula to Narva in an area covering about 11,000 square kilometres (4,200 sq mi).[12][13] When findings in the western Estonian islands are included, its extent increases to about 12,200 square kilometres (4,700 sq mi).[9] The thickness of the layer varies from less than 0.5 metres (1 ft 8 in) to a maximum of 8 metres (26 ft) in western Estonia, and its depth below the surface varies from 10 to 90 metres (33 to 295 ft).[13]

Resources of graptolitic argillite in Estonia have been estimated at 60–70 billion tonnes.[8][12] Although resources of graptolitic argillite exceed that of kukersite, attempts to use it as an energy source have been unsuccessful due to its low calorific value and high sulfur content.[1][13][14] Its organic content ranges from 10 to 20% and its sulfur content from 2 to 4%. Correspondingly, its calorific value is only 5–8 megajoules per kilogram (MJ/kg; 1,200–1,900 kcal/kg) and its Fischer Assay oil yield is 3–5%.[13] However, the graptolitic argillite resource in Estonia contains a potential 2.1 billion tonnes of oil. In addition, it contains 5.67 million tonnes of uranium – making it one of the main potential sources of uranium in Europe – 16.53 million tonnes of zinc, and 12.76 million tonnes of molybdenum. There is as yet no economical and environmentally friendly technology to extract either the metals or the oil.[14]

Kukersite

Main article: Kukersite
 
Location of kukersite deposits within the Baltic Oil Shale Basin in northern Estonia and Russia

Kukersite is a light-brown marine-type Late Ordovician oil shale formed some 460 million years ago.[15] It was named kuckers by the Baltic German geologist Carl Friedrich Schmidt in the mid-19th century, and kukersite by the Russian paleobotanist Mikhail Zalessky in 1916.[16][17] The name reflects the German name for Kukruse Manor where oil shale samples were obtained.[17][18]

Kukersite deposits in Estonia are the world's second highest-grade oil shale deposits after the Australian torbanite.[19] Its organic content varies from 15% to 55%, averaging over 40%. Correspondingly, its mean calorific value is 15 MJ/kg (3,600 kcal/kg).[19] The conversion ratio of its organic content into usable energy (shale oil and oil shale gas) is between 65 and 67%,[19][20] and its Fischer Assay oil yield is 30 to 47%.[21]

 
Fossils in northern Estonian kukersite

The principal organic component of kukersite is telalginite, which originated from the fossil green alga Gloeocapsomorpha prisca, deposited in a shallow marine basin.[21] Kukersite lies at depths of 7 to 170 metres (23 to 558 ft).[13][20] The most significant kukersite deposits in Estonia – the Estonian and the Tapa – cover about 3,000 to 5,000 square kilometres (1,200 to 1,900 sq mi),[13][22][23] and together with the Leningrad deposit (an extension of the Estonian) form the Baltic Oil Shale Basin.[24][25] The Estonian deposit, which covers about 2,000 square kilometres (770 sq mi), is used industrially. It consists of 23 exploration and mining fields. The Tapa deposit is not accounted as a reserve due to its lower calorific value, which makes its extraction economically inexpedient.[26][27] In northern Estonia there are 50 layers of kukersite; the six lowest of these form a 2.5-to-3-metre (8 ft 2 in to 9 ft 10 in) thick mineable bed.[1] In this area kukersite lies near the surface. To the south and west it lies deeper and its thickness and quality decrease.[27]

According to the International Energy Agency, Estonia's kukersite represents about 1.1% of global and 17% of European oil shale resources.[2] The total kukersite resources in Estonia are estimated to be about 4.8 billion tonnes, including 1.3 billion tonnes of economically proven and probable reserves.[28][29] Economically proven and probable reserves consist of mineable deposits with energy ratings of at least 35 gigajoules per square metre and calorific values of at least 8 MJ/kg, located in areas without environmental restrictions.[27][28][30] Up to 650 million tonnes of economically proven and probable reserves are designated as recoverable.[29]

History

Early history

It is often reported that 18th-century naturalist and explorer Johann Anton Güldenstädt had mentioned a discovery of a "burning rock" near Jõhvi in 1725, but his published travel notes mention neither oil shale nor Estonia.[31] It is also often reported that the earliest documented record of oil shale in Estonia, authored by the Baltic German publicist and linguist August Wilhelm Hupel, dates to 1777. However, this is based on a misinterpretation of the German word Steinöhl (meaning: stone oil), which was used by Hupel but which most likely did not mean oil shale in the context of his publication.[31]

In the second half of the 18th century, the St. Petersburg Free Economic Society started to search for information about combustible minerals which as fuels would replace the decreasing stock of trees in the European part of Russia. As a result of these inquiries, the Society received information about a combustible mineral found at the Kohala Manor near Rakvere. According to the landlord of the Kohala estate, Baron Fabian Reinhold Ungern-Sternberg, the 'burning rock' was discovered at a depth of about ten meters when a spring was opened on the slope of a sandy hump, as it was during the digging of a well some years earlier on the same slope.[31] This discovery was briefly mentioned in a paper prepared by the German chemist Johann Gottlieb Georgi and presented by the Actual State Councillor Anton-Johann Engelhardt at the meeting of the Society in 1789.[17][31][32] The first scientific research into the rock's oil yield, using samples from the Vanamõisa village of the Kohala Manor, was published by Georgi at the Russian Academy of Sciences in 1791.[26][31] In 1838 and 1839, the Baltic German geologist Gregor von Helmersen published a detailed description of the deposits of kukersite in Vanamõisa and graptolitic argillite in Keila-Joa.[33] In 1838 he made a thorough experiment to distil oil from the Vanamõisa oil shale deposit.[33][34][35]

During the 1850s, large-scale works were undertaken in Estonia to transform excessively wet land into land suitable for agriculture; this included the digging of drainage ditches. In the process, previously unknown layers of oil shale were discovered in several locations. In the years 1850–1857, the territory of Estonia was explored by the Baltic German geologist Carl Friedrich Schmidt who studied these findings of oil shale.[17][36] Russian chemist Aleksandr Shamarin, who at the end of the 1860s had studied the composition and properties of oil shale originating from the Kukruse area, concluded it made sense to use oil shale for the production of gas and as a solid fuel. However, he considered shale oil production unprofitable.[17] During the remainder of the 19th century oil shale was used locally as a low-grade fuel only.[37] For example, in the 1870s, Robert von Toll, landlord of the Kukruse Manor, started to use oil shale as a fuel for the manor's distillery.[38] There were failed attempts to use graptolitic argillite as fertilizer in the 19th century. In the beginning of the 20th century, geologist and engineer Carl August von Mickwitz studied self-ignition of graptolitic argillite near Paldiski.[39] At the University of Tartu oil shale geology and chemistry analyses were conducted during the 19th century by Georg Paul Alexander Petzholdt, Alexander Gustav von Schrenk, and Carl Ernst Heinrich Schmidt, among others.[26][37]

Beginning of oil shale industry

 
Historical monument at the location where the first tonnes of oil shale were mined in Pavandu, Kohtla-Järve

Analysis of Estonian oil shale resources and mining possibilities intensified during the early 20th century while Estonia was part of the Russian Empire. Industrial development was under way in Saint Petersburg (known as Petrograd in 1914–24), but regional fuel resources were in short supply. A large shale oil extraction plant for processing Estonian oil shale was proposed in 1910. The outbreak of World War I, coupled with a fuel supply crisis, accelerated the pace of the research.[37]

In June 1916, the Russian geologist Nikolay Pogrebov oversaw mining of the first tonnes of oil shale at Pavandu and delivered it to Saint Petersburg (then Petrograd) Polytechnic Institute for large-scale experiments.[40][41] These events marking the beginning of the Estonian oil shale industry[10] took place more than half a century after an oil shale industry had emerged in Scotland, the leading oil shale industry in 1916, and a decade before the industry emerged in China, which, besides Estonia, is today the other leading oil shale-exploiting country.[42] In 1916 a total of 640–690 tonnes of oil shale were sent to Saint Petersburg for testing. The tests proved that the oil shale was suitable for combustion as a solid fuel and for extraction of oil shale gas and shale oil.[17] Based on these promising results, a plan for oil shale mining in Estonia was presented to the Emperor Nicholas II on 3 January 1917. On 13 February 1917, the Council of Ministers of Russia allocated 1.2 million rubles to purchase land and start mining activities. After the February Revolution, the Russian Provisional Government appointed a special commissioner for oil shale purchasing and stockpiling who began preliminary work for the digging of an oil shale mine at Pavandu, with full-scale construction carried out by about 500 workers, including war prisoners, in the summer of 1917.[17] After the October Revolution, financing ceased and construction stopped.[17] Two private Saint Petersburg firms, established specially for oil shale mining, Böckel & Co. and Mutschnik & Co., which in the fall of 1916 had begun surface mining at Kukruse and Järve, respectively, also terminated their mining activities in 1917.[17][43]

In February 1918, the area surrounding the oil shale basin in northeast Estonia was occupied by German troops. During this occupation, mining activities were carried out at Pavandu by the German company Internationales Baukonsortium (English: International Construction Consortium), including sending oil shale to Germany for research and experimentation. This work used a retort constructed by Julius Pintsch AG, known as a Pintsch generator. In late 1918, German forces left Estonia, by which time no more than a single trainload of oil shale had been mined and sent to Germany.[44]

Developments in interwar Estonia

 
Kohtla-Järve shale oil extraction plant (Esimene Eesti Põlevkivitööstus, 1937. Photo by Carl Sarap)
 
Kohtla shale oil extraction plant (New Consolidated Gold Fields Ltd., 1931)

After Estonia gained independence, the state owned oil shale enterprise, Riigi Põlevkivitööstus (English: Estonian State Oil Shale Industry), was established as a department of the Ministry for Trade and Industry on 24 November 1918. The enterprise, later named Esimene Eesti Põlevkivitööstus (English: First Estonian Oil Shale Industry), was the predecessor of Viru Keemia Grupp, one of the current shale oil producers in Estonia. It took over the existing Pavandu open-pit mine, and opened new mines at Vanamõisa (1919), Kukruse (1920), and Käva (1924).[7][44] Also, several private investors, including investors from abroad, initiated oil shale industries in Estonia by opening mines at Kiviõli (1922), Küttejõu (1925), Ubja (1926), Viivikonna (1936), and Kohtla (1937).[7][45] Pavandu mine was closed in 1927 and Vanamõisa mine was closed in 1931.[45] While in 1918 only 16 tonnes and in 1919 only 9,631 tonnes of oil shale were mined, in 1937 the annual output exceeded one million tonnes. In 1940, the annual output reached 1,891,674 tonnes.[46]

Initially, oil shale was used primarily in the cement industry, but also for firing locomotive furnaces and as a household fuel. The first major industrial consumers of oil shale were cement factories in Kunda and Aseri.[7][47] By 1925, all locomotives in Estonia were powered by oil shale.[48]

Shale oil production started in Estonia in 1921 when Riigi Põlevkivitööstus built 14 experimental oil shale processing retorts in Kohtla-Järve.[7][49] These vertical retorts used the method developed by Julius Pintsch AG that would later evolve into the current Kiviter processing technology.[49] Along with the shale oil extraction plant, an oil shale research laboratory was founded in 1921.[43] Following the experimental retorts, the first commercial shale oil plant was put into operation on 24 December 1924.[50] The German-owned company Eesti Kiviõli (German: Estländische Steinöl, English: Estonian Stone Oil, predecessor of Kiviõli Keemiatööstus), affiliated with G. Scheel & Co. and Mendelssohn & Co., was established in 1922. By the end of the 1930s, it had become the largest shale oil producer in Estonia.[51][52] Around the company's mine and oil plant, the Kiviõli settlement (now town) was formed in the same way as the Küttejõu settlement (now district of Kiviõli) formed around the mine owned by Eesti Küttejõud. In 1924, the British investor-owned Estonian Oil Development Syndicate Ltd. (later Vanamõisa Oilfields Ltd.) purchased an open-pit mine in Vanamõisa and opened a shale oil extraction plant that was abandoned in 1931 due to technical problems.[1][49][53] The Swedish–Norwegian consortium Eestimaa Õlikonsortsium (Swedish: Estländska Oljeskifferkonsortiet, English: Estonian Oil Consortium), controlled by Marcus Wallenberg, was founded in Sillamäe in 1926.[53][54] New Consolidated Gold Fields Ltd. of the United Kingdom built a shale oil extraction plant at Kohtla-Nõmme in 1931.[7][49] This facility continued to operate until 1961.[7]

In 1934, Eesti Kiviõli and New Consolidated Gold Fields established the service station chain Trustivapaa Bensiini (now: Teboil) in Finland, which in 1940 sold more shale-oil-derived gasoline in Finland than did the entire conventional gasoline market in Estonia.[55] Since 1935, Estonian shale oil has been supplied to the German Kriegsmarine as a ship fuel.[51][56] In 1938, 45% of Estonian shale oil was exported, accounting for 8% of Estonia's total exports.[57] Although the price of oil shale-based gasoline was at least triple that of global gasoline prices, high production and bilateral agreements with Germany facilitated its export.[55] In 1939, Estonia produced 181,000 tonnes of shale oil, including 22,500 tonnes of oil that were suitable gasoline equivalents. The mining and oil industry employed 6,150 persons.[51]

The oil shale-fired electrical power industry started in 1924 when the Tallinn Power Station switched to oil shale.[22] In 1933, it reached a capacity of 22 megawatts (MW). Other oil shale-fired power stations were built in Püssi (3.7 MW), Kohtla (3.7 MW), Kunda (2.3 MW), and Kiviõli (0.8 MW). At the beginning of World War II, the total capacity of oil shale-fired power stations was 32.5 MW.[7] Only the Tallinn and Püssi power stations were connected to the grid.[58]

On 9 May 1922 the first international discussion of Estonian kukersite took place at the 64th meeting of the Institution of Petroleum Technologists.[40] Systematic research into oil shale and its products began at Tartu University's Oil Shale Research Laboratory in 1925, initiated by professor Paul Kogerman.[34][59] In 1937, the Geological Committee under the Ministry of Economic Affairs, and the Institute of Natural Resources, an independent academic institution, were established. A department of mining was established at Tallinn Technical University in 1938.[40] Estonian oil shale industries conducted tests of oil shale samples from Australia, Bulgaria, Germany and South Africa.[60]

Developments in German-occupied Estonia

Soon after the Soviet occupation in 1940, the entire oil shale industry was nationalised and subordinated to the Mining Office and later to the General Directorate of Mining and Fuel Industry of the Peoples' Commissariat for Light Industry.[61] Germany invaded the Soviet Union in 1941 and the industry's infrastructure was largely destroyed by retreating Soviet forces.[51] During the subsequent German occupation, the industry was merged into a company named Baltische Öl GmbH.[51][61] Baltische Öl became the largest industry in the Estonian territory.[62] This entity was subordinated to Kontinentale Öl, a company that had exclusive rights to oil production in German-occupied territories.[51][61]

The primary purpose of the industry was production of oil for the German Army.[61] In 1943, after the German troops retreated from the Caspian oil region, Estonian oil shale became increasingly important. On 16 March 1943, Hermann Göring issued a secret order stating that "development and utilisation of Estonian oil shale industry is the most important military-economic task in the territories of the former Baltic states".[63] On 21 June 1943, Reichsführer Heinrich Himmler issued an order to send as many male Jews as possible to the oil shale mining.[63][64]

Baltische Öl consisted of five units (Kiviõli, Küttejõu, Kohtla-Järve, Sillamäe, and Kohtla), all of which were partially restored, previously existing industries. In addition, Baltische Öl started construction of a new mining and shale oil extraction complex in Ahtme, but it never became operational.[51][65] Prisoners of war and forced labour made up about two-thirds of the work force in these units.[51]

While Soviet troops were advancing into Estonia during 1944, about 200 Estonian oil shale specialists were evacuated to Schömberg, Germany, to work at an oil shale industry there, codenamed Operation Desert (Unternehmen Wüste).[59][61] Shale oil extraction plants in Estonia were destroyed and mines were ignited or inundated by the retreating Germans.[51][66] Existing oil shale-fired power stations were also destroyed.[66]

Developments in Soviet Estonia

 
Annual amount of mined oil shale in Estonia (millions of metric tonnes from 1916 to 2019. Source: John R. Dyni,[42] Statistical Office of Estonia; Estonian Oil Shale Industry Yearbook 2019)[67]

In 1945–1946 the mining industry was merged into Eesti Põlevkivi (Russian: Эстонсланец, literally: Estonian Oil Shale; now part of Enefit Power) under the General Directorate of Oil Shale Industry of the USSR (Glavslanets).[68] Shale oil extraction, except the Kiviõli and Kohtla-Nõmme plants, was merged into the Kohtla-Järve shale oil combinate (Russian: Сланцехим, now Viru Keemia Grupp) under the General Directorate of Synthetic Liquid Fuel and Gas of the USSR (Glavgaztopprom). Both organisations were directed from Moscow.[69]

New mines were opened in Ahtme (1948), Jõhvi (No. 2, 1949), Sompa (1949), Tammiku (1951), and in the area between Käva and Sompa (No. 4, 1953).[26] The Küttejõu open-pit mine was closed in 1947 and the Küttejõu underground mine was merged with the Kiviõli mine in 1951.[70] The Ubja mine was closed in 1959.[45] After construction of large oil shale-fired power stations, demand for oil shale increased and consequently new larger mines were constructed: the underground mines Viru (1965) and Estonia (1972) along with the open-pit mines Sirgala (1963), Narva (1970) and Oktoobri (1974; later named Aidu).[26] Correspondingly, several exhausted smaller mines like Kukruse (1967), Käva (1972), No. 2 (1973), No. 4 (1975), and Kiviõli (1987) were closed.[26][71] The Estonia Mine became the largest oil shale mine in the world.[72] Because of the success of oil shale-based power generation, Estonian oil shale mining peaked in 1980 at 31.35 million tonnes, and in the same year power generation peaked at 18.9 TWh.[27][73][74] The industry declined during the subsequent two decades. Demand for electric power generated from oil shale decreased following construction of nuclear power stations in the Russian SFSR, particularly the Leningrad Nuclear Power Station.[73] At the end of 1988, a fire broke out in the Estonia Mine. The largest underground fire in Estonia, it continued for 81 days and caused serious pollution of ground and surface waters.[75]

 
Old shale oil extraction plant in Kohtla-Järve (2009)

The shale oil industry at Kohtla-Järve and Kiviõli was redeveloped. In 1945, the first tunnel kiln was restored, and by the end of the 1940s four tunnel kilns located in Kiviõli and Kohtla-Nõmme had been restored. German prisoners of war contributed most of the labour.[76] Between 1946 and 1963, 13 Kiviter-type retorts were built in Kohtla-Järve and eight in Kiviõli.[7] In 1947, a pilot Galoter retort was built at the Ilmarine engineering plant in Tallinn. This unit, in operation until 1956, was capable of processing 2.5 tonnes of oil shale per day and was used for modelling the next generation of commercial-scale retorts.[77][78] The first Galoter-type commercial-scale pilot retorts were built at Kiviõli in 1953 and 1963 with capacities of 200 and 500 tonnes of oil shale per day, respectively. The first of these retorts closed in 1963 and the second in 1981.[7][77][79][80] The Narva Oil Plant, annexed to the Eesti Power Station and operating two Galoter-type 3,000-tonnes-per day retorts, was commissioned in 1980.[7][80] Started as a pilot plant, the process of converting it to a commercial-scale plant took about 20 years.[79]

In 1948 an oil shale gas plant in Kohtla-Järve became operational, and for several decades the oil shale gas was used as a substitute for natural gas in Saint Petersburg (then known as Leningrad) and in northern Estonian cities.[57][81] It was the first time in history that synthetic gas from oil shale was used in households.[82] To enable delivery of the gas, a 200-kilometre (120 mi) pipeline from Kohtla-Järve to Saint Peterburg was built, followed by a 150-kilometre (93 mi) pipeline from Kohtla-Järve to Tallinn.[81] During the 1950s, unsuccessful tests of oil shale underground gasification were conducted at Kiviõli.[1][83][84] In 1962 and 1963, the conversion of oil shale gas into ammonium was tested; however, for industrial production, oil shale gas was replaced with natural gas.[85] Although this gas had become uneconomical by 1958, production continued and was even expanded.[86] After peaking in 1976 at 597.4 million cubic metres (21.10×10^9 cu ft),[87] oil shale gas production ceased in 1987.[7] In total, 276 generators were operated for the gas production.[7]

 
The Balti Power Station (2007)

In 1949, the 48 MW Kohtla-Järve Power Station – the first power station in the world to use pulverised oil shale at an industrial scale – was commissioned, followed by the 72.5 MW Ahtme Power Station in 1951.[7] To ensure sufficient electricity supply in Estonia, Latvia and north-west Russia, the Balti Power Station (1,430 MW) and the Eesti Power Station (1,610 MW) were built, the former between 1959 and 1971 and the latter between 1969 and 1973.[27] The stations, collectively known as the Narva Power Stations, are the world's two largest oil shale-fired power stations.[27][88] In 1988 Moscow-based authorities planned a third oil shale-fired power station in Narva with a capacity of 2,500 MW, together with a new mine at Kuremäe. The plan, disclosed at the time of the Phosphorite War and the Singing Revolution, met with strong local opposition and was never implemented.[58]

Between 1946 and 1952, uranium compounds were extracted from locally mined graptolitic argillite at the Sillamäe Processing Plant (now: Silmet).[89][90][91] More than 60 tonnes of uranium compounds (corresponding to 22.5 tonnes of elemental uranium) were produced.[9][12] Some sources note that uranium produced in Sillamäe was used for construction of the first Soviet atomic bomb; however, this information is not confirmed by the archive materials.[39]

An oil shale research institute (now a department within Tallinn University of Technology) was founded at Kohtla-Järve in 1958.[92] Preliminary research into oil shale-based chemical production began the same year, exploring the potential for the use of oil shale in bitumen, synthetic construction materials, detergents, synthetic leathers, synthetic fibres, plastics, paints, soaps, glues, and pesticides.[93] Between 1959 and 1985, 5.275 billion cubic metres (186.3×10^9 cu ft) of mineral wool were produced from oil shale coke, a solid residue of oil shale.[94] In 1968, a branch of the Skochinsky Institute of Mining was established in Kohtla-Järve,[40] and in 1984 the scientific-technical journal Oil Shale was founded in Estonia.[34]

Developments in independent Estonia

 
Oil shale cargo train near Ahtme (2007)

In the 1990s, after Estonia regained independence, the country underwent a restructuring of the economy, causing the collapse of a large part of the heavy industry sector. This collapse led to a decrease in the consumption of electricity and thus a decrease in the need for the oil shale that was mined to produce it.[13][57] Electricity and shale oil export to former Soviet markets largely ceased.[13] Due to a decrease in demand, the Tammiku and Sompa mines closed in 1999 and those at Kohtla and Ahtme closed in 2001.[71]

In 1995, state-owned shale oil producers in Kohtla-Järve and Kiviõli were merged into the single company named RAS Kiviter.[95] In 1997, Kiviter was privatized and a year later it declared insolvency. Its factories in Kohtla-Järve and Kiviõli were sold separately and new oil producers – Viru Keemia Grupp and Kiviõli Keemiatööstus – emerged.[13]

In 1995, the Government of Estonia started negotiations with American company NRG Energy to create a joint venture on the basis of the Narva Power Stations, the largest consumer of oil shale in Estonia. As a part of the deal, 51% of the government-owned shares in the oil shale mining company Eesti Põlevkivi was transferred to the Narva Power Stations.[96] The proposed deal with NRG Energy met a strong public and political opposition and was cancelled after NRG Energy failed the deadline to secure financing for the project.[97][98] Consequently, the Government transferred its remained shares in Eesti Põlevkivi to a state-owned company Eesti Energia, a parent company of the Narva Power Stations, and Eesti Põlevkivi became a fully owned subsidiary of Eesti Energia.[99]

Oil shale production started to increase again in the beginning of the 21st century. In 2000, the open-pit mines at Viivikonna, Sirgala and Narva were merged into the single Narva open-pit mine.[100] Since 2003, several new mines were opened: the Põhja-Kiviõli open-pit mine in 2003, the Ubja open-pit mine in 2005, and the Ojamaa underground mine in 2010.[1][45] By 2006, after 90 years of major mining in Estonia, the total amount of mined oil shale reached one billion tonnes.[10][101] The exhausted Aidu open-pit mine was closed in 2012, followed a year later by the Viru underground mine.[102][103]

In 2004, two power units with circulating fluidised bed combustion boilers were put into operation at the Narva Power Stations.[104] Construction of the Auvere Power Station, located next to the existing Eesti Power Station, began in 2012.[105] In the end of 2012, the Ahtme Power Station was closed.

In 2008, Eesti Energia established a joint venture, Enefit Outotec Technology, with the Finnish technology company Outotec. The venture sought to develop and commercialise a modified Galoter process–the Enefit process–that would enhance the existing technology by using circulating fluidised beds.[106] In 2013, Enefit Outotec Technology opened an Enefit testing plant in Frankfurt.[107][108]

Kiviõli Keemiatööstus began to test two Galoter-type retorts in 2006.[1] Eesti Energia opened a new generation Galoter-type plant using Enefit 280 technology in 2012.[109] VKG Oil opened three new Galoter-type oil plants called Petroter correspondingly in December 2009, in October 2014, and in November 2015.[110][111][112]

In 2020, Eesti Energia announced a plan to build additional oil plant by 2023.[113] At the same time, it cancelled a shale oil pre-refinery project developed jointly with Viru Keemia Grupp.[114]

In spring 2021, the government coalition of Estonian Reform Party and Estonian Centre Party put a political target in their coalition agreement to stop oil shale power generation by 2035 and using oil shale in the entire energy sector by 2040 at the latest.[115] Shortly after, Eesti Energia announced it will stop burning oil shale for electricity generation by 2025 and burning oil shale gas by 2030.[116] It will close older type shale oil plants by 2040 while in newer generation shale oil plants oil shale will be replaced with waste plastics.[116] Estonia is negotiating with the European Commission to receive €340 million support from the Just Transition Fund to mitigate the impact of the oil shale industry transition.[117]

Economic impact

See also: Economy of Estonia
 
Põhja-Kiviõli oil shale mine near Kohtla-Järve (2007)

The oil shale industry in Estonia is one of the most developed in the world.[4] The National Development Plan for the Utilisation of Oil Shale 2016–2030 describes oil shale as a strategic resource.[3] Estonia is the only country in the world that uses oil shale as its primary energy source.[118] In 2018, oil shale accounted for 72% of Estonia's total domestic energy production and supplied 73% of Estonia's total primary energy.[119] About 7,300 people (over 1% of the total workforce in Estonia) were employed in the oil shale industry.[120] The state revenue from oil shale production was about €122 million.[121]

Mining

 
Dragline excavator in the Narva open-pit mine (2005)

Estonia has adopted a national development plan that limits the annual mining of oil shale to 20 million tonnes.[67] If mined at this rate, mineable reserves will last for 25–30 years.[29] In 2019, 12.127 million tonnes of oil shale were mined.[67] As of 2021, five oil shale mines are in operation; three are open-pit mines and two are underground mines. The mines are owned by four companies. Several mining companies have applied for permits for opening new mines.[122] Historically, the ratio of underground mining to open-pit mining has been approximately even, but usable deposits close to the surface has become scarcer.[123]

The Estonia underground mine at Väike-Pungerja, operated by Enefit Power, a subsidiary of Eesti Energia, is the largest oil shale mine in the world.[72][124] The other underground mine, operated by privately owned Viru Keemia Grupp, is located at Ojamaa.[125] Both mines use the room and pillar mining method.[1][125] Oil shale mined at Ojamaa is transported to the processing plant by a unique 13-kilometre (8.1 mi) conveyor belt. Although there are similar conveyors in operation in other countries, the one at Ojamaa is an unusually challenging installation since its path contains many curves and sharp turns.[126]

The Narva open-pit mine is operated by Enefit Power, and the Põhja-Kiviõli open-pit mine is operated by privately owned Kiviõli Keemiatööstus. Both mines use highly selective extraction in three layers of seams.[1] The Narva mine uses a technology that involves breaking up both the overburden and the targeted deposits by blasting and then stripping the rock with relatively large-bucket (10–35 cubic metres or 350–1,240 cubic feet) excavators.[1] The company has applied and received a permit to start oil-shale mining in Narva by using underground longwall mining technology.[127] The third open-pit mine, operated by Kunda Nordic Tsement which belongs to German HeidelbergCement group, is located at Ubja.[1]

Enefit Power and VKG Oil plan to open jointly a new mine in Oandu.[122][better source needed]

Oil shale mines in Estonia[45]
Mine Type Opened Closed Owner(s) Coordinates
Pavandu open-pit 1917 1927 Special commissioner (1917)
Internationales Baukonsortium (1918)
Riigi Põlevkivitööstus (1918–1927)
Vanamõisa open-pit 1919 1931 Riigi Põlevkivitööstus (1919–1924)
Estonian Oil Development Syndicate Ltd. (1924–1930)
Vanamõisa Oilfields Ltd. (1930–1931)
Kukruse open-pit 1920 1920 Riigi Põlevkivitööstus
Küttejõu open-pit 1925 1946 Eesti Küttejõud (1925–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1946)
Kukruse underground 1921 1967 Riigi Põlevkivitööstus (1925–1936)
Esimene Eesti Põlevkivitööstus (1936–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1967)
Kiviõli open-pit 1922 1931 Eesti Kiviõli
Ubja underground 1924 1959 Port Kunda (1924–1941)
Punane Kunda (1941)
Port Kunda (1941–1944)
Punane Kunda (1944–1957)
Eesti Põlevkivi (1957–1959)
Käva underground 1924 1972 Riigi Põlevkivitööstus (1924–1936)
Esimene Eesti Põlevkivitööstus (1936–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1972) 		59°22′50″N 27°16′56″E / 59.38056°N 27.28222°E / 59.38056; 27.28222 (Käva Mine)
Käva open-pit 1925 1930 Riigi Põlevkivitööstus 59°21′43″N 27°14′48″E / 59.36194°N 27.24667°E / 59.36194; 27.24667 (Käva2 Mine)
Ubja open-pit 1926 1955 Port Kunda (1941–1944)
Punane Kunda (1944–1955)
Pavandu underground 1925 1927 Riigi Põlevkivitööstus
Kiviõli underground 1929 1987 Eesti Kiviõli (1929–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1987) 		59°21′02″N 26°56′23″E / 59.35056°N 26.93972°E / 59.35056; 26.93972 (Kiviõli Mine)
Küttejõu underground 1933 19511 Eesti Küttejõud (1933–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1951) 		59°20′19″N 26°59′09″E / 59.33861°N 26.98583°E / 59.33861; 26.98583 (Küttejõu Mine)
Viivikonna open-pit 1936 20002 Eestimaa Õlikonsortsium (1936–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–2000) 		59°18′42″N 27°38′10″E / 59.31167°N 27.63611°E / 59.31167; 27.63611 (Viivikonna Mine)
Kohtla open-pit 1937 1959 New Consolidated Gold Fields Ltd. (1937–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1959)
Viivikonna underground 1940 1954 Eestimaa Õlikonsortsium (1940–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1954)
Kohtla underground 1940 1999 New Consolidated Gold Fields Ltd. (1940–1941)
Baltische Öl (1941–1944)
Eesti Põlevkivi (1944–1999) 		59°21′03″N 27°10′23″E / 59.35083°N 27.17306°E / 59.35083; 27.17306 (Kohtla Mine)
Ahtme underground 1948 2001 Eesti Põlevkivi 59°18′37″N 27°28′33″E / 59.31028°N 27.47583°E / 59.31028; 27.47583 (Ahtme Mine)
Sompa underground 1948 1999 Eesti Põlevkivi 59°20′34″N 27°16′16″E / 59.34278°N 27.27111°E / 59.34278; 27.27111 (Sompa Mine)
Sillamäe3 underground 1949 1952 Sillamäe Processing Plant 59°24′21″N 27°43′22″E / 59.40583°N 27.72278°E / 59.40583; 27.72278 (Sillamäe Mine)
Mine No. 2 underground 1949 1973 Eesti Põlevkivi 59°21′31″N 27°23′01″E / 59.35861°N 27.38361°E / 59.35861; 27.38361 (Mine No. 2)
Tammiku underground 1951 1999 Eesti Põlevkivi 59°20′18″N 27°23′37″E / 59.33833°N 27.39361°E / 59.33833; 27.39361 (Tammiku Mine)
Mine No. 4 underground 1953 1975 Eesti Põlevkivi 59°20′27″N 27°16′30″E / 59.34083°N 27.27500°E / 59.34083; 27.27500 (Mine No. 4)
Sirgala open-pit 1962 20002 Eesti Põlevkivi 59°16′53″N 27°42′57″E / 59.28139°N 27.71583°E / 59.28139; 27.71583 (Sirgala Mine)
Viru underground 1965 2012 Eesti Põlevkivi (1965–2009)
Enefit Kaevandused (2009–2012) 		59°17′46″N 27°21′35″E / 59.29611°N 27.35972°E / 59.29611; 27.35972 (Viru Mine)
Narva open-pit 1970 ...4 Eesti Põlevkivi (1970–2009)
Enefit Kaevandused (2009–2021)
Enefit Power (2021–...) 		59°14′41″N 27°49′52″E / 59.24472°N 27.83111°E / 59.24472; 27.83111 (Narva Mine)
Estonia underground 1972 ...4 Eesti Põlevkivi (1972–2009)
Enefit Kaevandused (2009–2021)
Enefit Power (2021–...) 		59°12′16″N 27°23′11″E / 59.20444°N 27.38639°E / 59.20444; 27.38639 (Estonia Mine)
Aidu open-pit 1974 2012 Eesti Põlevkivi (1974–2009)
Enefit Kaevandused (2009–2012) 		59°19′17″N 27°06′04″E / 59.32139°N 27.10111°E / 59.32139; 27.10111 (Aidu Mine)
Põhja-Kiviõli open-pit 2004 ...4 Kiviõli Keemiatööstus 59°22′41″N 26°50′47″E / 59.37806°N 26.84639°E / 59.37806; 26.84639 (Põhja-Kiviõli Mine)
Ubja (new mine) open-pit 2005 ...4 Kunda Nordic Tsement 59°25′28″N 26°25′42″E / 59.42444°N 26.42833°E / 59.42444; 26.42833 (Ubja Mine)
Ojamaa underground 2010 ...4 Viru Keemia Grupp 59°17′51″N 27°09′39″E / 59.29750°N 27.16083°E / 59.29750; 27.16083 (Ojamaa Mine)
Notes:
  1. Merged into the Kiviõli underground mine
  2. Merged into the Narva open-pit
  3. Mining of graptolitic argillite
  4. Not closed, still operating

Electricity and heat generation

See also: Narva Power Plants
 
Eesti Power Station (2004)

In 2020, 2,225 GWh or 40.3% of Estonia's electricity was generated from oil shale and 748 GWh or 13.6% was generated from oil shale gas, which is a by-product of the shale oil generation.[128] The share of oil shale in Estonia's electricity generation has decreased significantly over the last decade,[129] and it is set to decrease even more due to the European Union's climate policy as well as the country's recognition of the environmental impact of oil shale-fired power stations and need to diversify the national energy balance.[130] According to the International Energy Agency, Estonia should adopt the energy strategy in order to reduce the share of oil shale in the primary energy supply by improving the efficiency of shale-fired power stations and increasing the use of other energy sources such as renewable energy.[131]

Eesti Energia owns the largest oil shale-fuelled power stations (Narva Power Stations) in the world.[132][unreliable source?][5] The increased carbon price has made oil-shale electricity less competitive and will affect it even more in the future.[133] In June 2021, Eesti Energia announced it will stop burning oil shale for electricity generation by 2025 and burning oil shale gas by 2030.[116] The government coalition of Estonia has decided that Estonia will stop oil shale power generation by 2035 at the latest.[117]

Heat produced by co-generation at the Balti Power Station is used for district heating of Narva, the third largest city in Estonia with 58,700 inhabitants (2013).[134] The co-generation plants in Kohtla-Järve, Sillamäe, and Kiviõli burn oil shale to produce electrical power and supply district heating to nearby towns.[135] In addition to raw oil shale, the Kohtla-Järve Power Station uses oil shale gas, a by-product of shale oil production, for the same purposes.[136]

Grid connected oil shale-fired power stations in Estonia[7][58][137]
Power station Opened Closed Max. installed
electrical capacity
(MWe) 		Owner(s) Coordinates
Tallinn 19241 19652 24 Tallinn City Council (1913–1941)
Reichskommissariat Ostland (1942–1944)
Eesti Energia (1945–1979) 		59°26′40″N 24°45′02″E / 59.44444°N 24.75056°E / 59.44444; 24.75056 (Tallinn Power Plant)
Püssi 1937 1973 3.8 Virumaa Elektri AS (VEAS, 1937−1941)
Reichskommissariat Ostland (1942–1944)
Eesti Energia (1945–1973) 		59°21′31″N 27°02′05″E / 59.35861°N 27.03472°E / 59.35861; 27.03472 (Püssi Power Plant)
Kohtla-Järve3 1949 ...4 48 Eesti Energia (1949–1996)
Kohtla-Järve Soojus (1996–2011)
VKG Energia (2011–...) 		59°23′45″N 27°14′31″E / 59.39583°N 27.24194°E / 59.39583; 27.24194 (Kohtla-Järve Power Plant)
Ahtme 1951 2012 72.5 Eesti Energia (1949–1996)
Kohtla-Järve Soojus (1996–2011)
VKG Energia (2011–2012) 		59°18′50″N 27°27′52″E / 59.31389°N 27.46444°E / 59.31389; 27.46444 (Ahtme Power Plant)
Sillamäe5 19531 ...4 18 Sillamäe Processing Plant (1948–1990)
Silmet (1990–1997)
Sillamäe SEJ (1997–...) 		59°24′13″N 27°44′41″E / 59.40361°N 27.74472°E / 59.40361; 27.74472 (Sillamäe Power Plant)
Kiviõli 1959 ...4 10 Kiviõli Keemiatööstus (1944–1995)
Kiviter (1995–1999)
Kiviõli Keemiatööstus (1999–...) 		59°21′13″N 26°56′16″E / 59.35361°N 26.93778°E / 59.35361; 26.93778 (Kiviõli Power Plant)
Balti 1959 ...4 1,430 Eesti Energia 59°21′12″N 28°07′22″E / 59.35333°N 28.12278°E / 59.35333; 28.12278 (Balti Power Plant)
Eesti 1969 ...4 1,610 Eesti Energia 59°16′10″N 27°54′08″E / 59.26944°N 27.90222°E / 59.26944; 27.90222 (Eesti Power Plant)
Auvere 20156 ...4 300 Eesti Energia 59°16′47″N 27°54′04″E / 59.27972°N 27.90111°E / 59.27972; 27.90111 (Auvere Power Plant)
Notes:
  1. Usage of oil shale started
  2. Usage of oil shale ended
  3. Uses oil shale and oil shale gas
  4. Not closed, still operating
  5. Uses natural gas in addition to oil shale
  6. Test production, commissioned in 2018

Shale oil extraction

See also: Narva Oil Plant

In 2008, Estonia was the second largest shale oil producer in the world after China.[138] Production was 1.173 million tonnes of shale oil in 2019.[139] About 99% of shale oil production was exported.[139] In 2018, 34% of the mined oil shale was used for shale oil production.[129]

There are three shale-oil producers in Estonia. In 2019, VKG Oil (a subsidiary of Viru Keemia Grupp) produced 637,000 tonnes of shale oil, Enefit Power (a subsidiary of Eesti Energia) produced 442,000 tonnes, and Kiviõli Keemiatööstus (a subsidiary of Alexela Energia) produced 94,000 tonnes.[139] Two processes – the Kiviter process and the Galoter process – are in use for shale oil extraction.[1][84][140] Enefit uses the Galoter process while VKG Oil and Kiviõli Keemiatööstus use both – Kiviter and Galoter processes.[140]

Shale oil extraction plants in Estonia[1]
Plant Opened Closed Technology Owner(s)
Kohtla-Järve 1921 ...1 Pintsch's generator/Kiviter retor (1921–...)1
Tunnel oven (1955–1968)
Chamber retort (1947–1987)
Galoter retort (2009–...)1		 Riigi Põlevkivitööstus (1918–1927)
Esimene Eesti Põlevkivitööstus (1936–1941)
Baltische Öl (1941–1944)
Kohtla-Järve Oil Shale Processing Plant (1944–1993)
Kiviter (1993–1999)
VKG Oil (1999–...)
Vanamõisa 1925 1931 Fusion retort Estonian Oil Development Syndicate Ltd. (1925–1930)
Vanamõisa Oilfields Ltd. (1930–1931)
Sillamäe 1928 1944 Tunnel oven Eestimaa Õlikonsortsium (1925–1941)
Baltische Öl (1941–1944)
Kiviõli 1929 ...1 Tunnel oven (1929–1975)
Kiviter retort (1953–...)1
Galoter retort (1953–1981, 2006–...)1		 Eesti Kiviõli (1929–1941)
Baltische Öl (1941–1944)
Kiviõli Keemiatööstus (1944–1995)
Kiviter (1995–1999)
Kiviõli Keemiatööstus (1999–...)
Kohtla 1931 1961 Davidson's retort New Consolidated Gold Fields Ltd. (1931–1941)
Baltische Öl (1941–1944)
Kohtla Oil Shale Combinate (1944–1961)
Narva 1980 ...1 Galoter retort1 Eesti Energia/Eesti Energia Õlitööstus
Note:
  1. Not closed, still operating

The government coalition of Estonia has decided that Estonia will stop shale oil extraction by 2040 at the latest.[117]

Environmental impact

See also: Environmental impact of the oil shale industry
 
Unrehabilitated land at the Aidu open-pit mine (2007)
 
An old semi-coke heap in Kiviõli (2005)

Wastes and land usage

The mining and processing of about one billion tonnes of oil shale in Estonia has created about 360-370 million tonnes of solid waste. Combustion ashes are the largest component (200 million tonnes), followed by mining waste (90 million tonnes) and spent shale (mainly semi-coke, 70–80 million tonnes).[94][141] In addition, approximately 73 million tonnes of graptolitic argillite as overlying deposit were mined and piled in waste heaps in the process of phosphorite–ore mining near Maardu in 1964–1991.[9]

The oil shale waste heaps pose a spontaneous ignition risk due to their remaining organic content.[142] The waste material, particularly semi-coke, contains pollutants including sulphates, heavy metals, and polycyclic aromatic hydrocarbons (PAHs), some of which are toxic and carcinogenic.[143][144]

As a result of decades of mining activity, the topography of the oil shale region has changed; this includes a greater range of altitudes within the mined area.[145] Former and current oil shale mines occupy about 1% of Estonia's territory.[19] About 500 square kilometres (190 sq mi) or 15% of Ida-Viru County's territory is out of use due to open-pit mines and waste landfills; an additional 150 square kilometres (58 sq mi) has sunk or become unstable due to underground mining.[146] Semi-coke heaps near Kohtla-Järve and Kiviõli cover more than 180–200 hectares (440–490 acres) and ash heaps near Narva cover more than 210 hectares (520 acres).[141] These heaps protruding from the flat landscape are regarded as landmarks and as monuments to the area's industrial heritage.[147]

There is less biodiversity within the mined area; in particular, the reclaimed and reforested areas have less biodiversity than the areas which have undergone a natural succession.[145]

Water usage and pollution

Surface water flows into mines and accumulates along with groundwater. This water must be pumped out in order for mining to proceed. The water that is pumped from the mines and the coolant water used by oil shale-fired power stations combined exceeds 90% of all water used in Estonia.[29] For each cubic meter of oil shale mined in Estonia, 14–18 cubic metres (490–640 cu ft) of water must be pumped from the mines, amounting to about 227 million cubic metres (184,000 acre⋅ft) that are pumped from mines annually. Groundwater comprises 64% of the water pumped from underground mines annually and 24% of that pumped from open-pit mines.[29] This alters both the circulation and quality of the groundwater, lowers groundwater levels, and releases mine water into surface water bodies such as rivers and lakes. Mining activities have contributed to lower water levels in 24 out of the 39 lakes in the Kurtna Lake District.[142] The release of mine water into the environment has changed the natural movement of surface water.[29] As a result of mining activities, groundwater moves towards the excavation cavities. A 220-kilometre (85-square-mile) underground water body that holds over 170 million cubic metres (140,000 acre⋅ft) of water has formed in eight abandoned underground mines: Ahtme, Kohtla, Kukruse, Käva, Sompa, Tammiku, No.2 and No.4.[71][148][149]

The process of pumping water from the mines introduces oxygen via aeration, thereby oxidising the rock's pyrite. Pyrite contains sulfur, and one consequence of its oxidation is the introduction of significant amounts of sulphates into mine water.[142][148] This has had a negative impact on water quality in five lakes in the Kurtna Lake District.[29] In some lakes, sulphate levels have increased tens of times compared to the pre-mining period. Suspended mineral matter in the mine water pumped into these lakes has changed the composition of the lakes' sediments. However, it has been found that this disturbance diminishes over time; studies show that sulphates and iron in mining water decrease to levels that meet drinking water quality standards about five years after mine closure.[148]

The process and waste waters used in shale oil extraction contain phenols, tar, and several other environmentally toxic products.[141][143] Power stations use water as a coolant and for hydraulic transportation of oil shale ash to the ash heaps. Narva power stations use 1,306 million cubic metres (1,059,000 acre⋅ft) of water from the Narva River annually for cooling.[29] For ash transportation, generated oil shale ash is mixed with water at a ratio of 1:20 and the resulted mixture, known as "ash pulp", is pumped to the heaps.[150] Consequently, the transportation water becomes highly alkaline. The total volume of formed alkaline water is 19 million cubic metres (15,000 acre⋅ft).[151]

Another source of water pollution is aqueous leachates from oil shale ash and spent shale. About 800,000 to 1,200,000 cubic metres (650 to 970 acre⋅ft) of toxic leachate from the Narva ash heaps inflows annually to the Narva River and further to the Gulf of Finland.[144] Before the closure of old semi-coke heaps in Kohtla-Järve and Kiviõli, an additional 500,000 cubic metres (410 acre⋅ft) of leachates reached via the Kohtla and Purtse rivers to the Baltic Sea annually.[141] The toxicity of leachate is mainly caused by the alkalinity and sulphides; leachate also includes chlorides, oil products, heavy metals, and PAHs which are carcinogenic.[141][144]

Air emissions

Oil shale-fired power stations pollute air with the fly ash and flue gases like carbon dioxide (CO2), nitrogen oxides (NOx), sulfur dioxide (SO2), and hydrogen chloride (HCl). In addition to Estonia, this pollution also affects Finland and Russia.[152] The industry emits into the atmosphere annually about 200,000 tonnes of fly-ash, including heavy metals, carbonates, alkaline oxides (mainly calcium oxide (CaO)), and harmful organic substances (including PAHs). About 30% of the fly-ash is CaO, a portion of which is neutralised by atmospheric CO2.[142] Alkaline fly ash has raised the pH value of lake and bog water. This has caused the invasion of eutrophic plants in the area of the oil shale industry, leading to the degradation of those waterbodies.[153] Another source of air pollution is the dust that arises during deposition of oil shale ash and semi-coke.[141]

According to a 2001 study, the concentration of particulate matter in the fly-ash is 39.7 mg per cubic metre.[154] The most hazardous particles are those with a diameter of less than 2.5 micrometres (9.8×10−5 in); these particles are associated with an increase in cardiovascular mortality and premature deaths in Estonia.[155]

The combustion of oil shale releases more CO2 into the atmosphere than any other primary fuel.[156][157] Generating 1 MWh of electricity in modern oil shale-fired boilers creates 0.9–1 tonnes of CO2.[158] In 2017, oil-shale related greenhouse gas emissions in Estonia accounted for 12.9 million tonnes or 69.1% of total energy-related emissions. Of the all energy-related CO2 emissions, heat and power generation accounted for 76%.[159] According to the OECD, CO2 emissions in Estonia could be reduced by two-thirds if oil shale would be used for production of lighter oil products, instead of burning to generate electricity.[160]

Mitigation

Various efforts have reduced the industry's environmental impact. Fluidised bed combustion generates fewer NOx, SO2, and fly-ash emissions, including PAHs, than the earlier technologies that burned pulverised oil shale.[151][158] Reclamation and reforestation of exhausted mining areas have been carried out since the 1970s.[161] In 2010–2013, a €38 million project was implemented for the environmentally safe closing of 86 hectares (210 acres) of semi-coke and ash heaps.[146] In accordance with a European Union waste framework directive, the heaps were covered with waterproof material, new topsoil, and sod.[162] In Kiviõli, a 90-metre (300 ft) semi-coke heap, the highest artificial hill in the Baltic countries, was converted into a ski centre.[163] The former Aidu open-pit mine was converted into a rowing course.[164] A part of the former Sirgala open pit mine has been used as a military training area.[145]

An oil shale sector health impact study conducted in 2014–2015 show that the residents of the region complained significantly more frequently about tightness, long-term cough, phlegm in the lungs, wheezing and cardiovascular diseases, hypertension, stroke, diabetes and stenocardia.[165] The study also shows that the rate of lung cancer among men in the region was higher compared to the Estonian average.[166]

See also

References

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External links

  •   Media related to Oil shale in Estonia at Wikimedia Commons
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February 02, 2023
shale, estonia, there, kinds, shale, estonia, both, which, sedimentary, rocks, laid, down, during, ordovician, geologic, period, graptolitic, argillite, larger, shale, resource, because, organic, matter, content, relatively, used, industrially, other, kukersit. There are two kinds of oil shale in Estonia both of which are sedimentary rocks laid down during the Ordovician geologic period 1 Graptolitic argillite is the larger oil shale resource but because its organic matter content is relatively low it is not used industrially The other is kukersite which has been mined for more than a hundred years Kukersite deposits in Estonia account for 1 of global oil shale deposits 2 Outcrop of Ordovician kukersite oil shale northern Estonia Oil shale Estonian polevkivi literally burning rock has been defined as a strategic energy resource in Estonia 3 and the oil shale industry in Estonia is one of the most developed in the world 4 Historically most of mined oil shale was used for electricity generation Of all the oil shale fired power stations in the world the two largest are in Estonia 5 Although its share decreased in the decade to 2022 6 direct and indirect use of oil shale still generates about half of Estonia s electricity About half of mined oil shale is used to produce shale oil a type of synthetic oil extracted from oil shale by pyrolysis which is sufficient to keep Estonia as the second largest shale oil producer in the world after China In addition oil shale and its products are used in Estonia for district heating and as a feedstock material for the cement industry In the 18th and 19th centuries Estonian oil shale was described by several scientists and used as a low grade fuel Its use in industry commenced in 1916 Production of shale oil began in 1921 and oil shale was first used to generate electrical power in 1924 7 Shortly thereafter systematic research into oil shale and its products began and in 1938 a department of mining was established at Tallinn Technical University After World War II Estonian oil shale gas was used in Saint Petersburg then called Leningrad and in northern cities in Estonia as a substitute for natural gas Increased need for electricity in the north west of the Soviet Union led to the construction of large oil shale fired power stations Oil shale extraction peaked in 1980 Subsequently the launch of nuclear reactors in Russia particularly the Leningrad Nuclear Power Station reduced demand for electricity produced from oil shale and along with a post Soviet restructuring of the industry in the 1990s led to a decrease in oil shale mining After decreasing for two decades oil shale mining started to increase again at the beginning of the 21st century Most oil shale fuelled electricity generation is planned to be phased out by 2030 The industry continues to have a serious impact on the environment producing ordinary and hazardous waste and greenhouse gas emissions lowering groundwater levels altering water circulation and spoiling water quality Leachates from waste heaps pollute surface and groundwater Former and current oil shale mines cover about one percent of Estonia s territory Contents 1 Resource 1 1 Graptolitic argillite 1 2 Kukersite 2 History 2 1 Early history 2 2 Beginning of oil shale industry 2 3 Developments in interwar Estonia 2 4 Developments in German occupied Estonia 2 5 Developments in Soviet Estonia 2 6 Developments in independent Estonia 3 Economic impact 3 1 Mining 3 2 Electricity and heat generation 3 3 Shale oil extraction 4 Environmental impact 4 1 Wastes and land usage 4 2 Water usage and pollution 4 3 Air emissions 4 4 Mitigation 5 See also 6 References 7 Bibliography 8 External linksResource EditGraptolitic argillite Edit Main article Graptolitic argillite A specimen of graptolite argillite containing pyrite FeS2 from the Turisalu cliff an outcrop of the Turisalu Formation An isopach map of the Ordovician graptolitic argillite deposits in northern Estonia indicating thickness in meters Estonian graptolitic argillite also known as dictyonema argillite dictyonema oil shale dictyonema shale or alum shale is a marine type of black shale belonging to the marinite type of oil shales 8 9 Although the name dictyonema argillite is widely used instead of graptolitic argillite it is now considered a misnomer as the graptolite fossils in the rock earlier considered dictyonemids were reclassified during the 1980s as members of the genus Rhabdinopora 9 10 11 Graptolitic argillite was formed some 480 million years ago during the Early Ordovician under a marine environment 12 In mainland Estonia it occurs at the foot of the North Estonian Klint ranging from the Pakri Peninsula to Narva in an area covering about 11 000 square kilometres 4 200 sq mi 12 13 When findings in the western Estonian islands are included its extent increases to about 12 200 square kilometres 4 700 sq mi 9 The thickness of the layer varies from less than 0 5 metres 1 ft 8 in to a maximum of 8 metres 26 ft in western Estonia and its depth below the surface varies from 10 to 90 metres 33 to 295 ft 13 Resources of graptolitic argillite in Estonia have been estimated at 60 70 billion tonnes 8 12 Although resources of graptolitic argillite exceed that of kukersite attempts to use it as an energy source have been unsuccessful due to its low calorific value and high sulfur content 1 13 14 Its organic content ranges from 10 to 20 and its sulfur content from 2 to 4 Correspondingly its calorific value is only 5 8 megajoules per kilogram MJ kg 1 200 1 900 kcal kg and its Fischer Assay oil yield is 3 5 13 However the graptolitic argillite resource in Estonia contains a potential 2 1 billion tonnes of oil In addition it contains 5 67 million tonnes of uranium making it one of the main potential sources of uranium in Europe 16 53 million tonnes of zinc and 12 76 million tonnes of molybdenum There is as yet no economical and environmentally friendly technology to extract either the metals or the oil 14 Kukersite Edit Main article Kukersite Location of kukersite deposits within the Baltic Oil Shale Basin in northern Estonia and Russia Kukersite is a light brown marine type Late Ordovician oil shale formed some 460 million years ago 15 It was named kuckers by the Baltic German geologist Carl Friedrich Schmidt in the mid 19th century and kukersite by the Russian paleobotanist Mikhail Zalessky in 1916 16 17 The name reflects the German name for Kukruse Manor where oil shale samples were obtained 17 18 Kukersite deposits in Estonia are the world s second highest grade oil shale deposits after the Australian torbanite 19 Its organic content varies from 15 to 55 averaging over 40 Correspondingly its mean calorific value is 15 MJ kg 3 600 kcal kg 19 The conversion ratio of its organic content into usable energy shale oil and oil shale gas is between 65 and 67 19 20 and its Fischer Assay oil yield is 30 to 47 21 Fossils in northern Estonian kukersite The principal organic component of kukersite is telalginite which originated from the fossil green alga Gloeocapsomorpha prisca deposited in a shallow marine basin 21 Kukersite lies at depths of 7 to 170 metres 23 to 558 ft 13 20 The most significant kukersite deposits in Estonia the Estonian and the Tapa cover about 3 000 to 5 000 square kilometres 1 200 to 1 900 sq mi 13 22 23 and together with the Leningrad deposit an extension of the Estonian form the Baltic Oil Shale Basin 24 25 The Estonian deposit which covers about 2 000 square kilometres 770 sq mi is used industrially It consists of 23 exploration and mining fields The Tapa deposit is not accounted as a reserve due to its lower calorific value which makes its extraction economically inexpedient 26 27 In northern Estonia there are 50 layers of kukersite the six lowest of these form a 2 5 to 3 metre 8 ft 2 in to 9 ft 10 in thick mineable bed 1 In this area kukersite lies near the surface To the south and west it lies deeper and its thickness and quality decrease 27 According to the International Energy Agency Estonia s kukersite represents about 1 1 of global and 17 of European oil shale resources 2 The total kukersite resources in Estonia are estimated to be about 4 8 billion tonnes including 1 3 billion tonnes of economically proven and probable reserves 28 29 Economically proven and probable reserves consist of mineable deposits with energy ratings of at least 35 gigajoules per square metre and calorific values of at least 8 MJ kg located in areas without environmental restrictions 27 28 30 Up to 650 million tonnes of economically proven and probable reserves are designated as recoverable 29 History EditEarly history Edit It is often reported that 18th century naturalist and explorer Johann Anton Guldenstadt had mentioned a discovery of a burning rock near Johvi in 1725 but his published travel notes mention neither oil shale nor Estonia 31 It is also often reported that the earliest documented record of oil shale in Estonia authored by the Baltic German publicist and linguist August Wilhelm Hupel dates to 1777 However this is based on a misinterpretation of the German word Steinohl meaning stone oil which was used by Hupel but which most likely did not mean oil shale in the context of his publication 31 In the second half of the 18th century the St Petersburg Free Economic Society started to search for information about combustible minerals which as fuels would replace the decreasing stock of trees in the European part of Russia As a result of these inquiries the Society received information about a combustible mineral found at the Kohala Manor near Rakvere According to the landlord of the Kohala estate Baron Fabian Reinhold Ungern Sternberg the burning rock was discovered at a depth of about ten meters when a spring was opened on the slope of a sandy hump as it was during the digging of a well some years earlier on the same slope 31 This discovery was briefly mentioned in a paper prepared by the German chemist Johann Gottlieb Georgi and presented by the Actual State Councillor Anton Johann Engelhardt at the meeting of the Society in 1789 17 31 32 The first scientific research into the rock s oil yield using samples from the Vanamoisa village of the Kohala Manor was published by Georgi at the Russian Academy of Sciences in 1791 26 31 In 1838 and 1839 the Baltic German geologist Gregor von Helmersen published a detailed description of the deposits of kukersite in Vanamoisa and graptolitic argillite in Keila Joa 33 In 1838 he made a thorough experiment to distil oil from the Vanamoisa oil shale deposit 33 34 35 During the 1850s large scale works were undertaken in Estonia to transform excessively wet land into land suitable for agriculture this included the digging of drainage ditches In the process previously unknown layers of oil shale were discovered in several locations In the years 1850 1857 the territory of Estonia was explored by the Baltic German geologist Carl Friedrich Schmidt who studied these findings of oil shale 17 36 Russian chemist Aleksandr Shamarin who at the end of the 1860s had studied the composition and properties of oil shale originating from the Kukruse area concluded it made sense to use oil shale for the production of gas and as a solid fuel However he considered shale oil production unprofitable 17 During the remainder of the 19th century oil shale was used locally as a low grade fuel only 37 For example in the 1870s Robert von Toll landlord of the Kukruse Manor started to use oil shale as a fuel for the manor s distillery 38 There were failed attempts to use graptolitic argillite as fertilizer in the 19th century In the beginning of the 20th century geologist and engineer Carl August von Mickwitz studied self ignition of graptolitic argillite near Paldiski 39 At the University of Tartu oil shale geology and chemistry analyses were conducted during the 19th century by Georg Paul Alexander Petzholdt Alexander Gustav von Schrenk and Carl Ernst Heinrich Schmidt among others 26 37 Beginning of oil shale industry Edit Historical monument at the location where the first tonnes of oil shale were mined in Pavandu Kohtla Jarve Analysis of Estonian oil shale resources and mining possibilities intensified during the early 20th century while Estonia was part of the Russian Empire Industrial development was under way in Saint Petersburg known as Petrograd in 1914 24 but regional fuel resources were in short supply A large shale oil extraction plant for processing Estonian oil shale was proposed in 1910 The outbreak of World War I coupled with a fuel supply crisis accelerated the pace of the research 37 In June 1916 the Russian geologist Nikolay Pogrebov oversaw mining of the first tonnes of oil shale at Pavandu and delivered it to Saint Petersburg then Petrograd Polytechnic Institute for large scale experiments 40 41 These events marking the beginning of the Estonian oil shale industry 10 took place more than half a century after an oil shale industry had emerged in Scotland the leading oil shale industry in 1916 and a decade before the industry emerged in China which besides Estonia is today the other leading oil shale exploiting country 42 In 1916 a total of 640 690 tonnes of oil shale were sent to Saint Petersburg for testing The tests proved that the oil shale was suitable for combustion as a solid fuel and for extraction of oil shale gas and shale oil 17 Based on these promising results a plan for oil shale mining in Estonia was presented to the Emperor Nicholas II on 3 January 1917 On 13 February 1917 the Council of Ministers of Russia allocated 1 2 million rubles to purchase land and start mining activities After the February Revolution the Russian Provisional Government appointed a special commissioner for oil shale purchasing and stockpiling who began preliminary work for the digging of an oil shale mine at Pavandu with full scale construction carried out by about 500 workers including war prisoners in the summer of 1917 17 After the October Revolution financing ceased and construction stopped 17 Two private Saint Petersburg firms established specially for oil shale mining Bockel amp Co and Mutschnik amp Co which in the fall of 1916 had begun surface mining at Kukruse and Jarve respectively also terminated their mining activities in 1917 17 43 In February 1918 the area surrounding the oil shale basin in northeast Estonia was occupied by German troops During this occupation mining activities were carried out at Pavandu by the German company Internationales Baukonsortium English International Construction Consortium including sending oil shale to Germany for research and experimentation This work used a retort constructed by Julius Pintsch AG known as a Pintsch generator In late 1918 German forces left Estonia by which time no more than a single trainload of oil shale had been mined and sent to Germany 44 Developments in interwar Estonia Edit Kohtla Jarve shale oil extraction plant Esimene Eesti Polevkivitoostus 1937 Photo by Carl Sarap Kohtla shale oil extraction plant New Consolidated Gold Fields Ltd 1931 After Estonia gained independence the state owned oil shale enterprise Riigi Polevkivitoostus English Estonian State Oil Shale Industry was established as a department of the Ministry for Trade and Industry on 24 November 1918 The enterprise later named Esimene Eesti Polevkivitoostus English First Estonian Oil Shale Industry was the predecessor of Viru Keemia Grupp one of the current shale oil producers in Estonia It took over the existing Pavandu open pit mine and opened new mines at Vanamoisa 1919 Kukruse 1920 and Kava 1924 7 44 Also several private investors including investors from abroad initiated oil shale industries in Estonia by opening mines at Kivioli 1922 Kuttejou 1925 Ubja 1926 Viivikonna 1936 and Kohtla 1937 7 45 Pavandu mine was closed in 1927 and Vanamoisa mine was closed in 1931 45 While in 1918 only 16 tonnes and in 1919 only 9 631 tonnes of oil shale were mined in 1937 the annual output exceeded one million tonnes In 1940 the annual output reached 1 891 674 tonnes 46 Initially oil shale was used primarily in the cement industry but also for firing locomotive furnaces and as a household fuel The first major industrial consumers of oil shale were cement factories in Kunda and Aseri 7 47 By 1925 all locomotives in Estonia were powered by oil shale 48 Shale oil production started in Estonia in 1921 when Riigi Polevkivitoostus built 14 experimental oil shale processing retorts in Kohtla Jarve 7 49 These vertical retorts used the method developed by Julius Pintsch AG that would later evolve into the current Kiviter processing technology 49 Along with the shale oil extraction plant an oil shale research laboratory was founded in 1921 43 Following the experimental retorts the first commercial shale oil plant was put into operation on 24 December 1924 50 The German owned company Eesti Kivioli German Estlandische Steinol English Estonian Stone Oil predecessor of Kivioli Keemiatoostus affiliated with G Scheel amp Co and Mendelssohn amp Co was established in 1922 By the end of the 1930s it had become the largest shale oil producer in Estonia 51 52 Around the company s mine and oil plant the Kivioli settlement now town was formed in the same way as the Kuttejou settlement now district of Kivioli formed around the mine owned by Eesti Kuttejoud In 1924 the British investor owned Estonian Oil Development Syndicate Ltd later Vanamoisa Oilfields Ltd purchased an open pit mine in Vanamoisa and opened a shale oil extraction plant that was abandoned in 1931 due to technical problems 1 49 53 The Swedish Norwegian consortium Eestimaa Olikonsortsium Swedish Estlandska Oljeskifferkonsortiet English Estonian Oil Consortium controlled by Marcus Wallenberg was founded in Sillamae in 1926 53 54 New Consolidated Gold Fields Ltd of the United Kingdom built a shale oil extraction plant at Kohtla Nomme in 1931 7 49 This facility continued to operate until 1961 7 In 1934 Eesti Kivioli and New Consolidated Gold Fields established the service station chain Trustivapaa Bensiini now Teboil in Finland which in 1940 sold more shale oil derived gasoline in Finland than did the entire conventional gasoline market in Estonia 55 Since 1935 Estonian shale oil has been supplied to the German Kriegsmarine as a ship fuel 51 56 In 1938 45 of Estonian shale oil was exported accounting for 8 of Estonia s total exports 57 Although the price of oil shale based gasoline was at least triple that of global gasoline prices high production and bilateral agreements with Germany facilitated its export 55 In 1939 Estonia produced 181 000 tonnes of shale oil including 22 500 tonnes of oil that were suitable gasoline equivalents The mining and oil industry employed 6 150 persons 51 The oil shale fired electrical power industry started in 1924 when the Tallinn Power Station switched to oil shale 22 In 1933 it reached a capacity of 22 megawatts MW Other oil shale fired power stations were built in Pussi 3 7 MW Kohtla 3 7 MW Kunda 2 3 MW and Kivioli 0 8 MW At the beginning of World War II the total capacity of oil shale fired power stations was 32 5 MW 7 Only the Tallinn and Pussi power stations were connected to the grid 58 On 9 May 1922 the first international discussion of Estonian kukersite took place at the 64th meeting of the Institution of Petroleum Technologists 40 Systematic research into oil shale and its products began at Tartu University s Oil Shale Research Laboratory in 1925 initiated by professor Paul Kogerman 34 59 In 1937 the Geological Committee under the Ministry of Economic Affairs and the Institute of Natural Resources an independent academic institution were established A department of mining was established at Tallinn Technical University in 1938 40 Estonian oil shale industries conducted tests of oil shale samples from Australia Bulgaria Germany and South Africa 60 Developments in German occupied Estonia Edit Soon after the Soviet occupation in 1940 the entire oil shale industry was nationalised and subordinated to the Mining Office and later to the General Directorate of Mining and Fuel Industry of the Peoples Commissariat for Light Industry 61 Germany invaded the Soviet Union in 1941 and the industry s infrastructure was largely destroyed by retreating Soviet forces 51 During the subsequent German occupation the industry was merged into a company named Baltische Ol GmbH 51 61 Baltische Ol became the largest industry in the Estonian territory 62 This entity was subordinated to Kontinentale Ol a company that had exclusive rights to oil production in German occupied territories 51 61 The primary purpose of the industry was production of oil for the German Army 61 In 1943 after the German troops retreated from the Caspian oil region Estonian oil shale became increasingly important On 16 March 1943 Hermann Goring issued a secret order stating that development and utilisation of Estonian oil shale industry is the most important military economic task in the territories of the former Baltic states 63 On 21 June 1943 Reichsfuhrer Heinrich Himmler issued an order to send as many male Jews as possible to the oil shale mining 63 64 Baltische Ol consisted of five units Kivioli Kuttejou Kohtla Jarve Sillamae and Kohtla all of which were partially restored previously existing industries In addition Baltische Ol started construction of a new mining and shale oil extraction complex in Ahtme but it never became operational 51 65 Prisoners of war and forced labour made up about two thirds of the work force in these units 51 While Soviet troops were advancing into Estonia during 1944 about 200 Estonian oil shale specialists were evacuated to Schomberg Germany to work at an oil shale industry there codenamed Operation Desert Unternehmen Wuste 59 61 Shale oil extraction plants in Estonia were destroyed and mines were ignited or inundated by the retreating Germans 51 66 Existing oil shale fired power stations were also destroyed 66 Developments in Soviet Estonia Edit Annual amount of mined oil shale in Estonia millions of metric tonnes from 1916 to 2019 Source John R Dyni 42 Statistical Office of Estonia Estonian Oil Shale Industry Yearbook 2019 67 In 1945 1946 the mining industry was merged into Eesti Polevkivi Russian Estonslanec literally Estonian Oil Shale now part of Enefit Power under the General Directorate of Oil Shale Industry of the USSR Glavslanets 68 Shale oil extraction except the Kivioli and Kohtla Nomme plants was merged into the Kohtla Jarve shale oil combinate Russian Slancehim now Viru Keemia Grupp under the General Directorate of Synthetic Liquid Fuel and Gas of the USSR Glavgaztopprom Both organisations were directed from Moscow 69 New mines were opened in Ahtme 1948 Johvi No 2 1949 Sompa 1949 Tammiku 1951 and in the area between Kava and Sompa No 4 1953 26 The Kuttejou open pit mine was closed in 1947 and the Kuttejou underground mine was merged with the Kivioli mine in 1951 70 The Ubja mine was closed in 1959 45 After construction of large oil shale fired power stations demand for oil shale increased and consequently new larger mines were constructed the underground mines Viru 1965 and Estonia 1972 along with the open pit mines Sirgala 1963 Narva 1970 and Oktoobri 1974 later named Aidu 26 Correspondingly several exhausted smaller mines like Kukruse 1967 Kava 1972 No 2 1973 No 4 1975 and Kivioli 1987 were closed 26 71 The Estonia Mine became the largest oil shale mine in the world 72 Because of the success of oil shale based power generation Estonian oil shale mining peaked in 1980 at 31 35 million tonnes and in the same year power generation peaked at 18 9 TWh 27 73 74 The industry declined during the subsequent two decades Demand for electric power generated from oil shale decreased following construction of nuclear power stations in the Russian SFSR particularly the Leningrad Nuclear Power Station 73 At the end of 1988 a fire broke out in the Estonia Mine The largest underground fire in Estonia it continued for 81 days and caused serious pollution of ground and surface waters 75 Old shale oil extraction plant in Kohtla Jarve 2009 The shale oil industry at Kohtla Jarve and Kivioli was redeveloped In 1945 the first tunnel kiln was restored and by the end of the 1940s four tunnel kilns located in Kivioli and Kohtla Nomme had been restored German prisoners of war contributed most of the labour 76 Between 1946 and 1963 13 Kiviter type retorts were built in Kohtla Jarve and eight in Kivioli 7 In 1947 a pilot Galoter retort was built at the Ilmarine engineering plant in Tallinn This unit in operation until 1956 was capable of processing 2 5 tonnes of oil shale per day and was used for modelling the next generation of commercial scale retorts 77 78 The first Galoter type commercial scale pilot retorts were built at Kivioli in 1953 and 1963 with capacities of 200 and 500 tonnes of oil shale per day respectively The first of these retorts closed in 1963 and the second in 1981 7 77 79 80 The Narva Oil Plant annexed to the Eesti Power Station and operating two Galoter type 3 000 tonnes per day retorts was commissioned in 1980 7 80 Started as a pilot plant the process of converting it to a commercial scale plant took about 20 years 79 In 1948 an oil shale gas plant in Kohtla Jarve became operational and for several decades the oil shale gas was used as a substitute for natural gas in Saint Petersburg then known as Leningrad and in northern Estonian cities 57 81 It was the first time in history that synthetic gas from oil shale was used in households 82 To enable delivery of the gas a 200 kilometre 120 mi pipeline from Kohtla Jarve to Saint Peterburg was built followed by a 150 kilometre 93 mi pipeline from Kohtla Jarve to Tallinn 81 During the 1950s unsuccessful tests of oil shale underground gasification were conducted at Kivioli 1 83 84 In 1962 and 1963 the conversion of oil shale gas into ammonium was tested however for industrial production oil shale gas was replaced with natural gas 85 Although this gas had become uneconomical by 1958 production continued and was even expanded 86 After peaking in 1976 at 597 4 million cubic metres 21 10 10 9 cu ft 87 oil shale gas production ceased in 1987 7 In total 276 generators were operated for the gas production 7 The Balti Power Station 2007 In 1949 the 48 MW Kohtla Jarve Power Station the first power station in the world to use pulverised oil shale at an industrial scale was commissioned followed by the 72 5 MW Ahtme Power Station in 1951 7 To ensure sufficient electricity supply in Estonia Latvia and north west Russia the Balti Power Station 1 430 MW and the Eesti Power Station 1 610 MW were built the former between 1959 and 1971 and the latter between 1969 and 1973 27 The stations collectively known as the Narva Power Stations are the world s two largest oil shale fired power stations 27 88 In 1988 Moscow based authorities planned a third oil shale fired power station in Narva with a capacity of 2 500 MW together with a new mine at Kuremae The plan disclosed at the time of the Phosphorite War and the Singing Revolution met with strong local opposition and was never implemented 58 Between 1946 and 1952 uranium compounds were extracted from locally mined graptolitic argillite at the Sillamae Processing Plant now Silmet 89 90 91 More than 60 tonnes of uranium compounds corresponding to 22 5 tonnes of elemental uranium were produced 9 12 Some sources note that uranium produced in Sillamae was used for construction of the first Soviet atomic bomb however this information is not confirmed by the archive materials 39 An oil shale research institute now a department within Tallinn University of Technology was founded at Kohtla Jarve in 1958 92 Preliminary research into oil shale based chemical production began the same year exploring the potential for the use of oil shale in bitumen synthetic construction materials detergents synthetic leathers synthetic fibres plastics paints soaps glues and pesticides 93 Between 1959 and 1985 5 275 billion cubic metres 186 3 10 9 cu ft of mineral wool were produced from oil shale coke a solid residue of oil shale 94 In 1968 a branch of the Skochinsky Institute of Mining was established in Kohtla Jarve 40 and in 1984 the scientific technical journal Oil Shale was founded in Estonia 34 Developments in independent Estonia Edit Oil shale cargo train near Ahtme 2007 In the 1990s after Estonia regained independence the country underwent a restructuring of the economy causing the collapse of a large part of the heavy industry sector This collapse led to a decrease in the consumption of electricity and thus a decrease in the need for the oil shale that was mined to produce it 13 57 Electricity and shale oil export to former Soviet markets largely ceased 13 Due to a decrease in demand the Tammiku and Sompa mines closed in 1999 and those at Kohtla and Ahtme closed in 2001 71 In 1995 state owned shale oil producers in Kohtla Jarve and Kivioli were merged into the single company named RAS Kiviter 95 In 1997 Kiviter was privatized and a year later it declared insolvency Its factories in Kohtla Jarve and Kivioli were sold separately and new oil producers Viru Keemia Grupp and Kivioli Keemiatoostus emerged 13 In 1995 the Government of Estonia started negotiations with American company NRG Energy to create a joint venture on the basis of the Narva Power Stations the largest consumer of oil shale in Estonia As a part of the deal 51 of the government owned shares in the oil shale mining company Eesti Polevkivi was transferred to the Narva Power Stations 96 The proposed deal with NRG Energy met a strong public and political opposition and was cancelled after NRG Energy failed the deadline to secure financing for the project 97 98 Consequently the Government transferred its remained shares in Eesti Polevkivi to a state owned company Eesti Energia a parent company of the Narva Power Stations and Eesti Polevkivi became a fully owned subsidiary of Eesti Energia 99 VKG Energia Oil shale production started to increase again in the beginning of the 21st century In 2000 the open pit mines at Viivikonna Sirgala and Narva were merged into the single Narva open pit mine 100 Since 2003 several new mines were opened the Pohja Kivioli open pit mine in 2003 the Ubja open pit mine in 2005 and the Ojamaa underground mine in 2010 1 45 By 2006 after 90 years of major mining in Estonia the total amount of mined oil shale reached one billion tonnes 10 101 The exhausted Aidu open pit mine was closed in 2012 followed a year later by the Viru underground mine 102 103 In 2004 two power units with circulating fluidised bed combustion boilers were put into operation at the Narva Power Stations 104 Construction of the Auvere Power Station located next to the existing Eesti Power Station began in 2012 105 In the end of 2012 the Ahtme Power Station was closed In 2008 Eesti Energia established a joint venture Enefit Outotec Technology with the Finnish technology company Outotec The venture sought to develop and commercialise a modified Galoter process the Enefit process that would enhance the existing technology by using circulating fluidised beds 106 In 2013 Enefit Outotec Technology opened an Enefit testing plant in Frankfurt 107 108 Kivioli Keemiatoostus began to test two Galoter type retorts in 2006 1 Eesti Energia opened a new generation Galoter type plant using Enefit 280 technology in 2012 109 VKG Oil opened three new Galoter type oil plants called Petroter correspondingly in December 2009 in October 2014 and in November 2015 110 111 112 In 2020 Eesti Energia announced a plan to build additional oil plant by 2023 113 At the same time it cancelled a shale oil pre refinery project developed jointly with Viru Keemia Grupp 114 In spring 2021 the government coalition of Estonian Reform Party and Estonian Centre Party put a political target in their coalition agreement to stop oil shale power generation by 2035 and using oil shale in the entire energy sector by 2040 at the latest 115 Shortly after Eesti Energia announced it will stop burning oil shale for electricity generation by 2025 and burning oil shale gas by 2030 116 It will close older type shale oil plants by 2040 while in newer generation shale oil plants oil shale will be replaced with waste plastics 116 Estonia is negotiating with the European Commission to receive 340 million support from the Just Transition Fund to mitigate the impact of the oil shale industry transition 117 Economic impact EditSee also Economy of Estonia Pohja Kivioli oil shale mine near Kohtla Jarve 2007 The oil shale industry in Estonia is one of the most developed in the world 4 The National Development Plan for the Utilisation of Oil Shale 2016 2030 describes oil shale as a strategic resource 3 Estonia is the only country in the world that uses oil shale as its primary energy source 118 In 2018 oil shale accounted for 72 of Estonia s total domestic energy production and supplied 73 of Estonia s total primary energy 119 About 7 300 people over 1 of the total workforce in Estonia were employed in the oil shale industry 120 The state revenue from oil shale production was about 122 million 121 Mining Edit Dragline excavator in the Narva open pit mine 2005 Estonia has adopted a national development plan that limits the annual mining of oil shale to 20 million tonnes 67 If mined at this rate mineable reserves will last for 25 30 years 29 In 2019 12 127 million tonnes of oil shale were mined 67 As of 2021 five oil shale mines are in operation three are open pit mines and two are underground mines The mines are owned by four companies Several mining companies have applied for permits for opening new mines 122 Historically the ratio of underground mining to open pit mining has been approximately even but usable deposits close to the surface has become scarcer 123 The Estonia underground mine at Vaike Pungerja operated by Enefit Power a subsidiary of Eesti Energia is the largest oil shale mine in the world 72 124 The other underground mine operated by privately owned Viru Keemia Grupp is located at Ojamaa 125 Both mines use the room and pillar mining method 1 125 Oil shale mined at Ojamaa is transported to the processing plant by a unique 13 kilometre 8 1 mi conveyor belt Although there are similar conveyors in operation in other countries the one at Ojamaa is an unusually challenging installation since its path contains many curves and sharp turns 126 The Narva open pit mine is operated by Enefit Power and the Pohja Kivioli open pit mine is operated by privately owned Kivioli Keemiatoostus Both mines use highly selective extraction in three layers of seams 1 The Narva mine uses a technology that involves breaking up both the overburden and the targeted deposits by blasting and then stripping the rock with relatively large bucket 10 35 cubic metres or 350 1 240 cubic feet excavators 1 The company has applied and received a permit to start oil shale mining in Narva by using underground longwall mining technology 127 The third open pit mine operated by Kunda Nordic Tsement which belongs to German HeidelbergCement group is located at Ubja 1 Enefit Power and VKG Oil plan to open jointly a new mine in Oandu 122 better source needed Oil shale mines in Estonia 45 Mine Type Opened Closed Owner s CoordinatesPavandu open pit 1917 1927 Special commissioner 1917 Internationales Baukonsortium 1918 Riigi Polevkivitoostus 1918 1927 Vanamoisa open pit 1919 1931 Riigi Polevkivitoostus 1919 1924 Estonian Oil Development Syndicate Ltd 1924 1930 Vanamoisa Oilfields Ltd 1930 1931 Kukruse open pit 1920 1920 Riigi PolevkivitoostusKuttejou open pit 1925 1946 Eesti Kuttejoud 1925 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1946 Kukruse underground 1921 1967 Riigi Polevkivitoostus 1925 1936 Esimene Eesti Polevkivitoostus 1936 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1967 Kivioli open pit 1922 1931 Eesti KivioliUbja underground 1924 1959 Port Kunda 1924 1941 Punane Kunda 1941 Port Kunda 1941 1944 Punane Kunda 1944 1957 Eesti Polevkivi 1957 1959 Kava underground 1924 1972 Riigi Polevkivitoostus 1924 1936 Esimene Eesti Polevkivitoostus 1936 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1972 59 22 50 N 27 16 56 E 59 38056 N 27 28222 E 59 38056 27 28222 Kava Mine Kava open pit 1925 1930 Riigi Polevkivitoostus 59 21 43 N 27 14 48 E 59 36194 N 27 24667 E 59 36194 27 24667 Kava2 Mine Ubja open pit 1926 1955 Port Kunda 1941 1944 Punane Kunda 1944 1955 Pavandu underground 1925 1927 Riigi PolevkivitoostusKivioli underground 1929 1987 Eesti Kivioli 1929 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1987 59 21 02 N 26 56 23 E 59 35056 N 26 93972 E 59 35056 26 93972 Kivioli Mine Kuttejou underground 1933 19511 Eesti Kuttejoud 1933 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1951 59 20 19 N 26 59 09 E 59 33861 N 26 98583 E 59 33861 26 98583 Kuttejou Mine Viivikonna open pit 1936 20002 Eestimaa Olikonsortsium 1936 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 2000 59 18 42 N 27 38 10 E 59 31167 N 27 63611 E 59 31167 27 63611 Viivikonna Mine Kohtla open pit 1937 1959 New Consolidated Gold Fields Ltd 1937 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1959 Viivikonna underground 1940 1954 Eestimaa Olikonsortsium 1940 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1954 Kohtla underground 1940 1999 New Consolidated Gold Fields Ltd 1940 1941 Baltische Ol 1941 1944 Eesti Polevkivi 1944 1999 59 21 03 N 27 10 23 E 59 35083 N 27 17306 E 59 35083 27 17306 Kohtla Mine Ahtme underground 1948 2001 Eesti Polevkivi 59 18 37 N 27 28 33 E 59 31028 N 27 47583 E 59 31028 27 47583 Ahtme Mine Sompa underground 1948 1999 Eesti Polevkivi 59 20 34 N 27 16 16 E 59 34278 N 27 27111 E 59 34278 27 27111 Sompa Mine Sillamae3 underground 1949 1952 Sillamae Processing Plant 59 24 21 N 27 43 22 E 59 40583 N 27 72278 E 59 40583 27 72278 Sillamae Mine Mine No 2 underground 1949 1973 Eesti Polevkivi 59 21 31 N 27 23 01 E 59 35861 N 27 38361 E 59 35861 27 38361 Mine No 2 Tammiku underground 1951 1999 Eesti Polevkivi 59 20 18 N 27 23 37 E 59 33833 N 27 39361 E 59 33833 27 39361 Tammiku Mine Mine No 4 underground 1953 1975 Eesti Polevkivi 59 20 27 N 27 16 30 E 59 34083 N 27 27500 E 59 34083 27 27500 Mine No 4 Sirgala open pit 1962 20002 Eesti Polevkivi 59 16 53 N 27 42 57 E 59 28139 N 27 71583 E 59 28139 27 71583 Sirgala Mine Viru underground 1965 2012 Eesti Polevkivi 1965 2009 Enefit Kaevandused 2009 2012 59 17 46 N 27 21 35 E 59 29611 N 27 35972 E 59 29611 27 35972 Viru Mine Narva open pit 1970 4 Eesti Polevkivi 1970 2009 Enefit Kaevandused 2009 2021 Enefit Power 2021 59 14 41 N 27 49 52 E 59 24472 N 27 83111 E 59 24472 27 83111 Narva Mine Estonia underground 1972 4 Eesti Polevkivi 1972 2009 Enefit Kaevandused 2009 2021 Enefit Power 2021 59 12 16 N 27 23 11 E 59 20444 N 27 38639 E 59 20444 27 38639 Estonia Mine Aidu open pit 1974 2012 Eesti Polevkivi 1974 2009 Enefit Kaevandused 2009 2012 59 19 17 N 27 06 04 E 59 32139 N 27 10111 E 59 32139 27 10111 Aidu Mine Pohja Kivioli open pit 2004 4 Kivioli Keemiatoostus 59 22 41 N 26 50 47 E 59 37806 N 26 84639 E 59 37806 26 84639 Pohja Kivioli Mine Ubja new mine open pit 2005 4 Kunda Nordic Tsement 59 25 28 N 26 25 42 E 59 42444 N 26 42833 E 59 42444 26 42833 Ubja Mine Ojamaa underground 2010 4 Viru Keemia Grupp 59 17 51 N 27 09 39 E 59 29750 N 27 16083 E 59 29750 27 16083 Ojamaa Mine Notes Merged into the Kivioli underground mine Merged into the Narva open pit Mining of graptolitic argillite Not closed still operatingElectricity and heat generation Edit See also Narva Power Plants Eesti Power Station 2004 In 2020 2 225 GWh or 40 3 of Estonia s electricity was generated from oil shale and 748 GWh or 13 6 was generated from oil shale gas which is a by product of the shale oil generation 128 The share of oil shale in Estonia s electricity generation has decreased significantly over the last decade 129 and it is set to decrease even more due to the European Union s climate policy as well as the country s recognition of the environmental impact of oil shale fired power stations and need to diversify the national energy balance 130 According to the International Energy Agency Estonia should adopt the energy strategy in order to reduce the share of oil shale in the primary energy supply by improving the efficiency of shale fired power stations and increasing the use of other energy sources such as renewable energy 131 Eesti Energia owns the largest oil shale fuelled power stations Narva Power Stations in the world 132 unreliable source 5 The increased carbon price has made oil shale electricity less competitive and will affect it even more in the future 133 In June 2021 Eesti Energia announced it will stop burning oil shale for electricity generation by 2025 and burning oil shale gas by 2030 116 The government coalition of Estonia has decided that Estonia will stop oil shale power generation by 2035 at the latest 117 Heat produced by co generation at the Balti Power Station is used for district heating of Narva the third largest city in Estonia with 58 700 inhabitants 2013 134 The co generation plants in Kohtla Jarve Sillamae and Kivioli burn oil shale to produce electrical power and supply district heating to nearby towns 135 In addition to raw oil shale the Kohtla Jarve Power Station uses oil shale gas a by product of shale oil production for the same purposes 136 Grid connected oil shale fired power stations in Estonia 7 58 137 Power station Opened Closed Max installed electrical capacity MWe Owner s CoordinatesTallinn 19241 19652 24 Tallinn City Council 1913 1941 Reichskommissariat Ostland 1942 1944 Eesti Energia 1945 1979 59 26 40 N 24 45 02 E 59 44444 N 24 75056 E 59 44444 24 75056 Tallinn Power Plant Pussi 1937 1973 3 8 Virumaa Elektri AS VEAS 1937 1941 Reichskommissariat Ostland 1942 1944 Eesti Energia 1945 1973 59 21 31 N 27 02 05 E 59 35861 N 27 03472 E 59 35861 27 03472 Pussi Power Plant Kohtla Jarve3 1949 4 48 Eesti Energia 1949 1996 Kohtla Jarve Soojus 1996 2011 VKG Energia 2011 59 23 45 N 27 14 31 E 59 39583 N 27 24194 E 59 39583 27 24194 Kohtla Jarve Power Plant Ahtme 1951 2012 72 5 Eesti Energia 1949 1996 Kohtla Jarve Soojus 1996 2011 VKG Energia 2011 2012 59 18 50 N 27 27 52 E 59 31389 N 27 46444 E 59 31389 27 46444 Ahtme Power Plant Sillamae5 19531 4 18 Sillamae Processing Plant 1948 1990 Silmet 1990 1997 Sillamae SEJ 1997 59 24 13 N 27 44 41 E 59 40361 N 27 74472 E 59 40361 27 74472 Sillamae Power Plant Kivioli 1959 4 10 Kivioli Keemiatoostus 1944 1995 Kiviter 1995 1999 Kivioli Keemiatoostus 1999 59 21 13 N 26 56 16 E 59 35361 N 26 93778 E 59 35361 26 93778 Kivioli Power Plant Balti 1959 4 1 430 Eesti Energia 59 21 12 N 28 07 22 E 59 35333 N 28 12278 E 59 35333 28 12278 Balti Power Plant Eesti 1969 4 1 610 Eesti Energia 59 16 10 N 27 54 08 E 59 26944 N 27 90222 E 59 26944 27 90222 Eesti Power Plant Auvere 20156 4 300 Eesti Energia 59 16 47 N 27 54 04 E 59 27972 N 27 90111 E 59 27972 27 90111 Auvere Power Plant Notes Usage of oil shale started Usage of oil shale ended Uses oil shale and oil shale gas Not closed still operating Uses natural gas in addition to oil shale Test production commissioned in 2018Shale oil extraction Edit See also Narva Oil Plant In 2008 Estonia was the second largest shale oil producer in the world after China 138 Production was 1 173 million tonnes of shale oil in 2019 139 About 99 of shale oil production was exported 139 In 2018 34 of the mined oil shale was used for shale oil production 129 There are three shale oil producers in Estonia In 2019 VKG Oil a subsidiary of Viru Keemia Grupp produced 637 000 tonnes of shale oil Enefit Power a subsidiary of Eesti Energia produced 442 000 tonnes and Kivioli Keemiatoostus a subsidiary of Alexela Energia produced 94 000 tonnes 139 Two processes the Kiviter process and the Galoter process are in use for shale oil extraction 1 84 140 Enefit uses the Galoter process while VKG Oil and Kivioli Keemiatoostus use both Kiviter and Galoter processes 140 Shale oil extraction plants in Estonia 1 Plant Opened Closed Technology Owner s Kohtla Jarve 1921 1 Pintsch s generator Kiviter retor 1921 1Tunnel oven 1955 1968 Chamber retort 1947 1987 Galoter retort 2009 1 Riigi Polevkivitoostus 1918 1927 Esimene Eesti Polevkivitoostus 1936 1941 Baltische Ol 1941 1944 Kohtla Jarve Oil Shale Processing Plant 1944 1993 Kiviter 1993 1999 VKG Oil 1999 Vanamoisa 1925 1931 Fusion retort Estonian Oil Development Syndicate Ltd 1925 1930 Vanamoisa Oilfields Ltd 1930 1931 Sillamae 1928 1944 Tunnel oven Eestimaa Olikonsortsium 1925 1941 Baltische Ol 1941 1944 Kivioli 1929 1 Tunnel oven 1929 1975 Kiviter retort 1953 1Galoter retort 1953 1981 2006 1 Eesti Kivioli 1929 1941 Baltische Ol 1941 1944 Kivioli Keemiatoostus 1944 1995 Kiviter 1995 1999 Kivioli Keemiatoostus 1999 Kohtla 1931 1961 Davidson s retort New Consolidated Gold Fields Ltd 1931 1941 Baltische Ol 1941 1944 Kohtla Oil Shale Combinate 1944 1961 Narva 1980 1 Galoter retort1 Eesti Energia Eesti Energia OlitoostusNote Not closed still operatingThe government coalition of Estonia has decided that Estonia will stop shale oil extraction by 2040 at the latest 117 Environmental impact EditSee also Environmental impact of the oil shale industry Unrehabilitated land at the Aidu open pit mine 2007 An old semi coke heap in Kivioli 2005 Wastes and land usage Edit The mining and processing of about one billion tonnes of oil shale in Estonia has created about 360 370 million tonnes of solid waste Combustion ashes are the largest component 200 million tonnes followed by mining waste 90 million tonnes and spent shale mainly semi coke 70 80 million tonnes 94 141 In addition approximately 73 million tonnes of graptolitic argillite as overlying deposit were mined and piled in waste heaps in the process of phosphorite ore mining near Maardu in 1964 1991 9 The oil shale waste heaps pose a spontaneous ignition risk due to their remaining organic content 142 The waste material particularly semi coke contains pollutants including sulphates heavy metals and polycyclic aromatic hydrocarbons PAHs some of which are toxic and carcinogenic 143 144 As a result of decades of mining activity the topography of the oil shale region has changed this includes a greater range of altitudes within the mined area 145 Former and current oil shale mines occupy about 1 of Estonia s territory 19 About 500 square kilometres 190 sq mi or 15 of Ida Viru County s territory is out of use due to open pit mines and waste landfills an additional 150 square kilometres 58 sq mi has sunk or become unstable due to underground mining 146 Semi coke heaps near Kohtla Jarve and Kivioli cover more than 180 200 hectares 440 490 acres and ash heaps near Narva cover more than 210 hectares 520 acres 141 These heaps protruding from the flat landscape are regarded as landmarks and as monuments to the area s industrial heritage 147 There is less biodiversity within the mined area in particular the reclaimed and reforested areas have less biodiversity than the areas which have undergone a natural succession 145 Water usage and pollution Edit Surface water flows into mines and accumulates along with groundwater This water must be pumped out in order for mining to proceed The water that is pumped from the mines and the coolant water used by oil shale fired power stations combined exceeds 90 of all water used in Estonia 29 For each cubic meter of oil shale mined in Estonia 14 18 cubic metres 490 640 cu ft of water must be pumped from the mines amounting to about 227 million cubic metres 184 000 acre ft that are pumped from mines annually Groundwater comprises 64 of the water pumped from underground mines annually and 24 of that pumped from open pit mines 29 This alters both the circulation and quality of the groundwater lowers groundwater levels and releases mine water into surface water bodies such as rivers and lakes Mining activities have contributed to lower water levels in 24 out of the 39 lakes in the Kurtna Lake District 142 The release of mine water into the environment has changed the natural movement of surface water 29 As a result of mining activities groundwater moves towards the excavation cavities A 220 kilometre 85 square mile underground water body that holds over 170 million cubic metres 140 000 acre ft of water has formed in eight abandoned underground mines Ahtme Kohtla Kukruse Kava Sompa Tammiku No 2 and No 4 71 148 149 The process of pumping water from the mines introduces oxygen via aeration thereby oxidising the rock s pyrite Pyrite contains sulfur and one consequence of its oxidation is the introduction of significant amounts of sulphates into mine water 142 148 This has had a negative impact on water quality in five lakes in the Kurtna Lake District 29 In some lakes sulphate levels have increased tens of times compared to the pre mining period Suspended mineral matter in the mine water pumped into these lakes has changed the composition of the lakes sediments However it has been found that this disturbance diminishes over time studies show that sulphates and iron in mining water decrease to levels that meet drinking water quality standards about five years after mine closure 148 The process and waste waters used in shale oil extraction contain phenols tar and several other environmentally toxic products 141 143 Power stations use water as a coolant and for hydraulic transportation of oil shale ash to the ash heaps Narva power stations use 1 306 million cubic metres 1 059 000 acre ft of water from the Narva River annually for cooling 29 For ash transportation generated oil shale ash is mixed with water at a ratio of 1 20 and the resulted mixture known as ash pulp is pumped to the heaps 150 Consequently the transportation water becomes highly alkaline The total volume of formed alkaline water is 19 million cubic metres 15 000 acre ft 151 Another source of water pollution is aqueous leachates from oil shale ash and spent shale About 800 000 to 1 200 000 cubic metres 650 to 970 acre ft of toxic leachate from the Narva ash heaps inflows annually to the Narva River and further to the Gulf of Finland 144 Before the closure of old semi coke heaps in Kohtla Jarve and Kivioli an additional 500 000 cubic metres 410 acre ft of leachates reached via the Kohtla and Purtse rivers to the Baltic Sea annually 141 The toxicity of leachate is mainly caused by the alkalinity and sulphides leachate also includes chlorides oil products heavy metals and PAHs which are carcinogenic 141 144 Air emissions Edit Oil shale fired power stations pollute air with the fly ash and flue gases like carbon dioxide CO2 nitrogen oxides NOx sulfur dioxide SO2 and hydrogen chloride HCl In addition to Estonia this pollution also affects Finland and Russia 152 The industry emits into the atmosphere annually about 200 000 tonnes of fly ash including heavy metals carbonates alkaline oxides mainly calcium oxide CaO and harmful organic substances including PAHs About 30 of the fly ash is CaO a portion of which is neutralised by atmospheric CO2 142 Alkaline fly ash has raised the pH value of lake and bog water This has caused the invasion of eutrophic plants in the area of the oil shale industry leading to the degradation of those waterbodies 153 Another source of air pollution is the dust that arises during deposition of oil shale ash and semi coke 141 According to a 2001 study the concentration of particulate matter in the fly ash is 39 7 mg per cubic metre 154 The most hazardous particles are those with a diameter of less than 2 5 micrometres 9 8 10 5 in these particles are associated with an increase in cardiovascular mortality and premature deaths in Estonia 155 The combustion of oil shale releases more CO2 into the atmosphere than any other primary fuel 156 157 Generating 1 MWh of electricity in modern oil shale fired boilers creates 0 9 1 tonnes of CO2 158 In 2017 oil shale related greenhouse gas emissions in Estonia accounted for 12 9 million tonnes or 69 1 of total energy related emissions Of the all energy related CO2 emissions heat and power generation accounted for 76 159 According to the OECD CO2 emissions in Estonia could be reduced by two thirds if oil shale would be used for production of lighter oil products instead of burning to generate electricity 160 Mitigation Edit Various efforts have reduced the industry s environmental impact Fluidised bed combustion generates fewer NOx SO2 and fly ash emissions including PAHs than the earlier technologies that burned pulverised oil shale 151 158 Reclamation and reforestation of exhausted mining areas have been carried out since the 1970s 161 In 2010 2013 a 38 million project was implemented for the environmentally safe closing of 86 hectares 210 acres of semi coke and ash heaps 146 In accordance with a European Union waste framework directive the heaps were covered with waterproof material new topsoil and sod 162 In Kivioli a 90 metre 300 ft semi coke heap the highest artificial hill in the Baltic countries was converted into a ski centre 163 The former Aidu open pit mine was converted into a rowing course 164 A part of the former Sirgala open pit mine has been used as a military training area 145 An oil shale sector health impact study conducted in 2014 2015 show that the residents of the region complained significantly more frequently about tightness long term cough phlegm in the lungs wheezing and cardiovascular diseases hypertension stroke diabetes and stenocardia 165 The study also shows that the rate of lung cancer among men in the region was higher compared to the Estonian average 166 See also Edit Estonia portal Energy portalEnergy in Estonia Geology of EstoniaReferences Edit a b c d e f g h i j k l m Vali E Valgma I Reinsalu E 2008 Usage of Estonian oil shale PDF Oil Shale A Scientific Technical Journal 25 2 101 114 doi 10 3176 oil 2008 2S 02 ISSN 0208 189X Retrieved 25 October 2008 a b IEA 2013 p 71 a b Ministry of Environment 2016 p 3 a b IEA 2013 p 20 a b Liive Sandor 2007 Oil Shale Energetics in Estonia PDF 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Nurme Martin Vaizene Vivika 2014 6 Eesti polevkivi kaevandamisviisid 6 Mining methods of Estonian oil shale PDF In Valgma Ingo ed Maendus Mining in Estonian Institute of Mining Tallinn University of Technology pp 55 68 ISBN 978 9949 430 80 2 External links Edit Media related to Oil shale in Estonia at Wikimedia CommonsLive carbon emissions from electricity generation electricityMap Live built by TomorrowEstonia at Climate Trace Retrieved from https en wikipedia org w index php title Oil shale in Estonia amp oldid 1136120057, wikipedia, wiki, book, books, library,

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