Graptolitic argillite explained

Graptolitic argillite
Type:Sedimentary
Prilithology:Black shale
Otherlithology:Slate, oil shale
Region:Baltoscandian platform
Country:Estonia

Graptolitic argillite (also known as dictyonema argillite, dictyonema oil shale, dictyonema shale, or Tremadocian black shale) is a marinite-type black shale of sapropelic origin. It is a blackish to greyish lithified claystone. The known occurrence of this rock is a graptolitic argillite of the Türisalu Formation in northern Estonia and northwest Russia.[1] [2] It is correlated with Swedish alum shale being its younger facial eastward continuation, and both being a part of the Baltoscandic Cambrian-Ordovician black shale, together with black shales in the Oslo region in Norway, Bornholm, Denmark, and Poland.[2] [3] Other known occurrences are in North America,[4] the Malay Peninsula,[5] and New Zealand.[6]

Although the name dictyonema argillite is widely used instead of graptolitic argillite, this name 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.[7] [8]

In mainland Estonia, it occurs at the foot of the North-Estonia Klint, ranging from the Pakri Peninsula to Narva in an area covering about .[9] When findings in the western Estonian islands are included, its extent increases to about .[2] The thickness of the layer varies from less than to a maximum of in western Estonia, as does its subsurface depth, which ranges from 10to.[10] It formed some 480 million years ago.[9]

The composition of graptolitic argillite varies by location within Estonia. Its organic content ranges from 10 to 20% and its sulfur content is 2 - 4%. Correspondingly, its calorific value is 5 - 8 megajoules per kilogram (MJ/kg) and Fischer Assay oil yield is 3 - 5%.[10] In northeastern Estonia its carbon-to-hydrogen atomic ratio is about nine.[2] Graptolitic argillite from the northeastern region contains up to 9% pyrite (generally between 2.4 and 6%), heavy metals such as uranium (up to 1,200 parts per million (ppm) or 300 grammes per tonne (g/t)), molybdenum (up to 1,000 ppm or 600 g/t), vanadium (up to 1,600 ppm or 1,200 g/t), and nickel,[2] [11] and other minerals including K-feldspars, quartz, clay minerals, light-brown phosphatic ooids, and accessory amounts of zircon, tourmaline, garnet, rutile, chalcopyrite, and glauconite.[2] Graptolitic argillite from the northwestern region contains fewer metals than are present in deposits in the northeast; it also contains more clay minerals.[11] Rock in these deposits contains corundum, amphiboles, and kyanite.[2]

Geological reserves of graptolitic argillite in Estonia have been estimated at 60–70 billion tonnes.[1] [9] Although the amount of graptolitic argillite exceeds that of kukersite, attempts to use it as an energy source have been unsuccessful due to its low calorific value and high content of sulfur.[10] [11] [12] However, it contains potentially about 2.1 billion tonnes of oil. In addition, graptolitic argillite in Estonia contains 5.67 million tonnes of uranium which makes it one of the main potential future uranium sources in Europe. Graptolitic argillite in Estonia also contains 16.53 million tonnes of zinc and 12.76 million tonnes of molybdenum; however, there is not yet any environmentally friendly and economically feasible technology to extract those metals.[12]

Citations and references

Cited sources

Notes and References

  1. Veski . R. . Palu . E. . Investigation of Dictyonema oil shale and its natural and artificial transformation products by a vankrevelenogram . Oil Shale. A Scientific-Technical Journal . Estonian Academy Publishers . 20 . 3 . 265–281 . 2003 . PDF . 0208-189X . 2008-10-25.
  2. Hade . Sigrid . Soesoo . Alvar . Estonian Graptolite Argillites Revisited: A Future Resource? . Oil Shale. A Scientific-Technical Journal . Estonian Academy Publishers . 31 . 1 . 4–18 . 2014 . PDF . 0208-189X . 10.3176/oil.2014.1.02 . 2014-04-13.
  3. Loog . A. . Kurvits . T. . Aruväli . J. . Petersell . V. . Grain size analysis and mineralogy of the Tremadocian Dictyonema shale in Estonia . Oil Shale. A Scientific-Technical Journal . Estonian Academy Publishers . 18 . 4 . 281–297 . 2001 . 0208-189X . 2014-11-09.
  4. [#dover|Dover et al. (1980)]
  5. Jones . C.R. . Lower Paleozoic Rocks of Malay Peninsula . . . 52 . 7 . 1259–1278 . 1968 . 10.1306/5d25c4a7-16c1-11d7-8645000102c1865d.
  6. Benson . W.N. . The geology of the region about Preservation and Chalky Inlets, south-west Fiordland, New Zealand . Transactions of the Royal Society of New Zealand Geology . . 63 . 393–432 . 1933 . PDF.
  7. [#kukersiteOS|Aaloe et al. (2007)]
  8. Lippmaa . E. . Marimäe . E. . Pihlak . A.-T. . Aguraiuja . R. . Estonian graptolitic argillites — ancient ores or future fuels? . Oil Shale. A Scientific-Technical Journal . Estonian Academy Publishers . 26 . 4 . 530–539 . 2009 . 0208-189X . 10.3176/oil.2009.4.08 . 2014-11-09.
  9. [#kukersiteOS|Aaloe et al. (2007)]
  10. Koel. Mihkel . Estonian oil shale . Oil Shale. A Scientific-Technical Journal . Estonian Academy Publishers . Extra . 1999 . 0208-189X . 2008-10-25.
  11. Väli . E. . Valgma . I. . Reinsalu . E. . Usage of Estonian oil shale . . . 25 . 2 . 101–114 . 2008 . PDF . 0208-189X . 2008-10-25 . 10.3176/oil.2008.2S.02.
  12. Soesoo . Alvar . Hade . Sigrid . Black shale of Estonia: Moving towards a Fennoscandian–Baltoscandian database . Trudy Karelskogo nauchnogo centra RAN . Karelian Research Centre of the Russian Academy of Sciences . 1 . 103–114 . 2014 . 1997-3217 . 2014-12-14.