Geology of Croatia

The geology of Croatia has some Precambrian rocks mostly covered by younger sedimentary rocks and deformed or superimposed by tectonic activity.[1]

Vertical sedimentary rock layers on the island of Hvar

The country is split into two main onshore provinces, a smaller part of the Pannonian Basin and the larger Dinarides. These areas are very different.

The carbonate platform karst landscape of Croatia helped to create the weathering conditions to form bauxite, gypsum, clay, spilite, and limestone.[2]

Geography

Relief map of Croatia

The territory covers 56,594 square kilometres (21,851 square miles), consisting of 56,414 square kilometres (21,782 square miles) of land and 128 square kilometres (49 square miles) of water.[3] Elevation ranges from the mountains of the Dinaric Alps with the highest point of the Dinara peak at 1,831 metres (6,007 feet) near the border with Bosnia and Herzegovina in the south[3] to the shore of the Adriatic Sea which makes up its entire southwest border. Insular Croatia consists of over a thousand islands and islets varying in size, 48 of which permanently inhabited. The largest islands are Cres and Krk,[3] each of them having an area of around 405 square kilometres (156 square miles).[3] Karst topography makes up about half of Croatia and is especially prominent in the Dinaric Alps.[4] There are several deep caves in Croatia, 49 of which deeper than 250 m (820.21 ft), 14 of them deeper than 500 m (1,640.42 ft) and three deeper than 1,000 m (3,280.84 ft). Croatia's most famous lakes are the Plitvice lakes, a system of 16 lakes with waterfalls connecting them over dolomite and limestone cascades. The lakes are renowned for their distinctive colours, ranging from turquoise to mint green, grey or blue.[5]

Pannonian Basin

The Pannonian Basin (marked III.), enclosed by the Carpathian Mountains and the Transylvanian Plateau (IV.) to the east and north. Croatia is the country marked as HR. Also shown: the Romanian Lowlands (II.) and the Outer Subcarpathian depressions (I.) beyond the Carpathians (also known as Transcarpathia)

The Pannonian Basin, or Carpathian Basin, is a large basin in Central Europe. The basin mostly is centered on the territory of modern Hungary, but also covers regions of western Slovakia, southeastern Poland, western Ukraine, western Romania, northern Serbia , the tip of northeast Croatia (Slavonia), northeastern Slovenia (Prekmurje), and eastern Austria. The Pannonian Basin is located within the arcuate Carpathian mountain chain that encircles the basin; this chain joins the Alpine mountain system to the west and the Dinaric mountain system to the southwest.[6] The basin is bounded by the intra-Carpathian mountain ranges and basement uplifts.[6] The Croatian sector of the basin has an area of 26,000 square kilometres (10,000 sq mi) and is broken into 4 main sub-basins – Sava, Drava, Northwest Croatia and Slavonija.[6] Evidence of the Carboniferous Variscan orogeny remains in Mt. Papuk in the east.[2] The basement is pre-Permian and is made of igneous, metamorphic and sedimentary rocks, with granites, gneisses, schists, and various low-grade metamorphic rocks and seem to have been affected by the Caledonian and Variscan orogenies. In the Pannonian area, Neogene material lies on top of older bedrock, emplaced on the periphery of the Paratethys Ocean. Neogene rocks include marl, conglomerate and sandstone as well as andesite and tuff. In the Drava River valley, the Neogene is seven kilometres thick. Many units contain lignite, and oil is found in lower units.

Dinarides

Croatia is mostly formed as a part of the Dinarides. The Dinaride region lies outside of the Pannonian Basin to the Southwest. The Dinarides is a mountain range in Southern and Southeastern Europe, separating the continental Balkan Peninsula from the Adriatic Sea. They stretch from Italy in the northwest through Slovenia, Croatia, Bosnia and Herzegovina, Serbia, Montenegro.[7][8] The Dinaric Alps extend for approximately 645 kilometres (401 mi) along the western Balkan peninsula from the Julian Alps to the northwest in Italy, downwards to the Šar and Korab massif, where their direction changes. The Dinarides are a wide NW-SE fold-and-thrust belt stretching from southwestern Slovenia to Montenegro along the Adriatic coast of Croatia and inland.

Formation

The Dinarides formed by subduction and collision processes in the border zone between Europe and Adria tectonic plates. The Adria plate is still pushing the Cenozoic carbonate rocks up on top of the Adriatic lithosphere. Ultramafic ophiolite formed with the opening of a branch of the Tethys Ocean in the Cretaceous, followed by a magmatic activity. With continued continental subduction in the Paleogene, uplift began. The Adriatic Sea is a carbonate platform structural belt with Mesozoic-Paleogene flysch, chert, and limestone superimposed on it. Cenozoic Paleogene rocks unconformably overlie Cretaceous rocks with bauxite, coal and freshwater limestone, overlain by marine limestone from the Eocene and flysch formed in a trough between two carbonate platforms. Sandstone, marl, and limestone deposited in basins now beneath the Adriatic Sea during the Neogene.

Adriatic plate

The Adriatic Sea and the Po Valley are associated with a tectonic microplate—identified as the Apulian or Adriatic Plate that separated from the African Plate during the Mesozoic era. This separation began in the Middle and Late Triassic, when limestone began to be deposited in the area. Between the Norian and Late Cretaceous, the Adriatic and Apulia Carbonate Platforms formed as a thick series of carbonate sediments (dolomites and limestones), up to 8,000 metres (26,000 ft) deep.[9] Remnants of the former are found in the Adriatic Sea, as well as in the southern Alps and the Dinaric Alps, and remnants of the latter are seen as the Gargano Promontory and the Maiella mountain. In the Eocene and early Oligocene, the plate moved north and north-east, contributing to the Alpine orogeny (along with the African and Eurasian Plates' movements) via the tectonic uplift of the Dinarides and Alps. In the Late Oligocene, the motion was reversed and the Apennine Mountains' orogeny took place.[10] An unbroken zone of increased seismic activity borders the Adriatic Sea, with a belt of thrust faults generally oriented in the northeast–southwest direction on the east coast and the northeast–southwest normal faults in the Apennines, indicating an Adriatic counterclockwise rotation.[11]

An active 200-kilometre (120 mi) fault has been identified to the northwest of Dubrovnik, adding to the Dalmatian islands as the Eurasian Plate slides over the Adriatic microplate. Furthermore, the fault causes the Apennine peninsula's southern tip to move towards the opposite shore by about 0.4 centimetres (0.16 in) per year. If this movement continues, the seafloor will be completely consumed and the Adriatic Sea closed off in 50–70 million years.[12] In the Northern Adriatic, the coast of the Gulf of Trieste and western Istria is gradually subsiding, having sunk about 1.5 metres (4 ft 11 in) in the past two thousand years.[13] In the Middle Adriatic Basin, there is evidence of Permian volcanism in the area of Komiža on the island of Vis and the volcanic islands of Jabuka and Brusnik.[14] Earthquakes have been observed in the region since the earliest historical records.[11] A recent strong earthquake in the region was the 1979 Montenegro earthquake, measuring 7.0 on the Richter scale.[15] Historical earthquakes in the area include the 1627 Gargano peninsula and the 1667 Dubrovnik earthquakes, both followed by strong tsunamis.[16] In the last 600 years, fifteen tsunamis have occurred in the Adriatic Sea.[17]

Natural resources

Coal, oil, gas, and water are the leading natural resources in Croatia.

References

  1. Moores, E.M.; Fairbridge, Rhodes W. (1997). Encyclopedia of European & Asian Regional Geology. Springer. pp. 156–160. ISBN 978-0-412-74040-4. OCLC 38157559.
  2. Moores & Fairbridge 1997, p. 159.
  3. "World Factbook". Central Intelligence Agency. Retrieved 9 September 2011.
  4. Matas, Mate (18 December 2006). "Raširenost krša u Hrvatskoj" [Presence of Karst in Croatia]. geografija.hr (in Croatian). Croatian Geographic Society. Archived from the original on 9 June 2012. Retrieved 18 October 2011.
  5. "The best national parks of Europe". BBC. 28 June 2011. Archived from the original on 1 July 2012. Retrieved 11 October 2011.
  6. "Geological overview onshore". CHA. Retrieved 8 June 2021.
  7. Dinaric Alps, dictionary.reference.com; accessed 25 August 2015.
  8. "Visit Dinaric Alps". Adventure Driven Vacations.
  9. Surić, Maša (June 2005). "Submerged Karst – Dead or Alive? Examples from the eastern Adriatic Coast (Croatia)". Geoadria. University of Zadar. 10 (1): 5–19. doi:10.15291/geoadria.71. ISSN 1331-2294.
  10. "Mladen Juračić" [Geology of the sea, Mediterranean and Adriatic] (PDF) (in Croatian). University of Zagreb, Faculty of Science, Geology Department. Retrieved 28 January 2012.
  11. Muço, Betim (2006). "Seismicity of the Adriatic microplate and a possible triggering: geodynamic implication". In Pinter, Nicholas; Grenerczy, Gyula; Weber, John; Stein, Seth; Medak, Damir (eds.). The Adria microplate: GPS geodesy, tectonics and hazards. Springer. pp. 351–352. ISBN 978-1-4020-4234-8.
  12. Goudarzi, Sara (25 January 2008). "New Fault Found in Europe; May "Close Up" Adriatic Sea". National Geographic. National Geographic Society. Retrieved 28 January 2012.
  13. Antonioli, F.; Anzidei, M.; Lambeck, K.; Auriemma, R.; Gaddi, D.; Furlani, S.; Orrù, P.; Solinas, E.; Gaspari, A.; Karinja, S.; Kovačić, V.; Surace, L. (2007). "Sea-level change during the Holocene in Sardinia and in the northeastern Adriatic (central Mediterranean Sea) from archaeological and geomorphological data". Quaternary Science Reviews. 26 (19–21): 2463–2486. Bibcode:2007QSRv...26.2463A. doi:10.1016/j.quascirev.2007.06.022.
  14. Vukosav, Branimir (30 April 2011). "Ostaci prastarog vulkana u Jadranu" [Remains of an ancient volcano in the Adriatic Sea]. Zadarski list (in Croatian). Retrieved 24 February 2012.
  15. "Historical Seismicity of Montenegro". Montenegro seismological observatory. Retrieved 6 February 2012.
  16. Soloviev, Sergey Leonidovich; Solovieva, Olga N.; Go, Chan N.; Kim, Khen S.; Shchetnikov, Nikolay A. (2000). Tsunamis in the Mediterranean Sea, 2000 B.C.-2000 A.D. Springer. pp. 47–52. ISBN 978-0-7923-6548-8.
  17. Pasarić, Mira; Brizuela, B; Graziani, L; Maramai, A; Orlić, M (2012). "Historical tsunamis in the Adriatic Sea". Natural Hazards. International Society for the Prevention and Mitigation of Natural Hazards. 61 (2): 281–316. doi:10.1007/s11069-011-9916-3. ISSN 1573-0840. S2CID 128392992.
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