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Pastos Grandes

January 01, 1970

21°45′S 67°50′W / 21.750°S 67.833°W / -21.750; -67.833[1] Pastos Grandes is the name of a caldera and its crater lake in Bolivia. The caldera is part of the Altiplano-Puna volcanic complex, a large ignimbrite province that is part of the Central Volcanic Zone of the Andes. Pastos Grandes has erupted a number of ignimbrites through its history, some of which exceeded a volume of 1,000 cubic kilometres (240 cu mi). After the ignimbrite phase, the lava domes of the Cerro Chascon-Runtu Jarita complex were erupted close to the caldera and along faults.

Satellite image of the Pastos Grandes lake basin

The caldera is the site of a few lakes, some of which are fed by hot springs. A number of minerals, including lithium, are dissolved in the lakes.

Location edit

Pastos Grandes lies in the Sud Lipez Region of Bolivia.[2] Geographically the area is part of the Altiplano, a high plateau bordered by the Cordillera Occidental and the Cordillera Oriental. The Altiplano contains two large salt pans, the Salar de Uyuni and Salar de Coipasa.[3] The specific area of Pastos Grandes is remote and poorly accessible,[4] the existence of the caldera was first established by satellite imagery.[5]

Geology edit

Regional edit

The region has been heavily affected by volcanism, including large ignimbrites and stratovolcanoes extending into Chile. Volcanic rocks include andesite, dacite and rhyodacite with the former dominating in the Chilean stratovolcanoes and the latter in the ignimbrites.[3] The dry regional climate means that there is little erosion and that volcanic centres are well conserved. The surface covered by volcanic rocks amounts to about 300,000 square kilometres (120,000 sq mi).[6]

Volcanic activity in the region is the consequence of the subduction of the Nazca Plate beneath the South American Plate in the Peru-Chile Trench. This process has formed three main volcanic zones at the Andes, the Northern Volcanic Zone, the Central Volcanic Zone and the Southern Volcanic Zone. Pastos Grandes is part of the Central Volcanic Zone along with about 50 volcanoes with recent activity and other ignimbrite generating volcanic centres.[7] This ignimbritic volcanism began in the late Miocene and formed a large field known as the Altiplano-Puna volcanic complex,[8] a large volcanic province which clusters around the tripoint between Argentina, Bolivia and Chile.[9]

Local edit

Pastos Grandes is a nested caldera which underwent repeated collapse in the past,[10] most likely along defined sectors of its rim.[11] It has been subdivided into two calderas, a larger Chuhuila caldera and the 40 by 25 kilometres (25 mi × 16 mi) smaller Pastos Grandes caldera.[12] The caldera is about 35 by 40 kilometres (22 mi × 25 mi)[13] wide and had a maximum depth of 400 metres (1,300 ft).[2] Cerro Pastos Grandes is 5,802 metres (19,035 ft) high and shows traces of a sector collapse.[1] It might be a 500–1,200 metres (1,600–3,900 ft) high resurgent dome[2] and is flanked by lava domes on the north-northwestern, southwestern and southeastern side.[14] The activity of Pastos Grandes may be associated with the ongoing development of a pluton underneath the caldera.[15] Major regional faults running through the region have influenced the shape of the calderas, giving them an elliptic shape which is also evident at Pastos Grandes.[16]

Pastos Grandes has erupted calc-alkaline rocks which define a dacite suite.[12] Eruption products of Pastos Grandes are rich in potassium. Minerals encountered in the rock include amphibole, biotite, plagioclase, quartz and sanidine.[12][13] The magmas underwent slow evolution in the 1,000,000 years preceding each eruption.[17] Plutonic rocks linked to Pastos Grandes were erupted from the Chascon-Runtu Jarita vents 94,000 - 85,000 years ago.[12]

Eruption history edit

Three large ignimbrite-forming eruptions occurred at Pastos Grandes during its history. At first, it was assumed that large eruptions first occurred 8.1 million years ago, a second 5.6 million years and a third 2.3 million years ago.[18] However, it is not clear which of any eruption formed the caldera.[19] A number of ignimbrites has been attributed to Pastos Grandes, some of them may be different names for the same ignimbrite:

  • The 8.33 ± 0.15 million years old Sifon ignimbrite has a volume of over 1,000 cubic kilometres (240 cu mi), but it is not certain that Pastos Grandes was actually the source.[20]
  • The 6.2 ± 0.7 million years old Pastos Grandes I or Chuhuhuilla ignimbrite has with a volume of over 1,000 cubic kilometres (240 cu mi).[20]
  • The 3.3 ± 0.4 million years old Pastos Grandes II/Juvina ignimbrite has a volume of 50–100 cubic kilometres (12–24 cu mi) from the Juvina centre.[20]
  • The 5.45 ± 0.02 million years old Chuhuilla ignimbrite with a volume of 1,200 cubic kilometres (290 cu mi)[13] and was responsible for the first caldera-forming cycle.[12]
  • The 2.89 ± 0.01 million years old Pastos Grandes ignimbrite that has a volume of 1,500 cubic kilometres (360 cu mi)[13] and is part of the second caldera-forming cycle.[12]

The 6.1 million years old Carcote ignimbrite may also have originated here.[21] The 5.22 ± 0.02 million years old Alota ignimbrite was also attributed to Pastos Grandes,[13] although it originated in a centre northeast of the Pastos Grandes caldera known as Cerro Juvina.[19] These ignimbrites crop out on the outside of the Pastos Grandes caldera,[22] where they extend to distances of 50 kilometres (31 mi), but also cover parts of the caldera.[13] Given the volumes involved, at least some of the eruptions are classified as 8 on the volcanic explosivity index.[23]

Pastos Grandes was volcanically active for a long time, more than many other Altiplano-Puna volcanic complex centres.[13] Later more recent volcanic centres formed within the caldera, the youngest of these centres are relatively recent[18] Such recent centres close to Pastos Grandes are Cerro Chao and Cerro Chascon-Runtu Jarita complex.[24] The former of which lies on a lineament that appears to coincide with the caldera rim of Pastos Grandes,[25] and the latter seems to rise from the ring fault of Pastos Grandes. but is apparently unrelated to the caldera.[26] Cerro Chascon-Runtu Jarita is less than 100,000 years old according to argon-argon dating.[27] This and ongoing geothermal manifestations suggest that volcanic activity may still occur at Pastos Grandes.[21] Finally, Pastos Grandes and Cerro Guacha may be the heat source for the El Tatio geothermal field west of Pastos Grandes.[28]

Lake edit

Main article: Pastos Grandes Lake

At an elevation of 4,430 metres (14,530 ft),[29] Pastos Grandes contains a lake basin north of Cerro Pastos Grandes,[22] which is 10 kilometres (6.2 mi) wide[30] and covers a surface area of about 100 square kilometres (39 sq mi)[3]-120 square kilometres (46 sq mi)[31] at an elevation of 4,400 metres (14,400 ft).[32] It only covers a fraction of the area of Pastos Grandes caldera[14] and is probably a remnant of a once-larger lake that filled the moat of the caldera.[31] Earlier lacustrine episodes left a layer of beige mud behind. This mud freezes during the winter months to a certain depth and cryoturbation has formed polygonal structures as well as large cracks in the crust on its surface.[3]

Surfaces of open water are concentrated on the eastern edge of the salt pan, in its very centre and isolated areas on the western side, these all form an intricated network[33] of interconnected ponds especially in the western half of the salt pan.[31] One of these open water surfaces on the western side of the lake basin is known as Laguna Caliente,[34] while another square-shaped lake in the southern part of the caldera is known as Laguna Khara.[35] Sometimes after heavy precipitation, these open water surfaces can join into a ring lake around the centre.[36]

Intermittent streams drain the catchment of Pastos Grandes and reach the salt pan; the longest flow through the southeastern parts of the catchment.[33] The entire drainage basin of the lake has a surface area of 655 square kilometres (253 sq mi)[32]-660 square kilometres (250 sq mi) and is delimited to the west and east by rhyolitic ridges.[31] Apart from surface streams, springs contribute to the water budget of Pastos Grandes.[36] Hot springs are active or were recently active on the western side of the salt pan[37] and bear names such as La Salsa, La Rumba and El Ojo Verde,[38] where temperatures of 20–75 °C (68–167 °F) have been measured. On the western shore, colder springs predominate.[33] The heat appears to originate from a 200–250 °C (392–482 °F) hot reservoir.[39]

Salts found within the salt pan include gypsum, halite and ulexite. The brines are rich in boron, lithium and sodium chloride,[33] the salt pan has been considered a potential site for lithium and potassium mining.[29] Salt contents range 144–371 grams per litre (0.0052–0.0134 lb/cu in).[40] The salt chemistry is strongly influenced by the climate; the precipitation of mirabilite due to cold and evaporation of water cause changes in the composition of the waters.[41]

Unique among most other salars of the Andes, Pastos Grandes features a c. 40 square kilometres (15 sq mi) carbonate platform with numerous fabrics of carbonate deposition.[42] It is unclear what drives its formation as the climate at Pastos Grandes is similar to that of other salt lakes without such platforms[31] but it may be a consequence of carbon dioxide degassing under the salar.[43] At numerous points, calcite pisoliths are found at Pastos Grandes, usually associated with active or former springs.[44] Rimstone dams and sinter terraces are also encountered close to inactive springs.[45] All these cave formations encountered at Pastos Grandes are caused by the precipitation of calcite from oversaturated waters at the surface. What drives the loss of carbon dioxide and thus the oversaturation is not clear but may involve photosynthesis by algae.[46]

Algae and diatoms grow within the open waters in Pastos Grandes,[33] the diatoms being represented by oligohaline species such as some Fragilaria and Navicularia species.[30] Different water surfaces are dominated by different diatom species, distinctions that are only partly mediated by different salinities.[47] Animal species found within the lakes include amphipods, elmids and leeches in freshwater and by Cricotopus in saltwater.[48] Additional animals are Euplanaria dorotocephala, Chironomidae, Corixidae, Cyclopoida, Ephydridae, Harpacticoida, Orchestidae, Ostracoda and Tipulidae species.[49][50] Similar but different animal species have been found in other local lakes, indicating that they are largely separate systems.[51] The animal flora of such Altiplano lakes is not very diverse, probably due to their relative youth and the harsh and often highly variable climates of the past in the region.[52]

Pastos Grandes is one of many endorheic lakes that cover the region.[30] The neighbouring Altiplano was formerly covered by lakes as well during the Pleistocene. After they dried up, the Salar de Uyuni and Salar de Coipasa were left behind.[3]

Climate edit

The area of Pastos Grandes has a summer wet climate, with most of the precipitation falling during a wet season in December–March. An estimate for the total precipitation is about 200 millimetres per year (7.9 in/year).[3] That is, the climate is arid and evaporation rates can reach about 1,400 millimetres per year (55 in/year). Insolation is high and the temperatures can vary by as much as 15 °C (27 °F).[36] During winter, they can drop as far as −25 °C (−13 °F).[3]

Human exploitation edit

The lithium deposits have drawn attention of mining interests, with the Bolivian government seeking businesses to exploit the lithium deposits at Pastos Grandes, Uyuni and Coipasa.[53]

References edit

  1. ^ a b Francis, P. W.; Wells, G. L. (1988-07-01). "Landsat Thematic Mapper observations of debris avalanche deposits in the Central Andes". Bulletin of Volcanology. 50 (4): 261. Bibcode:1988BVol...50..258F. doi:10.1007/BF01047488. ISSN 0258-8900. S2CID 128824938.
  2. ^ a b c Baker 1981, p. 306.
  3. ^ a b c d e f g Risacher & Eugster 1979, p. 255.
  4. ^ Risacher & Eugster 1979, p. 268.
  5. ^ Salisbury et al. 2010, p. 9.
  6. ^ Baker 1981, p. 293.
  7. ^ Silva 1989, p. 1102.
  8. ^ Silva 1989, p. 1103.
  9. ^ de Silva & Gosnold 2007, p. 321.
  10. ^ de Silva & Gosnold 2007, p. 324.
  11. ^ Baker 1981, p. 312.
  12. ^ a b c d e f Kaiser et al. 2017, p. 74.
  13. ^ a b c d e f g Kaiser, J. F.; de Silva, S. L.; Ort, M. H.; Sunagua, M. (2011-12-01). "The Pastos Grandes Caldera Complex of SW Bolivia: The building of a composite upper crustal batholith". AGU Fall Meeting Abstracts. 21: V21C–2509. Bibcode:2011AGUFM.V21C2509K.
  14. ^ a b Kaiser et al. 2017, p. 75.
  15. ^ de Silva & Gosnold 2007, p. 332.
  16. ^ Silva et al. 2006, p. 53.
  17. ^ Kaiser et al. 2017, p. 85.
  18. ^ a b Silva 1989, p. 1104.
  19. ^ a b Salisbury et al. 2010, p. 12.
  20. ^ a b c de Silva & Gosnold 2007, p. 323.
  21. ^ a b Francis, P.W.; Silva, S.L. De (1989). "Application of the Landsat Thematic Mapper to the identification of potentially active volcanoes in the central Andes". Remote Sensing of Environment. 28: 245–255. Bibcode:1989RSEnv..28..245F. doi:10.1016/0034-4257(89)90117-x.
  22. ^ a b Baker 1981, p. 307.
  23. ^ Salisbury et al. 2010, p. 2.
  24. ^ Silva et al. 2006, p. 51.
  25. ^ de Silva et al. 1994, p. 17806.
  26. ^ de Silva et al. 1994, p. 17821.
  27. ^ Watts et al. 1999, p. 244.
  28. ^ Landrum, J. T.; Bennett, P. C.; Engel, A. S.; Alsina, M. A.; Pastén, P. A.; Milliken, K. (2009-04-01). "Partitioning geochemistry of arsenic and antimony, El Tatio Geyser Field, Chile". Applied Geochemistry. 12th International Symposium on Water-Rock Interaction (WRI-12). 24 (4): 665. Bibcode:2009ApGC...24..664L. doi:10.1016/j.apgeochem.2008.12.024. hdl:10533/142624.
  29. ^ a b Warren, John K. (2010-02-01). "Evaporites through time: Tectonic, climatic and eustatic controls in marine and nonmarine deposits". Earth-Science Reviews. 98 (3–4): 227. Bibcode:2010ESRv...98..217W. doi:10.1016/j.earscirev.2009.11.004.
  30. ^ a b c Servant-Vildary 1983, p. 249.
  31. ^ a b c d e Muller et al. 2020, p. 222.
  32. ^ a b Williams et al. 1995, p. 66.
  33. ^ a b c d e Risacher & Eugster 1979, p. 257.
  34. ^ Dejoux 1993, p. 258.
  35. ^ Watts et al. 1999, p. 246.
  36. ^ a b c Servant-Vildary & Roux 1990, p. 268.
  37. ^ Risacher & Eugster 1979, p. 256.
  38. ^ Muller et al. 2020, p. 223.
  39. ^ Muller et al. 2020, p. 228.
  40. ^ Servant-Vildary 1983, p. 252.
  41. ^ Williams et al. 1995, p. 69.
  42. ^ Muller et al. 2020, p. 221.
  43. ^ Muller et al. 2020, p. 234.
  44. ^ Risacher & Eugster 1979, p. 258.
  45. ^ Risacher & Eugster 1979, p. 261.
  46. ^ Risacher & Eugster 1979, p. 267.
  47. ^ Servant-Vildary & Roux 1990, p. 281.
  48. ^ Dejoux 1993, p. 262.
  49. ^ Williams et al. 1995, p. 71.
  50. ^ Dejoux 1993, p. 261.
  51. ^ Dejoux 1993, p. 266.
  52. ^ Williams et al. 1995, p. 74.
  53. ^ Poveda Bonilla, Rafael (13 May 2022). "La gobernanza de las empresas estatales en la industria minera de los países andinos" (in Spanish): 13–14. {{cite journal}}: Cite journal requires |journal= (help)

Sources edit

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  • Dejoux, Claude (1993-09-01). "Benthic invertebrates of some saline lakes of the Sud Lipez region, Bolivia". Hydrobiologia. 267 (1–3): 257–267. doi:10.1007/BF00018807. ISSN 0018-8158. S2CID 23979914.
  • de Silva, S. L.; Self, S.; Francis, P. W.; Drake, R. E.; Carlos, Ramirez R. (10 September 1994). "Effusive silicic volcanism in the Central Andes: The Chao dacite and other young lavas of the Altiplano-Puna Volcanic Complex" (PDF). Journal of Geophysical Research: Solid Earth. 99 (B9): 17805–17825. Bibcode:1994JGR....9917805D. doi:10.1029/94JB00652.
  • de Silva, Shanaka L.; Gosnold, William D. (2007-11-01). "Episodic construction of batholiths: Insights from the spatiotemporal development of an ignimbrite flare-up". Journal of Volcanology and Geothermal Research. Large Silicic Magma Systems. 167 (1–4): 320–335. Bibcode:2007JVGR..167..320D. doi:10.1016/j.jvolgeores.2007.07.015.
  • Kaiser, Jason F.; de Silva, Shanaka; Schmitt, Axel K.; Economos, Rita; Sunagua, Mayel (1 January 2017). "Million-year melt–presence in monotonous intermediate magma for a volcanic–plutonic assemblage in the Central Andes: Contrasting histories of crystal-rich and crystal-poor super-sized silicic magmas". Earth and Planetary Science Letters. 457: 73–86. Bibcode:2017E&PSL.457...73K. doi:10.1016/j.epsl.2016.09.048. ISSN 0012-821X.
  • Muller, E.; Gaucher, E.C.; Durlet, C.; Moquet, J.S.; Moreira, M.; Rouchon, V.; Louvat, P.; Bardoux, G.; Noirez, S.; Bougeault, C.; Vennin, E.; Gérard, E.; Chavez, M.; Virgone, A.; Ader, M. (June 2020). "The origin of continental carbonates in Andean salars: A multi-tracer geochemical approach in Laguna Pastos Grandes (Bolivia)". Geochimica et Cosmochimica Acta. 279: 220–237. Bibcode:2020GeCoA.279..220M. doi:10.1016/j.gca.2020.03.020. ISSN 0016-7037.
  • Risacher, Francois; Eugster, Hans P. (1979-04-01). "Holocene pisoliths and encrustations associated with spring-fed surface pools, Pastos Grandes, Bolivia". Sedimentology. 26 (2): 253–270. Bibcode:1979Sedim..26..253R. doi:10.1111/j.1365-3091.1979.tb00353.x.
  • Salisbury, Morgan J.; Jicha, Brian R.; Silva, Shanaka L. de; Singer, Brad S.; Jiménez, Néstor C.; Ort, Michael H. (2010-12-21). "40Ar/39Ar chronostratigraphy of Altiplano-Puna volcanic complex ignimbrites reveals the development of a major magmatic province". Geological Society of America Bulletin. 123 (5–6): 821–840. Bibcode:2011GSAB..123..821S. doi:10.1130/B30280.1. ISSN 0016-7606.
  • Servant-Vildary, Simone (1983). "Les diatomées des sédiments superficiels de quelques lacs salés de Bolivie". Sciences Géologiques Bulletin (in French). 36 (4): 249–253. doi:10.3406/sgeol.1983.1643. ISSN 0302-2692.
  • Servant-Vildary, S.; Roux, M. (1990-05-01). "Multivariate analysis of diatoms and water chemistry in Bolivian saline lakes". Hydrobiologia. 197 (1): 267–290. doi:10.1007/BF00026956. ISSN 0018-8158. S2CID 12273039.
  • Silva, S. L. de (1989-12-01). "Altiplano-Puna volcanic complex of the central Andes". Geology. 17 (12): 1102–1106. Bibcode:1989Geo....17.1102D. doi:10.1130/0091-7613(1989)017<1102:APVCOT>2.3.CO;2.
  • Silva, Shanaka De; Zandt, George; Trumbull, Robert; Viramonte, José G.; Salas, Guido; Jiménez, Néstor (2006-01-01). "Large ignimbrite eruptions and volcano-tectonic depressions in the Central Andes: a thermomechanical perspective". Geological Society, London, Special Publications. 269 (1): 47–63. Bibcode:2006GSLSP.269...47D. doi:10.1144/GSL.SP.2006.269.01.04. ISSN 0305-8719. S2CID 129924955.
  • Watts, Robert B.; Silva, Shanaka L. de; Rios, Guillermina Jimenez de; Croudace, Ian (1999-09-01). "Effusive eruption of viscous silicic magma triggered and driven by recharge: a case study of the Cerro Chascon-Runtu Jarita Dome Complex in Southwest Bolivia". Bulletin of Volcanology. 61 (4): 241–264. Bibcode:1999BVol...61..241W. doi:10.1007/s004450050274. ISSN 0258-8900. S2CID 56303121.
  • Williams, W. D.; Carrick, T. R.; Bayly, I. a. E.; Green, J.; Herbst, D. B. (1995-03-01). "Invertebrates in salt lakes of the Bolivian Altiplano". International Journal of Salt Lake Research. 4 (1): 65–77. doi:10.1007/BF01992415. ISSN 1037-0544.

External links edit

  • Understanding large resurgent calderas and associated magma systems: the Pastos Grandes Caldera Complex, southwest Bolivia

January 01, 1970
pastos, grandes, name, caldera, crater, lake, bolivia, caldera, part, altiplano, puna, volcanic, complex, large, ignimbrite, province, that, part, central, volcanic, zone, andes, erupted, number, ignimbrites, through, history, some, which, exceeded, volume, cu. 21 45 S 67 50 W 21 750 S 67 833 W 21 750 67 833 1 Pastos Grandes is the name of a caldera and its crater lake in Bolivia The caldera is part of the Altiplano Puna volcanic complex a large ignimbrite province that is part of the Central Volcanic Zone of the Andes Pastos Grandes has erupted a number of ignimbrites through its history some of which exceeded a volume of 1 000 cubic kilometres 240 cu mi After the ignimbrite phase the lava domes of the Cerro Chascon Runtu Jarita complex were erupted close to the caldera and along faults Satellite image of the Pastos Grandes lake basin The caldera is the site of a few lakes some of which are fed by hot springs A number of minerals including lithium are dissolved in the lakes Contents 1 Location 2 Geology 2 1 Regional 2 2 Local 2 3 Eruption history 3 Lake 4 Climate 5 Human exploitation 6 References 6 1 Sources 7 External linksLocation editPastos Grandes lies in the Sud Lipez Region of Bolivia 2 Geographically the area is part of the Altiplano a high plateau bordered by the Cordillera Occidental and the Cordillera Oriental The Altiplano contains two large salt pans the Salar de Uyuni and Salar de Coipasa 3 The specific area of Pastos Grandes is remote and poorly accessible 4 the existence of the caldera was first established by satellite imagery 5 Geology editRegional edit The region has been heavily affected by volcanism including large ignimbrites and stratovolcanoes extending into Chile Volcanic rocks include andesite dacite and rhyodacite with the former dominating in the Chilean stratovolcanoes and the latter in the ignimbrites 3 The dry regional climate means that there is little erosion and that volcanic centres are well conserved The surface covered by volcanic rocks amounts to about 300 000 square kilometres 120 000 sq mi 6 Volcanic activity in the region is the consequence of the subduction of the Nazca Plate beneath the South American Plate in the Peru Chile Trench This process has formed three main volcanic zones at the Andes the Northern Volcanic Zone the Central Volcanic Zone and the Southern Volcanic Zone Pastos Grandes is part of the Central Volcanic Zone along with about 50 volcanoes with recent activity and other ignimbrite generating volcanic centres 7 This ignimbritic volcanism began in the late Miocene and formed a large field known as the Altiplano Puna volcanic complex 8 a large volcanic province which clusters around the tripoint between Argentina Bolivia and Chile 9 Local edit Pastos Grandes is a nested caldera which underwent repeated collapse in the past 10 most likely along defined sectors of its rim 11 It has been subdivided into two calderas a larger Chuhuila caldera and the 40 by 25 kilometres 25 mi 16 mi smaller Pastos Grandes caldera 12 The caldera is about 35 by 40 kilometres 22 mi 25 mi 13 wide and had a maximum depth of 400 metres 1 300 ft 2 Cerro Pastos Grandes is 5 802 metres 19 035 ft high and shows traces of a sector collapse 1 It might be a 500 1 200 metres 1 600 3 900 ft high resurgent dome 2 and is flanked by lava domes on the north northwestern southwestern and southeastern side 14 The activity of Pastos Grandes may be associated with the ongoing development of a pluton underneath the caldera 15 Major regional faults running through the region have influenced the shape of the calderas giving them an elliptic shape which is also evident at Pastos Grandes 16 Pastos Grandes has erupted calc alkaline rocks which define a dacite suite 12 Eruption products of Pastos Grandes are rich in potassium Minerals encountered in the rock include amphibole biotite plagioclase quartz and sanidine 12 13 The magmas underwent slow evolution in the 1 000 000 years preceding each eruption 17 Plutonic rocks linked to Pastos Grandes were erupted from the Chascon Runtu Jarita vents 94 000 85 000 years ago 12 Eruption history edit Three large ignimbrite forming eruptions occurred at Pastos Grandes during its history At first it was assumed that large eruptions first occurred 8 1 million years ago a second 5 6 million years and a third 2 3 million years ago 18 However it is not clear which of any eruption formed the caldera 19 A number of ignimbrites has been attributed to Pastos Grandes some of them may be different names for the same ignimbrite The 8 33 0 15 million years old Sifon ignimbrite has a volume of over 1 000 cubic kilometres 240 cu mi but it is not certain that Pastos Grandes was actually the source 20 The 6 2 0 7 million years old Pastos Grandes I or Chuhuhuilla ignimbrite has with a volume of over 1 000 cubic kilometres 240 cu mi 20 The 3 3 0 4 million years old Pastos Grandes II Juvina ignimbrite has a volume of 50 100 cubic kilometres 12 24 cu mi from the Juvina centre 20 The 5 45 0 02 million years old Chuhuilla ignimbrite with a volume of 1 200 cubic kilometres 290 cu mi 13 and was responsible for the first caldera forming cycle 12 The 2 89 0 01 million years old Pastos Grandes ignimbrite that has a volume of 1 500 cubic kilometres 360 cu mi 13 and is part of the second caldera forming cycle 12 The 6 1 million years old Carcote ignimbrite may also have originated here 21 The 5 22 0 02 million years old Alota ignimbrite was also attributed to Pastos Grandes 13 although it originated in a centre northeast of the Pastos Grandes caldera known as Cerro Juvina 19 These ignimbrites crop out on the outside of the Pastos Grandes caldera 22 where they extend to distances of 50 kilometres 31 mi but also cover parts of the caldera 13 Given the volumes involved at least some of the eruptions are classified as 8 on the volcanic explosivity index 23 Pastos Grandes was volcanically active for a long time more than many other Altiplano Puna volcanic complex centres 13 Later more recent volcanic centres formed within the caldera the youngest of these centres are relatively recent 18 Such recent centres close to Pastos Grandes are Cerro Chao and Cerro Chascon Runtu Jarita complex 24 The former of which lies on a lineament that appears to coincide with the caldera rim of Pastos Grandes 25 and the latter seems to rise from the ring fault of Pastos Grandes but is apparently unrelated to the caldera 26 Cerro Chascon Runtu Jarita is less than 100 000 years old according to argon argon dating 27 This and ongoing geothermal manifestations suggest that volcanic activity may still occur at Pastos Grandes 21 Finally Pastos Grandes and Cerro Guacha may be the heat source for the El Tatio geothermal field west of Pastos Grandes 28 Lake editMain article Pastos Grandes Lake At an elevation of 4 430 metres 14 530 ft 29 Pastos Grandes contains a lake basin north of Cerro Pastos Grandes 22 which is 10 kilometres 6 2 mi wide 30 and covers a surface area of about 100 square kilometres 39 sq mi 3 120 square kilometres 46 sq mi 31 at an elevation of 4 400 metres 14 400 ft 32 It only covers a fraction of the area of Pastos Grandes caldera 14 and is probably a remnant of a once larger lake that filled the moat of the caldera 31 Earlier lacustrine episodes left a layer of beige mud behind This mud freezes during the winter months to a certain depth and cryoturbation has formed polygonal structures as well as large cracks in the crust on its surface 3 Surfaces of open water are concentrated on the eastern edge of the salt pan in its very centre and isolated areas on the western side these all form an intricated network 33 of interconnected ponds especially in the western half of the salt pan 31 One of these open water surfaces on the western side of the lake basin is known as Laguna Caliente 34 while another square shaped lake in the southern part of the caldera is known as Laguna Khara 35 Sometimes after heavy precipitation these open water surfaces can join into a ring lake around the centre 36 Intermittent streams drain the catchment of Pastos Grandes and reach the salt pan the longest flow through the southeastern parts of the catchment 33 The entire drainage basin of the lake has a surface area of 655 square kilometres 253 sq mi 32 660 square kilometres 250 sq mi and is delimited to the west and east by rhyolitic ridges 31 Apart from surface streams springs contribute to the water budget of Pastos Grandes 36 Hot springs are active or were recently active on the western side of the salt pan 37 and bear names such as La Salsa La Rumba and El Ojo Verde 38 where temperatures of 20 75 C 68 167 F have been measured On the western shore colder springs predominate 33 The heat appears to originate from a 200 250 C 392 482 F hot reservoir 39 Salts found within the salt pan include gypsum halite and ulexite The brines are rich in boron lithium and sodium chloride 33 the salt pan has been considered a potential site for lithium and potassium mining 29 Salt contents range 144 371 grams per litre 0 0052 0 0134 lb cu in 40 The salt chemistry is strongly influenced by the climate the precipitation of mirabilite due to cold and evaporation of water cause changes in the composition of the waters 41 Unique among most other salars of the Andes Pastos Grandes features a c 40 square kilometres 15 sq mi carbonate platform with numerous fabrics of carbonate deposition 42 It is unclear what drives its formation as the climate at Pastos Grandes is similar to that of other salt lakes without such platforms 31 but it may be a consequence of carbon dioxide degassing under the salar 43 At numerous points calcite pisoliths are found at Pastos Grandes usually associated with active or former springs 44 Rimstone dams and sinter terraces are also encountered close to inactive springs 45 All these cave formations encountered at Pastos Grandes are caused by the precipitation of calcite from oversaturated waters at the surface What drives the loss of carbon dioxide and thus the oversaturation is not clear but may involve photosynthesis by algae 46 Algae and diatoms grow within the open waters in Pastos Grandes 33 the diatoms being represented by oligohaline species such as some Fragilaria and Navicularia species 30 Different water surfaces are dominated by different diatom species distinctions that are only partly mediated by different salinities 47 Animal species found within the lakes include amphipods elmids and leeches in freshwater and by Cricotopus in saltwater 48 Additional animals are Euplanaria dorotocephala Chironomidae Corixidae Cyclopoida Ephydridae Harpacticoida Orchestidae Ostracoda and Tipulidae species 49 50 Similar but different animal species have been found in other local lakes indicating that they are largely separate systems 51 The animal flora of such Altiplano lakes is not very diverse probably due to their relative youth and the harsh and often highly variable climates of the past in the region 52 Pastos Grandes is one of many endorheic lakes that cover the region 30 The neighbouring Altiplano was formerly covered by lakes as well during the Pleistocene After they dried up the Salar de Uyuni and Salar de Coipasa were left behind 3 Climate editThe area of Pastos Grandes has a summer wet climate with most of the precipitation falling during a wet season in December March An estimate for the total precipitation is about 200 millimetres per year 7 9 in year 3 That is the climate is arid and evaporation rates can reach about 1 400 millimetres per year 55 in year Insolation is high and the temperatures can vary by as much as 15 C 27 F 36 During winter they can drop as far as 25 C 13 F 3 Human exploitation editThe lithium deposits have drawn attention of mining interests with the Bolivian government seeking businesses to exploit the lithium deposits at Pastos Grandes Uyuni and Coipasa 53 References edit a b Francis P W Wells G L 1988 07 01 Landsat Thematic Mapper observations of debris avalanche deposits in the Central Andes Bulletin of Volcanology 50 4 261 Bibcode 1988BVol 50 258F doi 10 1007 BF01047488 ISSN 0258 8900 S2CID 128824938 a b c Baker 1981 p 306 a b c d e f g Risacher amp Eugster 1979 p 255 Risacher amp Eugster 1979 p 268 Salisbury et al 2010 p 9 Baker 1981 p 293 Silva 1989 p 1102 Silva 1989 p 1103 de Silva amp Gosnold 2007 p 321 de Silva amp Gosnold 2007 p 324 Baker 1981 p 312 a b c d e f Kaiser et al 2017 p 74 a b c d e f g Kaiser J F de Silva S L Ort M H Sunagua M 2011 12 01 The Pastos Grandes Caldera Complex of SW Bolivia The building of a composite upper crustal batholith AGU Fall Meeting Abstracts 21 V21C 2509 Bibcode 2011AGUFM V21C2509K a b Kaiser et al 2017 p 75 de Silva amp Gosnold 2007 p 332 Silva et al 2006 p 53 Kaiser et al 2017 p 85 a b Silva 1989 p 1104 a b Salisbury et al 2010 p 12 a b c de Silva amp Gosnold 2007 p 323 a b Francis P W Silva S L De 1989 Application of the Landsat Thematic Mapper to the identification of potentially active volcanoes in the central Andes Remote Sensing of Environment 28 245 255 Bibcode 1989RSEnv 28 245F doi 10 1016 0034 4257 89 90117 x a b Baker 1981 p 307 Salisbury et al 2010 p 2 Silva et al 2006 p 51 de Silva et al 1994 p 17806 de Silva et al 1994 p 17821 Watts et al 1999 p 244 Landrum J T Bennett P C Engel A S Alsina M A Pasten P A Milliken K 2009 04 01 Partitioning geochemistry of arsenic and antimony El Tatio Geyser Field Chile Applied Geochemistry 12th International Symposium on Water Rock Interaction WRI 12 24 4 665 Bibcode 2009ApGC 24 664L doi 10 1016 j apgeochem 2008 12 024 hdl 10533 142624 a b Warren John K 2010 02 01 Evaporites through time Tectonic climatic and eustatic controls in marine and nonmarine deposits Earth Science Reviews 98 3 4 227 Bibcode 2010ESRv 98 217W doi 10 1016 j earscirev 2009 11 004 a b c Servant Vildary 1983 p 249 a b c d e Muller et al 2020 p 222 a b Williams et al 1995 p 66 a b c d e Risacher amp Eugster 1979 p 257 Dejoux 1993 p 258 Watts et al 1999 p 246 a b c Servant Vildary amp Roux 1990 p 268 Risacher amp Eugster 1979 p 256 Muller et al 2020 p 223 Muller et al 2020 p 228 Servant Vildary 1983 p 252 Williams et al 1995 p 69 Muller et al 2020 p 221 Muller et al 2020 p 234 Risacher amp Eugster 1979 p 258 Risacher amp Eugster 1979 p 261 Risacher amp Eugster 1979 p 267 Servant Vildary amp Roux 1990 p 281 Dejoux 1993 p 262 Williams et al 1995 p 71 Dejoux 1993 p 261 Dejoux 1993 p 266 Williams et al 1995 p 74 Poveda Bonilla Rafael 13 May 2022 La gobernanza de las empresas estatales en la industria minera de los paises andinos in Spanish 13 14 a href Template Cite journal html title Template Cite journal cite journal a Cite journal requires journal help Sources edit Baker M C W 1981 The nature and distribution of upper cenozoic ignimbrite centres in the Central Andes Journal of Volcanology and Geothermal Research 11 2 4 293 315 Bibcode 1981JVGR 11 293B doi 10 1016 0377 0273 81 90028 7 Dejoux Claude 1993 09 01 Benthic invertebrates of some saline lakes of the Sud Lipez region Bolivia Hydrobiologia 267 1 3 257 267 doi 10 1007 BF00018807 ISSN 0018 8158 S2CID 23979914 de Silva S L Self S Francis P W Drake R E Carlos Ramirez R 10 September 1994 Effusive silicic volcanism in the Central Andes The Chao dacite and other young lavas of the Altiplano Puna Volcanic Complex PDF Journal of Geophysical Research Solid Earth 99 B9 17805 17825 Bibcode 1994JGR 9917805D doi 10 1029 94JB00652 de Silva Shanaka L Gosnold William D 2007 11 01 Episodic construction of batholiths Insights from the spatiotemporal development of an ignimbrite flare up Journal of Volcanology and Geothermal Research Large Silicic Magma Systems 167 1 4 320 335 Bibcode 2007JVGR 167 320D doi 10 1016 j jvolgeores 2007 07 015 Kaiser Jason F de Silva Shanaka Schmitt Axel K Economos Rita Sunagua Mayel 1 January 2017 Million year melt presence in monotonous intermediate magma for a volcanic plutonic assemblage in the Central Andes Contrasting histories of crystal rich and crystal poor super sized silicic magmas Earth and Planetary Science Letters 457 73 86 Bibcode 2017E amp PSL 457 73K doi 10 1016 j epsl 2016 09 048 ISSN 0012 821X Muller E Gaucher E C Durlet C Moquet J S Moreira M Rouchon V Louvat P Bardoux G Noirez S Bougeault C Vennin E Gerard E Chavez M Virgone A Ader M June 2020 The origin of continental carbonates in Andean salars A multi tracer geochemical approach in Laguna Pastos Grandes Bolivia Geochimica et Cosmochimica Acta 279 220 237 Bibcode 2020GeCoA 279 220M doi 10 1016 j gca 2020 03 020 ISSN 0016 7037 Risacher Francois Eugster Hans P 1979 04 01 Holocene pisoliths and encrustations associated with spring fed surface pools Pastos Grandes Bolivia Sedimentology 26 2 253 270 Bibcode 1979Sedim 26 253R doi 10 1111 j 1365 3091 1979 tb00353 x Salisbury Morgan J Jicha Brian R Silva Shanaka L de Singer Brad S Jimenez Nestor C Ort Michael H 2010 12 21 40Ar 39Ar chronostratigraphy of Altiplano Puna volcanic complex ignimbrites reveals the development of a major magmatic province Geological Society of America Bulletin 123 5 6 821 840 Bibcode 2011GSAB 123 821S doi 10 1130 B30280 1 ISSN 0016 7606 Servant Vildary Simone 1983 Les diatomees des sediments superficiels de quelques lacs sales de Bolivie Sciences Geologiques Bulletin in French 36 4 249 253 doi 10 3406 sgeol 1983 1643 ISSN 0302 2692 Servant Vildary S Roux M 1990 05 01 Multivariate analysis of diatoms and water chemistry in Bolivian saline lakes Hydrobiologia 197 1 267 290 doi 10 1007 BF00026956 ISSN 0018 8158 S2CID 12273039 Silva S L de 1989 12 01 Altiplano Puna volcanic complex of the central Andes Geology 17 12 1102 1106 Bibcode 1989Geo 17 1102D doi 10 1130 0091 7613 1989 017 lt 1102 APVCOT gt 2 3 CO 2 Silva Shanaka De Zandt George Trumbull Robert Viramonte Jose G Salas Guido Jimenez Nestor 2006 01 01 Large ignimbrite eruptions and volcano tectonic depressions in the Central Andes a thermomechanical perspective Geological Society London Special Publications 269 1 47 63 Bibcode 2006GSLSP 269 47D doi 10 1144 GSL SP 2006 269 01 04 ISSN 0305 8719 S2CID 129924955 Watts Robert B Silva Shanaka L de Rios Guillermina Jimenez de Croudace Ian 1999 09 01 Effusive eruption of viscous silicic magma triggered and driven by recharge a case study of the Cerro Chascon Runtu Jarita Dome Complex in Southwest Bolivia Bulletin of Volcanology 61 4 241 264 Bibcode 1999BVol 61 241W doi 10 1007 s004450050274 ISSN 0258 8900 S2CID 56303121 Williams W D Carrick T R Bayly I a E Green J Herbst D B 1995 03 01 Invertebrates in salt lakes of the Bolivian Altiplano International Journal of Salt Lake Research 4 1 65 77 doi 10 1007 BF01992415 ISSN 1037 0544 External links editUnderstanding large resurgent calderas and associated magma systems the Pastos Grandes Caldera Complex southwest Bolivia Retrieved from https en wikipedia org w index php title Pastos Grandes amp oldid 1213194906, wikipedia, wiki, book, books, library,

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