Earth:Quetrupillán

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Short description: Mountain in Chile
Quetrupillán
Volcanoes Quetrupillan and Lanin.jpg
Quetrupillán with Lanín in the background
Highest point
Elevation2,360 m (7,740 ft)
Coordinates [ ⚑ ] 39°30′S 71°42′W / 39.5°S 71.7°W / -39.5; -71.7[1]
Geography
LocationChile
Parent rangeAndes
Geology
Age of rockPleistocene-Holocene[1]
Mountain typeStratovolcano
Volcanic arc/beltSouth Volcanic Zone
Last eruptionJune 1872[1]
Climbing
Easiest routePalguín - Laguna Azul

Quetrupillán ("blunted", "mutilated";[2] also known as Ketropillán;[2] the name is sometimes applied to the neighbouring Lanín volcano.[3]) is a stratovolcano located in Los Ríos Region of Chile . It is situated between Villarrica and Lanín volcanoes, within Villarrica National Park. Geologically, Quetrupillán is located in a tectonic basement block between the main traces of Liquiñe-Ofqui Fault (to the west) and Reigolil-Pirihueico Fault (to the east).

The volcano consists of one stratovolcano with a summit caldera, and is constructed within a field of smaller centres and a larger caldera. It was active during the late Pleistocene; some large eruptions occurred during the Holocene as well.

Geology and geography

The volcano is situated in the Curarrehue, Pucón and Panguipulli municipalities of the Cautín and Valdivia provinces. Towns close to Quetrupillán are Catripulli, Currarehue and Puesco. It is considered Chile's 21st most dangerous volcano.[4] The volcano and its neighbours form part of the Kütralkura geopark[5] and are an important tourism destination.[6]

Regional

Off the western coast of South America, the Nazca Plate subducts beneath the South American Plate in the Peru-Chile Trench. As the plate subducts, it releases water into the overlying mantle and causes it to melt, gives rise to the Southern Volcanic Zone of the Andes. The rate and geometry of subduction has varied over time. During the last six million years, the subduction process has been oblique and as a consequence, the Liquiñe-Ofqui Fault has developed within the volcanic arc and dominates the regional tectonics.[7]

Quetrupillán lies on the border between Los Ríos Region and Araucanía Region,[4][8] in the Southern Volcanic Zone.[8] Together with Villarrica and Lanín it forms a northwest-southeast alignment of volcanoes,[8] which coincides with the Mocha-Villarrica transcurrent fault.[9] The Cordillera El Mocho and Quinquilil volcanoes are likewise situated on this alignment,[10] both are deeply eroded composite volcanoes of small dimensions.[11] Other volcanoes in the Southern Volcanic Zone have similar alignments, such as Nevados de Chillán and Puyehue-Cordón Caulle.[10] In comparison to Villarrica, Quetrupillán has been less active and its eruptions were also smaller than Villarrica's,[12] with no large pyroclastic flows found at Quetrupillán.[11]

Local

Quetrupillán is a 2,360 metres (7,740 ft) high composite stratovolcano[11] and a shrinking glacier cover;[13] the existence of calderas is unconfirmed.[14] The entire edifice has a north-south elongated shape[15] and covers a ground surface of 107 square kilometres (41 sq mi).[4] The volcano contains a field of lava domes, maars and pyroclastic cones that occupy a surface of 400 square kilometres (150 sq mi).[16][11] These subsidiary vents include the scoria cone Huililco, the Volcanes de Llancahue and the Volcanoes de Reyehueico.[1] There are in total 16 lateral vents, of which 12 are found in a volcanic field south of Quetrupillán.[16] Fissure vents of Pleistocene-Holocene age occur on the southern side of the volcano. The small volume of the main Quetrupillán edifice and the widespread vents may reflect the interaction between the volcano and the Liquiñe-Ofqui fault, which generated secondary vents[17] whose location was controlled by the Liquiñe-Ofqui fault, the Mocha-Villarrica fault and local structures.[18] There are two lakes on the southern flank, Laguna Azul to the southwest and Laguna Blanca to the southeast.[14]

A number of eruption products show traces of ice-lava interactions.[17] Tuff rings and maars formed through the interaction of magma with groundwater.[16] A geomagnetic anomaly at shallow depth south of the volcano may be a pluton associated with a resurgent dome.[19] Huililco scoria cone has produced two lava flows and is considered to be also part of the Quetrupillán volcanic complex.[20]

Three different formations make up the basement of Quetrupillán: The Triassic Panguipulli, the possibly Cretaceous Currarehue and the Miocene Trápatrapa formations and plutonic rocks.[10] These are plutonic and volcaniclastic rock units.[20] The Villarrica-Quetrupillán volcanic chain forms a geological boundary, since the Patagonian Batholith crops out south of it.[21] Magnetotelluric investigation of the area has found evidence of a possible deep-seated magma reservoir.[22]

Composition

Volcanic rocks at Quetrupillán have a bimodal composition,[23] ranging from basalt to andesite[11] with trachyte the main component,[24] and overall more silicic than the rocks erupted by Villarrica and Lanín.[1] Unusually for the region, trachydacite also occurs at the volcano. These contain phenocrysts of plagioclase and pyroxene, with additional microphenocrysts of ilmenite and magnetite.[25]

Based on the composition, it has been inferred that the magma reservoir of Quetrupillán contained a mush of crystals, from which magma was repeatedly mobilized following the injection of fresh magmas that reheated the mush.[25] Fractional crystallization of basalts generated trachytic melts.[20] A tectonic regime associated with the Liquiñe-Ofqui Fault which prevents magma from simply ascending to the surface may help the magma evolution processes.[26]

Eruptive history

Eruptive activity at Quetrupillán commenced before the ice ages. The first phase of activity involved the formation of calderas and stratovolcanoes; later during the ice ages lava flows and ignimbrites were emplaced. Finally, the present stratovolcano was emplaced towards the end of glaciation; parasitic vents formed even later[11] and produced lava flows.[20]

Quetrupillán has erupted pyroclastics, which have formed flow and pumice deposits east of the volcano. Several phases of volcanic activity have been inferred from the deposits; most of them feature either pumiceous or scoriaceous pyroclastic flow deposits with varying contents of juvenile lapilli, lithics and ash fall deposits.[8]

  • The Moraga sequence was formed 12,720 ± 40 – 12,690 ± 40 years Before Present (BP) during one rather prolonged eruption.[27]
  • The Puala sequence was formed 10,240 ± 40 years BP.[12]
  • The Trancura sequence was formed 8,680 ± 40 years BP and has a similar composition to the Avutardas sequence.[12]
  • The Carén sequence was formed 3,800 ± 30 years BP.[12]
  • The Correntoso sequence was formed 2,930 ± 30 years BP.[12]
  • The Trancas Negras sequence was formed 2,060 ± 30 years BP.[12]
  • The Puesco sequence was formed 1,650 ± 70 years BP, during the largest known eruption of Quetrupillán. This eruption created a 25 kilometres (16 mi) high eruption column and deposited about 0.26 cubic kilometres (0.062 cu mi) of rock.[12] A volcanic explosivity index of 4 has been assigned to this event.[28]
  • The Carén sequence was formed 1,380 ± 30 years BP, it is the youngest explosive eruption of Quetrupillán.[12]

In addition, three tephras in neighbouring lakes dated to 16,748–16,189, 15,597–12,582 and 12,708–12,567 years Before Present may originate from Quetrupillán but they have also been attributed to Sollipulli. All these tephras are of rhyolitic to rhyodacitic composition and the eruptions that generated them have an estimated volcanic explosivity index of 3.[28]

Reports exist of eruptions during the 19th century,[11] one eruption was reported in 1872.[1] Explosive activity has a recurrence interval of about 1,200 years, which given the age of the last event carries significant implications with regards to the volcanic hazard of Quetrupillán.[12]

Mythology

According to a tale from Mapuche mythology, originally there were just two volcanoes: Choshuenco and Lanín. Then the volcano Ruka Pillan (Villarrica) fought the other two volcanoes in a century-long conflict; eventually Ruka Pillan was victorious, coinciding with the beginning Spain conquest.[29]

Climate and vegetation

Annual precipitation exceeds 1,800 millimetres (71 in), with a mean annual temperature of 7.5 °C (45.5 °F). The slopes of Quetrupillán are covered by temperate forests, with Nothofagus trees being the most important species; other trees are the tepa and the maniú hembra.[30] (As of 1961), vegetation on Quetrupillán included Araucaria araucana and Nothofagus antarctica forests, as well as puna-like vegetation.[31]

See also

  • List of volcanoes in Chile

References

  1. 1.0 1.1 1.2 1.3 1.4 1.5 "Quetrupillan". Smithsonian Institution. https://volcano.si.edu/volcano.cfm?vn=357121. 
  2. 2.0 2.1 Huiliñir-Curío, Viviana (2018). "De senderos a paisajes: paisajes de las movilidades de una comunidad mapuche en los Andes del sur de Chile". Chungará (Arica) 50 (3): 487–499. doi:10.4067/S0717-73562018005001301. ISSN 0717-7356. 
  3. Vilariño, Martín; Ayelén, Ibarra Mendoza (2022). "UN ESCUDO, MUCHAS HISTORIAS: TENSIONES EN TORNO A LA REPRESENTACIÓN SIMBÓLICA DEL VOLCÁN LANÍN" (in es). Cuadernos del Instituto Nacional de Antropología y Pensamiento Latinoamericano–Series Especiales 10 (1): 429. doi:10.5281/zenodo.7694088. ISSN 2362-1958. 
  4. 4.0 4.1 4.2 "Complejo Volcánico Quetrupillán" (in es). https://rnvv.sernageomin.cl/complejo-volcanico-quetrupillan/. 
  5. Schilling, Manuel Enrique; Contreras, María Angélica; Farías, Cristian; Tascón, Gabriela; Partarrieu, Diego (April 2023). "Geoparque Mundial UNESCO Kütralkura: Laboratorio natural para la educación sobre los peligros volcánicos". Repositorio Institucional INGEMMET. https://repositorio.ingemmet.gob.pe/handle/20.500.12544/4552. 
  6. Rivera Merino, Maria Nicol; Sepúlveda Arriagada, Leslie Viviana; Silva Carrasco, Claudia Andrea; Rivera Merino, Maria Nicol; Sepúlveda Arriagada, Leslie Viviana; Silva Carrasco, Claudia Andrea (December 2022). "El cambio climático y su influencia en las fluctuaciones del turismo en Chile". Revista interamericana de ambiente y turismo 18 (2): 118–136. doi:10.4067/S0718-235X2022000200118. ISSN 0718-235X. https://www.scielo.cl/scielo.php?pid=S0718-235X2022000200118&script=sci_arttext&tlng=pt. 
  7. Simmons et al. 2020, pp. 1-2.
  8. 8.0 8.1 8.2 8.3 Toloza & Moreno 2015, p. 574.
  9. Balbis et al. 2022, p. 2.
  10. 10.0 10.1 10.2 Moreno, López-Escobar & Cembrano 1994, p. 339.
  11. 11.0 11.1 11.2 11.3 11.4 11.5 11.6 Moreno, López-Escobar & Cembrano 1994, p. 340.
  12. 12.0 12.1 12.2 12.3 12.4 12.5 12.6 12.7 12.8 Toloza & Moreno 2015, p. 575.
  13. Huggel, Christian; Rivera, Andrés; Granados, Hugo Delgado; Paul, Frank; Reinthaler, Johannes (2019). "Area changes of glaciers on active volcanoes in Latin America between 1986 and 2015 observed from multi-temporal satellite imagery" (in en). Journal of Glaciology 65 (252): 9. doi:10.1017/jog.2019.30. ISSN 0022-1430. Bibcode2019JGlac..65..542R. 
  14. 14.0 14.1 Simmons et al. 2020, p. 3.
  15. Simmons et al. 2020, p. 13.
  16. 16.0 16.1 16.2 Simmons et al. 2020, p. 2.
  17. 17.0 17.1 McGarvie, Dave (October 2014). "GLACIOVOLCANISM AT VOLCÁN QUETRUPILLÁN, CHILE". https://gsa.confex.com/gsa/2014AM/finalprogram/abstract_245951.htm. 
  18. Balbis et al. 2022, p. 15.
  19. Delgado 2012, p. 625.
  20. 20.0 20.1 20.2 20.3 Brahm, Raimundo; Parada, Miguel Angel; Morgado, Eduardo; Contreras, Claudio; McGee, Lucy Emma (May 2018). "Origin of Holocene trachyte lavas of the Quetrupillán volcanic complex, Chile: Examples of residual melts in a rejuvenated crystalline mush reservoir" (in en). Journal of Volcanology and Geothermal Research 357: 163–176. doi:10.1016/j.jvolgeores.2018.04.020. ISSN 0377-0273. Bibcode2018JVGR..357..163B. 
  21. Daniele, Linda; Taucare, Matías; Viguier, Benoît; Arancibia, Gloria; Aravena, Diego; Roquer, Tomás; Sepúlveda, Josefa; Molina, Eduardo et al. (1 November 2020). "Exploring the shallow geothermal resources in the Chilean Southern Volcanic Zone: Insight from the Liquiñe thermal springs" (in en). Journal of Geochemical Exploration 218: 106611. doi:10.1016/j.gexplo.2020.106611. ISSN 0375-6742. Bibcode2020JCExp.21806611D. https://www.sciencedirect.com/science/article/pii/S0375674220302491. 
  22. Pavez et al. 2023, p. 4.
  23. Delgado 2012, p. 624.
  24. Pavez et al. 2023, p. 3.
  25. 25.0 25.1 Brahm, R.; Parada, M. Á.; Morgado, E. E.; Contreras, C. (2015-12-01). "Pre-eruptive rejuvenations of crystalline mush by reservoir heating: the case of trachy-dacitic lavas of Quetrupillán Volcanic Complex, Chile (39º30' lat. S)". AGU Fall Meeting Abstracts 43: V43B–3122. Bibcode2015AGUFM.V43B3122B. 
  26. Simmons et al. 2020, p. 16.
  27. Toloza & Moreno 2015, pp. 574-575.
  28. 28.0 28.1 Fontijn, Karen; Rawson, Harriet; Van Daele, Maarten; Moernaut, Jasper; Abarzúa, Ana M.; Heirman, Katrien; Bertrand, Sébastien; Pyle, David M. et al. (2016-04-01). "Synchronisation of sedimentary records using tephra: A postglacial tephrochronological model for the Chilean Lake District". Quaternary Science Reviews 137: 238. doi:10.1016/j.quascirev.2016.02.015. Bibcode2016QSRv..137..234F. 
  29. Salazar, Gonzalo; Riquelme Maulén, Wladimir (22 October 2020). "The Space-Time Compression of Indigenous Toponymy: The Case of Mapuche Toponymy in Chilean Norpatagonia". Geographical Review 112 (5): 21. doi:10.1080/00167428.2020.1839898. ISSN 0016-7428. https://www.tandfonline.com/doi/full/10.1080/00167428.2020.1839898. 
  30. Escobar, Álvaro (December 2022). "Nidificación de Peuquito en los Bosques Templados de la Araucanía Andina" (in es). La Chiricoca (Fundación Mar Adentro) 29: 40. http://www.lachiricoca.cl/wp-content/uploads/2023/03/La-Chiricoca-29-Nidificaci%C3%B3n-de-Peuquito-en-los-Bosques-Templados-de-la-Araucan%C3%ADa-Andina.pdf. 
  31. Allgemeine Vegetationsgeographie. De Gruyter. 1961-12-31. pp. 123,126. doi:10.1515/9783111616728. ISBN 978-3-11-161672-8. https://www.degruyter.com/document/doi/10.1515/9783111616728/html. 

Sources