Earth:Jotabeche
Template:Coord/display/intitle Jotabeche is a Miocene-Pliocene caldera in the Atacama Region of Chile . It is part of the volcanic Andes, more specifically of the extreme southern end of the Central Volcanic Zone (CVZ). This sector of the Andean Volcanic Belt contains about 44 volcanic centres and numerous more minor volcanic systems, as well as some caldera and ignimbrite systems. Jotabeche is located in a now inactive segment of the CVZ, the Maricunga Belt.
Jotabeche formed from the subduction of the Nazca plate beneath the South America plate, like the other volcanoes in the CVZ and the Andean Volcanic Belt. In the region of Jotabeche, during the late Miocene and Pliocene a change in the subduction geometry has caused volcanism to end, with volcanism shifting eastwards to the Incapillo volcanic centre. The crust beneath Jotabeche is 70 kilometres (43 mi) thick, which has had effects on the rock composition of the volcano.
Jotabeche has erupted two major ignimbrites between 8,500,000 and 5,900,000 years ago. The first ignimbrite was the larger one and is named Negro Francisco and the second is called Jotabeche proper. A caldera and some lava domes are also part of the complex. Volcanism ceased 5 million years ago.
Geography and structure
Jotabeche is located at the extreme southern end of the Central Volcanic Zone (CVZ) of the Andes.[1] The Central Volcanic Zone is one of the four volcanic zones of the Andean Volcanic Belt. In this belt, ongoing subduction of the Antarctica plate, Nazca plate and its precursor the Farallon plate are responsible for ongoing volcanic activity, including such volcanoes as Villarrica and Nevado del Ruiz. The Central Volcanic Zone sub-belt itself contains about 44 volcanic centres and over five major Quaternary caldera and ignimbrite complexes. The so-called Abancay deflection separates the CVZ in the north from the Peruvian flat subduction segment where no volcanic activity occurs, while the southern limit is marked by a seismic discontinuity around 27° S.[2]
Jotabeche is a 5,862 metres (19,232 ft) high volcano with a caldera.[3] A rhyolitic dome formed inside of the caldera. The Jotabeche complex reaches a thickness of 500 metres (1,600 ft) when including ignimbrite, lava domes and lavas.[4] The 5,432 metres (17,822 ft) high and 4 kilometres (2.5 mi) wide Jotabeche Norte stratovolcano is found northeast of Jotabeche and is surrounded by pyroclastic flows. The Santa Cecilia lava domes ( [ ⚑ ] 27°41′S 69°19.5′W / 27.683°S 69.325°W) have diameters of 1.5 kilometres (0.93 mi) and sit along a 4 kilometres (2.5 mi) long fault.[3] The Miocene volcanic complex branches out in four chains stretching in east-west direction, the Cadillal, Aguas Blancas, Jotabeche Norte and Cordon de Yeguas Heladas.[1] N-S to NE-SW trending faults border the volcanic complex and have allowed the intrusion of diorite porphyries. The resulting hydrothermally altered rocks are the sites of mineral deposits and prospects.[5] These faults include the Yeguas Heladas, Rio La Gallina and Rio Astaburuaga and form a hexagonal structure which partly forms the margin of the caldera.[3] Otherwise, only little erosion has taken place at Jotabeche;[6] stronger erosion though has exposed a >1 kilometre (0.62 mi) thick hydrothermally altered complex at Aldebaran-Cerro Casale.[7] Other hydrothermally altered areas are found within depressions.[1] The crust beneath Jotabeche reaches a thickness of 60 kilometres (37 mi).[3]
Geology
Jotabeche is a volcanic centre in the 26-6 mya old and 200 kilometres (120 mi) long Maricunga belt. Some stratovolcanoes in the belt include Copiapó-Azufre, Cerros Bravos, Doña Inés, La Laguna, Lagunillas, Ojos del Maricunga, Santa Rosa and Cadillal-Yeguas Heladas. Volcanic activity in this belt has also generated porphyry deposits containing Ag, Au and Cu.[8] This belt is bordered by graben and horst tectonic structures that have generated the Salar de Maricunga and the Laguna de Negro Francisco.[6]
Jotabeche is located at the southern end of the Maricunga belt, which was active starting from the Oligocene until the Pliocene. The formation of this volcanic belt was influenced by the changes in the subduction of the Nazca plate, which included the shallowing of the subducting plate and the formation of the Puna plateau.[9] Jotabeche, belonging to the fourth stage of Maricunga belt activity after the third stage of Copiapo,[10] is the youngest eruption of the Maricunga belt, whose activity ended with the Jotabeche caldera forming eruption. Volcanism afterwards shifted eastwards.[11] Jotabeche is one of the largest volcanoes in the Maricunga belt.[6] Volcanic activity at Jotabeche is coeval with the last mineralization phase of the Vallecito system in the El Indio belt.[12]
Local
Jotabeche is part of the so-called Cordillera de Darwin segment of the Andes.[13] The basement in the area consists of various sedimentary-volcanic formations dating back to the Paleozoic Chinches formation but also including the Jurassic Lautaro formation and the Cretaceous Quebrada de Monardes formation.[14] Of the volcanic formations, the Pantanoso rhyolitic formation of the Paleozoic and the thick andesitic-dacitic lava flows of the mesozoic Rio Aguas Blancas formation are the most important. During the Cretaceous, local extension formed a number of small faults in the area.[1] The oldest of these sequences crops out east of Jotabeche at the Chilean-Argentine frontier.[15]
Composition
Jotabeche has generated rhyodacite rocks.[9] The Negro Francisco ignimbrite is rhyolitic while the Jotabeche ignimbrite itself is of rhyodacitic composition.[4] Specific SiO2 concentrations are 65–70% for Negro Francisco while the caldera complex has 68–72%. The Jotabeche Norte stratovolcano has a concentration of 60% and is considered to be hornblende andesite in terms of composition. Overall, all rocks fit the K rich calc alkaline pattern.[3] Au-rich porphyry deposits are found on Jotabeche's flanks. Diorites are also found but the only weak erosion and thick late Miocene rock cover bury them.[5] Other mineralizations are found between Jotabeche and the Salar de Maricunga.[7]
The chemistry of Jotabeche ignimbrites is distinct from other Tertiary volcanic rocks in the Andes.[3] The rocks of Jotabeche have La, Sr and Y concentrations which fit an eclogitic trend, similar to other Andean volcanoes Pircas Negras, Tortolas and Vallecito.[16] More generally, the geochemistry is indicative of the volcanic activity being influenced both by a thick crust and other factors of crustal contamination.[9] Other composition data are indicative of a drop in mantle water content above the shallowing slab.[8] The crust above the Jotabeche ignimbrite source region was thick enough to permit the stability of garnet in said source region.[17]
Glaciation
Jotabeche does not currently display any perennial snow, only during summer is snow observed in the area. Likewise, rock glaciers are only found as fossil remnants.[18] However, moraines are found at Jotabeche,[14] and glaciers advanced north from a cirque on its northern flank into the Laguna de Negro Francisco, where a peninsula marks the position of the most extensive moraine.[19]
Eruptive history
Jotabeche was active between 7 and 5 mya ago, spanning the late Miocene and Pliocene.[9] The end of volcanic activity at Jotabeche occurred at the same time as the northeastern arm of the Juan Fernandez ridge passed beneath the volcano.[20] After end of activity at Jotabeche volcanism occurred farther east at Incapillo.[11] 15.3 ± 0.8 and 17.2 ± 0.7 mya the Las Gallinas ignimbrite formed east of Jotabeche, but its origin is unknown.[4]
The Santa Cecilia domes of Jotabeche were active 24.3 ± 0.7 mya and 24.1 ± 0.8 mya based on potassium-argon dating of an eroded tuff ring. Between 18 and 16 mya the Jotabeche Norte stratovolcano was active in the region.[3] Some rhyolitic lava domes intruded into the caldera are 10 mya old.[1] The Negro Francisco ignimbrite was erupted 8.5 mya ago and covers a surface area of 39.05 square kilometres (15.08 sq mi) around the Laguna del Negro Francisco; it is the initial activity of Jotabeche. 5.9–6.2 mya the Jotabeche ignimbrite covered a surface area of 3.18 square kilometres (1.23 sq mi).[4] The Negro Francisco ignimbrite was erupted from a NW-trending fault and flowed between the Jotabeche Norte and La Laguna stratovolcanoes to the Laguna del Negro Francisco depression and across it.[3] The so-called Pircas Negras andesitic lava flows occur at the same time as the younger Jotabeche activity.[20] Andesitic-dacitic lava domes along the La Gallina fault are of the same age.[1]
At Copiapo and Jotabeche, the volcanic activity has been subdivided in three phases, the first being the "normal" volcanic phase, a second phase with a drop in magma supply and the formation of more differentiated magmas in crustal magma chambers such as rhyolites and at the end the eruption of andesites along fractures. Other volcanoes in the Maricunga belt display different evolutionary processes, probably because of a lesser tectonic influence.[1]
Archeology
Research performed on Jotabeche in the 1980s demonstrated the existence of a shrine on Jotabeche. People probably climbed the mountain to use it during the southern summer months. Archeological sites in the region are not unknown: Copiapo, Incahuasi, Pastillitos and Los Patos also have archeological sites.[21]
See also
References
- ↑ 1.0 1.1 1.2 1.3 1.4 1.5 1.6 Mpodozis, C.; Allmendinger, R.; Jordan, T. (1991). "La zona del Nevado de Jotabeche y la Laguna de Negro Francisco: Evolucion tectonica y volcanica de la extremidad meridional del altiplano chileno" (in es). 6th Chilean Geological Congress. pp. 91–95. http://biblioteca.sernageomin.cl/opac/DataFiles/5881pp91_95.pdf. Retrieved 13 June 2016.
- ↑ Stern, Charles R. (December 2004). "Active Andean volcanism: its geologic and tectonic setting". Revista Geológica de Chile 31 (2). doi:10.4067/S0716-02082004000200001.
- ↑ 3.0 3.1 3.2 3.3 3.4 3.5 3.6 3.7 Kay, Suzanne Mahlburg; Mpodozis, Constantino; Tittler, Andrew; Cornejo, Paula (December 1994). "Tertiary Magmatic Evolution of the Maricunga Mineral Belt in Chile". International Geology Review 36 (12): 1079–1112. doi:10.1080/00206819409465506. Bibcode: 1994IGRv...36.1079K.
- ↑ 4.0 4.1 4.2 4.3 Guzmán, Silvina; Grosse, Pablo; Montero-López, Carolina; Hongn, Fernando; Pilger, Rex; Petrinovic, Ivan; Seggiaro, Raúl; Aramayo, Alejandro (December 2014). "Spatial–temporal distribution of explosive volcanism in the 25–28°S segment of the Andean Central Volcanic Zone". Tectonophysics 636: 170–189. doi:10.1016/j.tecto.2014.08.013. Bibcode: 2014Tectp.636..170G.
- ↑ 5.0 5.1 Palacios, CarlosM.; Townley, BrianC.; Lahsen, AlfredoA.; Egaña, AntonioM. (December 1993). "Geological development and mineralization in the Atacama segment of the South American Andes, northern Chile (26°15'-27°25'S)". Geologische Rundschau 82 (4): 652. doi:10.1007/BF00191492. Bibcode: 1993GeoRu..82..652P.
- ↑ 6.0 6.1 6.2 Vila, T.; Sillitoe, R. H. (1 October 1991). "Gold-rich porphyry systems in the Maricunga Belt, northern Chile". Economic Geology 86 (6): 1238–1260. doi:10.2113/gsecongeo.86.6.1238.
- ↑ 7.0 7.1 Davidson, J.; Mpodozis, C. (1 October 1991). "Regional geologic setting of epithermal gold deposits, Chile". Economic Geology 86 (6): 1174–1186. doi:10.2113/gsecongeo.86.6.1174.
- ↑ 8.0 8.1 Kay, S. M.; Mpodozis, C.; Gardeweg, M. (7 August 2013). "Magma sources and tectonic setting of Central Andean andesites (25.5-28 S) related to crustal thickening, forearc subduction erosion and delamination". Geological Society, London, Special Publications 385 (1): 303–334. doi:10.1144/SP385.11. Bibcode: 2014GSLSP.385..303K.
- ↑ 9.0 9.1 9.2 9.3 Kay, Suzanne Mahlburg; Coira, Beatriz; Mpodozis, Constantino (2008). "Field trip guide: Neogene evolution of the central Andean Puna plateau and southern Central Volcanic Zone". GSA Field Guide 13: Field Trip Guides to the Backbone of the Americas in the Southern and Central Andes: Ridge Collision, Shallow Subduction, and Plateau Uplift. 13. pp. 117–181. doi:10.1130/2008.0013(05). ISBN 978-0-8137-0013-7.
- ↑ Muntean, J. L.; Einaudi, M. T. (1 November 2000). "Porphyry Gold Deposits of the Refugio District, MaricungaBelt, Northern Chile". Economic Geology 95 (7): 1445–1472. doi:10.2113/gsecongeo.95.7.1445.
- ↑ 11.0 11.1 Goss, A.R.; Kay, S.M.; Mpodozis, C.; Singer, B.S. (July 2009). "The Incapillo Caldera and Dome Complex (∼28° S, Central Andes): A stranded magma chamber over a dying arc". Journal of Volcanology and Geothermal Research 184 (3–4): 389–404. doi:10.1016/j.jvolgeores.2009.05.005. Bibcode: 2009JVGR..184..389G.
- ↑ Clavero, Jorge; Martin, Mark; Mpodozis, Constantino; Cuitino, Lucia (1997). "Eventos de alteraction-mineralizacion en la franja El Indio (29–30 S): Nuevos antecedentes geologicos y geocronologicos" (in es). 8th Chilean Geological Congress. p. 899. http://biblioserver.sernageomin.cl/opac/DataFiles/8457pp896_900.pdf. Retrieved 13 June 2016.
- ↑ Gonzalez-Ferran, O.; Baker, P.E.; Rex, D.C. (March 1985). "Tectonic-volcanic discontinuity at latitude 27° south Andean Range, associated with Nazca Plate Subduction". Tectonophysics 112 (1–4): 423–441. doi:10.1016/0040-1951(85)90189-1. Bibcode: 1985Tectp.112..423G.
- ↑ 14.0 14.1 Toro G., J.C.; Gonzalez, E. (2000). "CASPICHE. MODELO DE UN PORFIDO DE Au-Cu FRANJA DE MARICUNGA" (in es). Puerto Varas: 9th Chilean Geological Congress. http://biblioserver.sernageomin.cl/opac/DataFiles/10072v1pp400_402.pdf. Retrieved 13 June 2016.
- ↑ Mpodozis, Constantino; Cornejo, Paula; Kay, Suzanne M.; Tittler, Andrew (1995). "La Franja de Maricunga: sintesis de la evolucion del Frente Volcanico Oligoceno-Mioceno de la zona sur de los Andes Centrales". Andean Geology 22 (2): 273–313. http://www.andeangeology.cl/index.php/revista1/article/view/1489. Retrieved 13 June 2016.
- ↑ Wang, Qiang; Xu, Ji-Feng; Zhao, Zhen-Hua; Bao, Zhi-Wei; Xu, Wei; Xiong, Xiao-Lin (2004). "Cretaceous high-potassium intrusive rocks in the Yueshan-Hongzhen area of east China: Adakites in an extensional tectonic regime within a continent". Geochemical Journal 38 (5): 428. doi:10.2343/geochemj.38.417. Bibcode: 2004GeocJ..38..417W.
- ↑ Trumbull, R.B; Wittenbrink, R; Hahne, K; Emmermann, R; Büsch, W; Gerstenberger, H; Siebel, W (March 1999). "Evidence for Late Miocene to Recent contamination of arc andesites by crustal melts in the Chilean Andes (25–26°S) and its geodynamic implications". Journal of South American Earth Sciences 12 (2): 135–155. doi:10.1016/S0895-9811(99)00011-5. Bibcode: 1999JSAES..12..135T.
- ↑ Haselton, Kirk; Hilley, George; Strecker, Manfred R. (March 2002). "Average Pleistocene Climatic Patterns in the Southern Central Andes: Controls on Mountain Glaciation and Paleoclimate Implications". The Journal of Geology 110 (2): 211–226. doi:10.1086/338414. Bibcode: 2002JG....110..211H. http://pangea.stanford.edu/~hilley/REPRINTS/Haseltonetal2002.pdf. Retrieved 13 June 2016.
- ↑ Jenny, Bettina; Kammer, Klaus (1996) (in de). Climate Change in den trockenen Anden. Verlag des Geographischen Institutes der Universität Bern. p. 67. ISBN 3906151034.
- ↑ 20.0 20.1 Mahlburg Kay, Suzanne; Mpodozis, Constantino (April 2002). "Magmatism as a probe to the Neogene shallowing of the Nazca plate beneath the modern Chilean flat-slab". Journal of South American Earth Sciences 15 (1): 39–57. doi:10.1016/S0895-9811(02)00005-6. Bibcode: 2002JSAES..15...39M.
- ↑ Moyano, Ricardo (2009). "El adoratorio del cerro El Potro: Arqueología de alta montaña en la cordillera de Copiapó, norte de Chile" (in es). Estudios Atacameños (38). doi:10.4067/S0718-10432009000200004. ISSN 0718-1043. http://revistas.ucn.cl/index.php/estudios-atacamenos/article/view/344.
External links
- Sergio Gamonal 2015, Volcanic stratigraphy and epithermal mineralization of the La Coipa district, Maricunga belt, Chile
- Alexander Brenning 2005, Climatic and geomorphological controls of rock glaciers in the Andes of Central Chile – combining statistical modelling and field mapping