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Galán

January 01, 1970

For the town in Colombia, see Galán, Santander. For the commune in France, see Galan, Hautes-Pyrénées.

Cerro Galán is a caldera in the Catamarca Province of Argentina. It is one of the largest exposed calderas in the world and forms part of the Central Volcanic Zone of the Andes, one of the three volcanic belts found in South America. One of several major caldera systems in the Central Volcanic Zone, the mountain is grouped into the Altiplano–Puna volcanic complex.

Galán
Galán viewed from space
Highest point
Elevation6,100 m (20,000 ft)
Coordinates25°56′S 66°55′W / 25.93°S 66.92°W / -25.93; -66.92[1]
Geography
Galán
Location in Argentina
LocationCatamarca Province, Argentina
Parent rangeAndes
Geology
Age of rock2.08 ± 0.02 million years
Mountain typeCaldera
Last eruptionUnknown

Volcanic activity at Galán is the indirect consequence of the subduction of the Nazca Plate beneath the South America Plate, and involves the infiltration of melts into the crust and the formation of secondary magmas which after storage in the crust give rise to the dacitic to rhyodacitic rocks erupted by the volcano.

Galán was active between 5.6 and 4.51 million years ago, when it generated a number of ignimbrites known as the Toconquis group which crop out mainly west of the caldera. The largest eruption of Galán was 2.08 ± 0.02 million years ago and was the source of the Galán ignimbrite, which covered the surroundings of the caldera with volcanic material. The volume of this ignimbrite has been estimated to be about 650 cubic kilometres (160 cu mi); after this eruption much smaller ignimbrite eruptions took place and presently two hot springs are active in the caldera.

Geography and geomorphology edit

The Galán caldera lies in the northwestern Catamarca Province of Argentina and was discovered in 1975 in a remote region of the Andes,[2] using satellite images.[3] The town of Antofagasta de la Sierra lies west-southwest of the Galán caldera,[4] Tacuil is almost due northeast from the caldera and El Penon southwest of the volcano.[5] The caldera is difficult to access.[6] An Inka tambo was situated at Laguna Diamante,[7][8] and an important prehistoric travel route passed through the caldera.[9] Sacrificial offers were given on the summit of Galán.[10]

Galán is part of the Central Volcanic Zone of the Andes,[11][12] which lies on the western margin of South America,[13] where the Nazca Plate subducts beneath the South America Plate. There are about 50 volcanoes with recent activity in the Central Volcanic Zone, and additional volcanoes exist in the Northern Volcanic Zone and the Southern Volcanic Zone, two other volcanic belts north and south.[14]

The volcanic arc runs along the borders between Bolivia and Argentina with Chile, and behind the volcanic arc lies a chain of silicic[a] volcanoes, of which Galán is a southern member.[16] The whole region has been subject to substantial ignimbrite-forming volcanism with many eruptions producing volumes of rock larger than 100 cubic kilometres (24 cu mi), although the actual vents often are only visible from space imagery.[17] Many vents cluster in an area known as the Altiplano-Puna volcanic complex which occupies a surface of about 70,000 square kilometres (27,000 sq mi)[13] approximately 200 kilometres (120 mi) north of Galán,[18] and which includes the large calderas of La Pacana, Cerro Guacha, Pastos Grandes and Cerro Panizos as well as more recent geothermal systems.[19] This volcanism appears to be a surface expression of a pluton,[20] and at depths of 17–19 kilometres (11–12 mi) beneath the Altiplano-Puna volcanic complex electrical, gravity and seismic tomography data have localized a structure of partially molten rock called the "Altiplano Puna Magma Body".[b][22] Volcanism in this "back" region may not be directly related to subduction processes despite the region itself being close to a subducting margin.[23]

The Galán caldera lies on the eastern margin of the Andes, where the Sierras Pampeanas begin.[24] The region is characterized by the Puna, a high plateau similar to Tibet in Asia.[25]

Local edit

 
The Galán caldera from the inside

Galán is a caldera with topographic dimensions of 38 by 26 kilometres (24 mi × 16 mi), of which about 26 by 18 kilometres (16 mi × 11 mi) are part of the caldera proper.[26] Such dimensions make Galán one of the biggest calderas on Earth;[18] it has been described as a supervolcano.[27] The floor of the caldera reaches an elevation of 4,500 metres (14,800 ft)[2][17] or about 4,600 metres (15,100 ft),[28] and the whole caldera has an elliptical shape[17] extending in the north–south direction.[29] Only the western margin of the caldera structure appears to be a true caldera margin, however,[30] with different landforms forming the rest of the caldera walls[31] and the actual collapse caldera covering only a portion of the topographic caldera expression;[32] the latter has been defined to be a volcano-tectonic depression.[33]

The caldera contains a resurgent dome,[34][35] whose highest point[2] in the frost-shattered Galán massif[36] reaches an elevation of about 5,912 metres (19,396 ft)[37]-6,100 metres (20,000 ft).[28] Seismic tomography has identified a slow-speed anomaly beneath Galán, which has a volume of about 22,000 cubic kilometres (5,300 cu mi) and is considered to be a magma reservoir of the volcano.[38]

Summits along the caldera margin include Cerro Aguas Calientes (a lava dome[39]) to the north, Cerro Leon Muerto to the southeast, Cerro Pabellon to the southwest and Cerro Toconquis to the northwest.[4] On the western rim, elevations of 5,200 metres (17,100 ft) are reached.[29] Younger volcanoes have developed on the western and northern rim of the Galán caldera.[35]

Hydrology edit

The caldera contains a 7 by 3 kilometres (4.3 mi × 1.9 mi) lake[40] in its southwestern corner,[35][41] which is known as Laguna Diamante[4] and may formerly have occupied much of the caldera.[42] Laguna Diamante has gained attention among scientists for the extreme environmental conditions that life within the lake has to withstand, including high arsenic contents of the waters and high insolation with ultraviolet radiation.[43][44] The water is hyper-alkaline and five times as salty as the sea but supports microorganisms which form microbial mats and provide food for a colony of flamingos.[43] Tube-shaped microbialites have also been reported.[37] A smaller lake known as Laguna Pabellon lies just south of Laguna Diamante. North of the resurgent dome, the Rio Aguas Calientes drains the caldera northward, while east of it the Rio Leon Muerto runs eastward out of the caldera.[4]

Rivers in the caldera and neighbourhood display river terraces which may reflect pre-caldera formation uplift of the terrain and uplift associated with the resurgent dome.[45] These drainages eventually converge in the Rio de Los Patos and end into the Salar del Hombre Muerto north of Galán.[46][47] The high Cerro Galán intercepts moisture transported from east, thus nourishing the Rio de Los Patos in a region where long permanent watercourses are unusual.[48] The western flanks of the caldera drain into the Antofagasta de la Sierra valley through a number of drainages such as Rio Punilla, Rio Toconquis, Rio Miriguaca, Rio Las Pitas; the waters eventually end into the Laguna Antofagasta south of Antofagasta de la Sierra.[49] Two hot springs are found within the caldera, the first close to its northern end and the second on the southwestern foot of the resurgent dome,[50] both emitting water with temperatures of about 56–85 °C (133–185 °F).[51] The first one is known as the Aguas Calientes hydrothermal spring and features deposits of tufa[30] and boiling water.[52] Another geothermal system is known as La Colcha and includes fumaroles as well as boiling water and sinter deposits; it has been prospected for the possibility of geothermal power generation.[53]

Geology edit

The basement beneath the caldera consists of 600–365 million years old metamorphic[54] and sedimentary rocks of Precambrian to Paleozoic age.[55] These include intrusions of granitoid character and are overlain with Paleozoic marine sediments.[56] Ordovician units are also present[57] and form sediment layers up to 7 kilometres (4.3 mi) thick.[17] Basements outcrops occur in the northeastern margin of the caldera.[58]

About 14.5 million years ago volcanic activity started in the region, first west of Galán but by 7 million years ago it shifted to the future caldera, forming the Cerro Colorado, Pabellon and Cerro Toconquis composite volcanoes on its future western rim.[54] The more westerly centres are today represented by eroded volcanoes.[59] Since about 6.6 million years ago the volcanic activity produced rocks of both mafic[c] and silicic compositions.[55] The increase of volcanic activity has been attributed to the steepening of the Nazca Plate slab which allowed mantle material to penetrate into the space between the lower crust and the slab.[61] North of 21° degrees southern latitude ignimbritic volcanism started earlier, generating the Altos de Pica and Oxaya formations.[62]

Mafic volcanism occurred south and west of Galán both before its large eruption and afterwards, in the valley of Antofagasta de la Sierra and may have continued to less than ten thousand years ago.[54] The positions of the exact vents are controlled by recent fault systems in the region.[63]

Since about 10 million years ago, the area has been subject to reverse faulting which has disrupted the basement along north–south lines,[57] forming a rift valley that also stretches from north to south.[17] The magma erupted by the Galán system was likewise channelled along such fault systems,[64][65] and neighbouring volcanoes were similarly influenced by them;[65] the fault systems at Galán proper are known as the Diablillos-Galán faults.[26][66] Another major lineament in the area is the Archibarca lineament, which is formed by a strike-slip fault that extends from the northwest to the southeast in the region[3] and which intersects the Diablillos-Galán faults at the location of the caldera.[66]

Composition edit

Galán has erupted mainly potassium-rich dacitic to rhyolitic rocks that are often called rhyodacitic,[67] and which reflect a calc-alkaline suite.[45] Each ignimbrite has usually a uniform composition but there is some variation between individual ignimbrites;[68] for example older rocks contain amphibole and younger rocks instead sanidine.[69] Minerals contained in the eruption products include allanite, apatite, biotite, hornblende, ilmenite, magnetite, orthopyroxene, plagioclase, quartz, sanidine and zircon. Hydrothermal alteration has left calcite in some rocks.[68] Trace element patterns are distinct in the Galán ignimbrite in comparison to the Toconquis Group rocks.[70]

The formation of the Galán magma has been explained with melting of lower crustal rocks under the influence of rising basaltic magmas that supplied the heat needed for the melting processes, and which also directly contributed to magma formation through mixing events.[71] Further metasomatism in the crust and fractional crystallization processes completed the magma genesis process.[72] Probably under the influence of larger scale tectonics, magma that accumulated into a mid-crustal mush zone is eventually transferred into shallow magma chambers at depths of 8–4 kilometres (5.0–2.5 mi);[73] recharge events where deep magma entered the shallow magma bodies may have triggered eruptions at Galán.[74] After eruption, a leftover pluton would have been generated inside the crust.[75]

Based on the presence of two separate populations of pumice in the Galán ignimbrite it has been inferred that there were two types of magma in the magmatic system during the Galán eruption, a larger volume of so-called "white" magma and a "grey" magma which was injected into the "white" magma pool and eventually rose above the latter.[76] More generally, it appears that before each eruption there were two batches of magma present beneath the volcano[74] which however were very similar owing perhaps to a homogenization process that took place deep in the crust.[77] Before the eruption, the magma is estimated to have been 790–820 °C (1,450–1,510 °F) hot.[69]

Climate and biology edit

Galán lies in a region of arid climate, with annual precipitation amounting to about 65 millimetres per year (2.6 in/year).[78] Frosts occur year-round.[79] Climate data are known for Salar de Hombre Muerto north of Galán; average temperatures there are 8–23 °C (46–73 °F) in summer and winter, respectively. Precipitation occurs mostly during the summer months.[46]

At high elevations there is no vegetation.[79] Between 3,900–5,000 metres (12,800–16,400 ft) elevation, vegetation consists of high altitude steppe dominated by Poaceae (grasses) such as Festuca (fescue) and Stipa (feather grass). At lower altitudes, wetlands have their own vegetation.[49] In sheltered areas birds like ducks and flamingos can be observed.[52]

Eruptive history edit

Volcanic activity at Galán occurred in two separate stages,[54] which are separated by an erosional unconformity[80][28] during which the ignimbrite apron of the Toconquis group was incised by deep valleys.[81] Mechanistically, the onset of the eruptions has been explained with delamination events during which parts of the lower crust broke off, asthenospheric material replaced the crust lost by delamination and basaltic magmas penetrated the remaining crust.[82][83]

These stages have left an ignimbrite plateau that surrounds the caldera[4] except on its southern side, and which is noticeable on satellite images.[28] It covers a surface area of about 3,500 square kilometres (1,400 sq mi)[17] and is the largest ignimbrite system in the Puna plateau.[84]

Toconquis Group edit

The first stage occurred between 5.60 and 4.51 million years ago and consisted of the eruption of large ignimbrites such as the[22] Blanco,[80] Cueva Negra,[54] several Merihuaca ignimbrites[63] and Real Grande ignimbrite as well as lava domes, all from north–south trending fractures,[80][54] forming the Toconquis Group (formerly called the Toconquis Formation).[85] The Real Grande and Cueva Negra ignimbrites were considered to be homologous, as are the easterly Leon Muerto and several Merihuaca ignimbrites,[86] but it was later found that the Leon Muerto and Merihuaca ignimbrites probably were erupted from distinct vent systems and have distinct compositions,[87] and the Cueva Negra ignimbrite was later considered to be a separate formation from the other Toconquis group ignimbrites.[88] The later classifications established a 6.5 – 5.5 million-year-old Blanco/Merihuaca ignimbrites, 4.8 million-year-old Pitas, 4.7 million-year-old Real Grande, 4.5 million-year-old Vega and 3.8 million-year-old Cueva Negra ignimbrite.[55]

The formation is fairly heterogeneous, with some ignimbrites separated by sharp contacts and the degree of welding and crystal content of pumices varies from one ignimbrite to the other.[63] Generally the ignimbrites are rich in crystals and pumice, are unwelded and contain few flow structures,[89] with the exception of the welded Cueva Negra ignimbrite.[88] Some ignimbrite eruptions were preceded by the formation of Plinian eruption columns that generated ash fallout, and there is evidence for pulsating flow in the ignimbrites.[90]

On the northern side of the Galán complex, ignimbrites extend up to 80 kilometres (50 mi) away from the caldera and may have reached even larger distances prior to erosion,[88] and they have thicknesses of 300 metres (980 ft).[91] The ignimbrites have a total volume of about 650 cubic kilometres (160 cu mi), with the Real Grande ignimbrite comprising over half of its volume.[34][92] The volume of the individual ignimbrites increases the younger they are[93] with the initial Blanco and Merihuaca ignimbrites having a volume of about 70 cubic kilometres (17 cu mi).[92]

The last eruption may have generated a caldera that was later obliterated.[94] Emission of lava flows occurred during the Toconquis phase as well,[95] in general there was vigorous volcanic activity between the eruptions that formed the main ignimbrites.[96] The Cueva Negra ignimbrite was emplaced after the Toconquis Group, and small lava domes and pyroclastic flows continued to be erupted until the Galán ignimbrite proper.[97] The magmatic system shallowed during this time, resulting in composition changes of the erupted ignimbrites[98] and a general increase of elevations in the region.[99]

Galán ignimbrite edit

2.08 ± 0.02 million years ago[34][100] the rhyodacitic[101] Galán ignimbrite proper was emplaced. Aside from a facies that remained inside the caldera and is minimally 1.4 kilometres (0.87 mi) thick,[54][64] ignimbrites extend outside of the caldera to distances of 80 kilometres (50 mi)[88] but with an average runout distance of 40 square kilometres (15 sq mi)[102] and have thicknesses of 200–10 metres (656–33 ft);[54][64] closer to the caldera it has been largely eroded away and there are more complete exposures farther away from Galán.[103] A contrary view is that the Galán ignimbrite was largely eroded only on its northern side by wind action, forming yardangs.[92] The resurgent dome consists of Galán ignimbrite material, along with basement rocks.[31] The "Toba Dacitica" 270 kilometres (170 mi) outcrop away from the volcano was once considered part of the Galán eruption but later compositional differences were found.[104]

The Galán ignimbrite is fairly homogeneous and has a high crystal content;[63] overall it appears that the eruption commenced and reached large dimensions fairly quickly without leaving time for an eruption column or distinct flow units to form, except in some places.[105][106][100] Conversely, the produced flows were relatively slow flows[107] that had little capacity to pass above topographic obstacles or to move rocks around.[108] It nevertheless spread over large distances, since the topography of the region had been flattened by the previous Toconquis ignimbrites,[109] and was still hot by the time it came to a standstill.[110] Pumice is scarce and usually present in only small fragments, and lithic fragments are also uncommon except at the bases of the deposit. Fiamme structures on the other hand are fairly common especially where the ignimbrite crossed river valleys. The ignimbrite displays varying degrees of welding but has often spectacular columnar joints.[28][111]

At first it was assumed that this ignimbrite crops out over a surface of 7,500 square kilometres (2,900 sq mi) but later it was found that it covers a surface closer to 2,400 square kilometres (930 sq mi).[88] Between the intracaldera ignimbrite, the parts of the ignimbrite that extend away from the caldera and outcrops at large distance, the volume is about 650 cubic kilometres (160 cu mi),[92] down from earlier estimated of volumes exceeding 1,000 cubic kilometres (240 cu mi)[96] but the Galán eruption is still one of the biggest known volcanic eruptions[100] and the volcano has produced almost half of the volume of ignimbrites in the southern Puna.[112] The Galán ignimbrite is the largest ignimbrite erupted by this centre;[26] there is a tendency of the volume of individual ignimbrites to increase as the volcanoes grow younger, not only at Galán but also at other Puna ignimbrite centres, and this may be a consequence of progressive changes in the crust.[113] Such giant eruptions have not been observed during historical time and are considered to be among the most dangerous volcanic phenomena known.[114]

Kay et al. proposed that the Galán ignimbrite consisted of three separate units, an intracaldera one emplaced 2.13 million years ago and two extracaldera ones 2.09 and 2.06 million years ago.[75]

Post-Galán volcanism edit

The main Galán caldera formed during the Galán ignimbrite eruption,[94] and it is possible that the collapse of the magma chamber roof actually started the eruption.[106] Later it was found that a trapdoor collapse is a more plausible interpretation of the caldera structure[30] and that the caldera appears to be much smaller than its present-day topographic expression.[32] Most likely a lake formed within the caldera after its eruption.[115][41]

Later volcanic activity resulted in lava flows of dacitic composition being erupted along the ring fault of the caldera, as well as the formation of the resurgent dome by about 2 kilometres (1.2 mi) uplift along the eastern caldera margin fault.[54] This uplift encompasses both Galán ignimbrite rocks but also parts of the basement, the latter especially in the southern part of the dome.[31] Post-caldera volcanism occurred on the northern margin of the caldera 2.01 ± 0.28 million years ago,[116] and several small ignimbrites were emplaced after the main Galán eruption until less than 2 million years ago.[102] These ignimbrites have similar compositions to the Galán ignimbrite[117] and were formed from magma left over by the main Galán eruption.[118] The onset of resurgence within the caldera may have been triggered by the same magma that is responsible for the post-caldera volcanism along the eastern caldera rims.[115] The post-caldera volcanic systems appear to be rather ill-defined, however. The most recent activity was of tectonic nature and consists of movements along the faults and mafic volcanism ("Incahuasi Formation"[119]) farther west.[41][113] Seismic tomography indicates that there is still a melt zone under Galán,[120] the "Cerro Galán Mush Body".[121] An earthquake swarm was recorded on the 25 January 2009 mainly under the resurgent dome, and may reflect hydrothermal or magmatic activity.[122]

See also edit

Notes edit

  1. ^ Silicic volcanic rocks are volcanic rocks such as dacite and rhyolite that contain at least 63% silicon dioxide. Volcanoes erupting such rocks tend to undergo explosive eruptions.[15]
  2. ^ The "Altiplano Puna Magma Body" is a layer underneath the Altiplano that consists of large amounts of molten magma, with a volume of about 10,000 cubic kilometres (2,400 cu mi).[21]
  3. ^ A volcanic rock relatively rich in iron and magnesium, relative to silicon.[60]

References edit

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  4. ^ a b c d e Sparks et al. 1985, p. 211.
  5. ^ Folkes et al. 2011, p. 1431.
  6. ^ HONGN et al. 2001, p. 76.
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  122. ^ Mulcahy, Patrick; Chen, Chen; Kay, Suzanne M.; Brown, Larry D.; Isacks, Bryan L.; Sandvol, Eric; Heit, Benjamin; Yuan, Xiaohui; Coira, Beatriz L. (August 2014). "Central Andean mantle and crustal seismicity beneath the Southern Puna plateau and the northern margin of the Chilean-Pampean flat slab". Tectonics. 33 (8): 1654–1655. Bibcode:2014Tecto..33.1636M. doi:10.1002/2013TC003393. hdl:11336/35932. S2CID 129847828.

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  • Farías, María Eugenia, ed. (2020). Microbial Ecosystems in Central Andes Extreme Environments: Biofilms, Microbial Mats, Microbialites and Endoevaporites. Cham: Springer International Publishing. doi:10.1007/978-3-030-36192-1. ISBN 978-3-030-36191-4. S2CID 218912960.
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  • Francis, P. W.; O'Callaghan, L.; Kretzschmar, G. A.; Thorpe, R. S.; Sparks, R. S. J.; Page, R. N.; Barrio, R. E. de; Gillou, G.; Gonzalez, O. E. (1983). "The Cerro Galan ignimbrite". Nature. 301 (5895): 51–53. Bibcode:1983Natur.301...51F. doi:10.1038/301051a0. ISSN 1476-4687. S2CID 4252925.
  • Francis, P. W.; Sparks, R. S. J.; Hawkesworth, C. J.; Thorpe, R. S.; Pyle, D. M.; Tait, S. R.; Mantovani, M. S.; McDermott, F. (1989). "Petrology and geochemistry of volcanic rocks of the Cerro Galan caldera, northwest Argentina". Geological Magazine. 126 (5): 515–547. Bibcode:1989GeoM..126..515F. doi:10.1017/S0016756800022834. ISSN 1469-5081. S2CID 128614585.
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  • Grocke, Stephanie B.; Andrews, Benjamin J.; de Silva, Shanaka L. (November 2017). "Experimental and petrological constraints on long-term magma dynamics and post-climactic eruptions at the Cerro Galán caldera system, NW Argentina". Journal of Volcanology and Geothermal Research. 347: 296–311. Bibcode:2017JVGR..347..296G. doi:10.1016/j.jvolgeores.2017.09.021. ISSN 0377-0273.
  • HONGN, D.; SEGGIARO, R.E.; MONALDI, C.R.; ALONSO, R.N.; GONZÁLEZ, R.E.; IGARZÁBAL, A.P.; RAMALLO, E.; GODEAS, M.; FUERTES, A.; GARCÍA, R.; MOYA, F.; GONZÁLEZ, O. (2001). Hoja Geológica 2566-III, Cachi. Provincias de Salta y Catamarca (Report). Boletín 248 (in Spanish). Buenos Aires: Instituto de Geología y Recursos Minerales, Servicio Geológico Minero Argentino.
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  • Lesti, Chiara; Porreca, Massimiliano; Giordano, Guido; Mattei, Massimo; Cas, Raymond A. F.; Wright, Heather M. N.; Folkes, Chris B.; Viramonte, Josè (1 December 2011). "High-temperature emplacement of the Cerro Galán and Toconquis Group ignimbrites (Puna plateau, NW Argentina) determined by TRM analyses". Bulletin of Volcanology. 73 (10): 1535–1565. Bibcode:2011BVol...73.1535L. doi:10.1007/s00445-011-0536-2. ISSN 0258-8900. S2CID 128626947.
  • Puente, Verónica; Martel, Álvaro (September 2023). "Cerámica internodal: Aportes a las interacciones entre la Puna meridional y los Valles Calchaquíes (Argentina)". Latin American Antiquity. 34 (3): 569–588. doi:10.1017/laq.2022.49. S2CID 251996977.
  • Silva, S. L. de (1 December 1989). "Altiplano-Puna volcanic complex of the central Andes". Geology. 17 (12): 1102. Bibcode:1989Geo....17.1102D. doi:10.1130/0091-7613(1989)017<1102:APVCOT>2.3.CO;2. ISSN 0091-7613.
  • Sparks, R.S.J.; Francis, P.W.; Hamer, R.D.; Pankhurst, R.J.; O'Callaghan, L.O.; Thorpe, R.S.; Page, R. (May 1985). "Ignimbrites of the Cerro Galan caldera, NW Argentina". Journal of Volcanology and Geothermal Research. 24 (3–4): 205–248. Bibcode:1985JVGR...24..205S. doi:10.1016/0377-0273(85)90071-X. ISSN 0377-0273.
  • Wright, Heather M. N.; Folkes, Chris B.; Cas, Raymond A. F.; Cashman, Katharine V. (1 December 2011). "Heterogeneous pumice populations in the 2.08-Ma Cerro Galán Ignimbrite: implications for magma recharge and ascent preceding a large-volume silicic eruption". Bulletin of Volcanology. 73 (10): 1513–1533. Bibcode:2011BVol...73.1513W. doi:10.1007/s00445-011-0525-5. ISSN 0258-8900. S2CID 129628410.

Further reading edit

  • Cerro Galan Caldera 2017-02-18 at the Wayback Machine Oregon State University
  • , from How Volcanoes Work, by Vic Camp, Department of Geological Sciences, San Diego State University
  • "Cerro Galán". Global Volcanism Program. Smithsonian Institution.
  • Ben G. Mason; David M. Pyle; Clive Oppenheimer (2004). "The size and frequency of the largest explosive eruptions on Earth". Bulletin of Volcanology. 66 (8): 735–748. Bibcode:2004BVol...66..735M. doi:10.1007/s00445-004-0355-9. S2CID 129680497.

January 01, 1970
galán, town, colombia, santander, commune, france, galan, hautes, pyrénées, cerro, caldera, catamarca, province, argentina, largest, exposed, calderas, world, forms, part, central, volcanic, zone, andes, three, volcanic, belts, found, south, america, several, . For the town in Colombia see Galan Santander For the commune in France see Galan Hautes Pyrenees Cerro Galan is a caldera in the Catamarca Province of Argentina It is one of the largest exposed calderas in the world and forms part of the Central Volcanic Zone of the Andes one of the three volcanic belts found in South America One of several major caldera systems in the Central Volcanic Zone the mountain is grouped into the Altiplano Puna volcanic complex GalanGalan viewed from spaceHighest pointElevation6 100 m 20 000 ft Coordinates25 56 S 66 55 W 25 93 S 66 92 W 25 93 66 92 1 GeographyGalanLocation in ArgentinaLocationCatamarca Province ArgentinaParent rangeAndesGeologyAge of rock2 08 0 02 million yearsMountain typeCalderaLast eruptionUnknown Volcanic activity at Galan is the indirect consequence of the subduction of the Nazca Plate beneath the South America Plate and involves the infiltration of melts into the crust and the formation of secondary magmas which after storage in the crust give rise to the dacitic to rhyodacitic rocks erupted by the volcano Galan was active between 5 6 and 4 51 million years ago when it generated a number of ignimbrites known as the Toconquis group which crop out mainly west of the caldera The largest eruption of Galan was 2 08 0 02 million years ago and was the source of the Galan ignimbrite which covered the surroundings of the caldera with volcanic material The volume of this ignimbrite has been estimated to be about 650 cubic kilometres 160 cu mi after this eruption much smaller ignimbrite eruptions took place and presently two hot springs are active in the caldera Contents 1 Geography and geomorphology 1 1 Local 1 2 Hydrology 2 Geology 2 1 Composition 3 Climate and biology 4 Eruptive history 4 1 Toconquis Group 4 2 Galan ignimbrite 4 3 Post Galan volcanism 5 See also 6 Notes 7 References 7 1 Bibliography 8 Further readingGeography and geomorphology editThe Galan caldera lies in the northwestern Catamarca Province of Argentina and was discovered in 1975 in a remote region of the Andes 2 using satellite images 3 The town of Antofagasta de la Sierra lies west southwest of the Galan caldera 4 Tacuil is almost due northeast from the caldera and El Penon southwest of the volcano 5 The caldera is difficult to access 6 An Inka tambo was situated at Laguna Diamante 7 8 and an important prehistoric travel route passed through the caldera 9 Sacrificial offers were given on the summit of Galan 10 Galan is part of the Central Volcanic Zone of the Andes 11 12 which lies on the western margin of South America 13 where the Nazca Plate subducts beneath the South America Plate There are about 50 volcanoes with recent activity in the Central Volcanic Zone and additional volcanoes exist in the Northern Volcanic Zone and the Southern Volcanic Zone two other volcanic belts north and south 14 The volcanic arc runs along the borders between Bolivia and Argentina with Chile and behind the volcanic arc lies a chain of silicic a volcanoes of which Galan is a southern member 16 The whole region has been subject to substantial ignimbrite forming volcanism with many eruptions producing volumes of rock larger than 100 cubic kilometres 24 cu mi although the actual vents often are only visible from space imagery 17 Many vents cluster in an area known as the Altiplano Puna volcanic complex which occupies a surface of about 70 000 square kilometres 27 000 sq mi 13 approximately 200 kilometres 120 mi north of Galan 18 and which includes the large calderas of La Pacana Cerro Guacha Pastos Grandes and Cerro Panizos as well as more recent geothermal systems 19 This volcanism appears to be a surface expression of a pluton 20 and at depths of 17 19 kilometres 11 12 mi beneath the Altiplano Puna volcanic complex electrical gravity and seismic tomography data have localized a structure of partially molten rock called the Altiplano Puna Magma Body b 22 Volcanism in this back region may not be directly related to subduction processes despite the region itself being close to a subducting margin 23 The Galan caldera lies on the eastern margin of the Andes where the Sierras Pampeanas begin 24 The region is characterized by the Puna a high plateau similar to Tibet in Asia 25 Local edit nbsp The Galan caldera from the inside Galan is a caldera with topographic dimensions of 38 by 26 kilometres 24 mi 16 mi of which about 26 by 18 kilometres 16 mi 11 mi are part of the caldera proper 26 Such dimensions make Galan one of the biggest calderas on Earth 18 it has been described as a supervolcano 27 The floor of the caldera reaches an elevation of 4 500 metres 14 800 ft 2 17 or about 4 600 metres 15 100 ft 28 and the whole caldera has an elliptical shape 17 extending in the north south direction 29 Only the western margin of the caldera structure appears to be a true caldera margin however 30 with different landforms forming the rest of the caldera walls 31 and the actual collapse caldera covering only a portion of the topographic caldera expression 32 the latter has been defined to be a volcano tectonic depression 33 The caldera contains a resurgent dome 34 35 whose highest point 2 in the frost shattered Galan massif 36 reaches an elevation of about 5 912 metres 19 396 ft 37 6 100 metres 20 000 ft 28 Seismic tomography has identified a slow speed anomaly beneath Galan which has a volume of about 22 000 cubic kilometres 5 300 cu mi and is considered to be a magma reservoir of the volcano 38 Summits along the caldera margin include Cerro Aguas Calientes a lava dome 39 to the north Cerro Leon Muerto to the southeast Cerro Pabellon to the southwest and Cerro Toconquis to the northwest 4 On the western rim elevations of 5 200 metres 17 100 ft are reached 29 Younger volcanoes have developed on the western and northern rim of the Galan caldera 35 Hydrology edit The caldera contains a 7 by 3 kilometres 4 3 mi 1 9 mi lake 40 in its southwestern corner 35 41 which is known as Laguna Diamante 4 and may formerly have occupied much of the caldera 42 Laguna Diamante has gained attention among scientists for the extreme environmental conditions that life within the lake has to withstand including high arsenic contents of the waters and high insolation with ultraviolet radiation 43 44 The water is hyper alkaline and five times as salty as the sea but supports microorganisms which form microbial mats and provide food for a colony of flamingos 43 Tube shaped microbialites have also been reported 37 A smaller lake known as Laguna Pabellon lies just south of Laguna Diamante North of the resurgent dome the Rio Aguas Calientes drains the caldera northward while east of it the Rio Leon Muerto runs eastward out of the caldera 4 Rivers in the caldera and neighbourhood display river terraces which may reflect pre caldera formation uplift of the terrain and uplift associated with the resurgent dome 45 These drainages eventually converge in the Rio de Los Patos and end into the Salar del Hombre Muerto north of Galan 46 47 The high Cerro Galan intercepts moisture transported from east thus nourishing the Rio de Los Patos in a region where long permanent watercourses are unusual 48 The western flanks of the caldera drain into the Antofagasta de la Sierra valley through a number of drainages such as Rio Punilla Rio Toconquis Rio Miriguaca Rio Las Pitas the waters eventually end into the Laguna Antofagasta south of Antofagasta de la Sierra 49 Two hot springs are found within the caldera the first close to its northern end and the second on the southwestern foot of the resurgent dome 50 both emitting water with temperatures of about 56 85 C 133 185 F 51 The first one is known as the Aguas Calientes hydrothermal spring and features deposits of tufa 30 and boiling water 52 Another geothermal system is known as La Colcha and includes fumaroles as well as boiling water and sinter deposits it has been prospected for the possibility of geothermal power generation 53 Geology editThe basement beneath the caldera consists of 600 365 million years old metamorphic 54 and sedimentary rocks of Precambrian to Paleozoic age 55 These include intrusions of granitoid character and are overlain with Paleozoic marine sediments 56 Ordovician units are also present 57 and form sediment layers up to 7 kilometres 4 3 mi thick 17 Basements outcrops occur in the northeastern margin of the caldera 58 About 14 5 million years ago volcanic activity started in the region first west of Galan but by 7 million years ago it shifted to the future caldera forming the Cerro Colorado Pabellon and Cerro Toconquis composite volcanoes on its future western rim 54 The more westerly centres are today represented by eroded volcanoes 59 Since about 6 6 million years ago the volcanic activity produced rocks of both mafic c and silicic compositions 55 The increase of volcanic activity has been attributed to the steepening of the Nazca Plate slab which allowed mantle material to penetrate into the space between the lower crust and the slab 61 North of 21 degrees southern latitude ignimbritic volcanism started earlier generating the Altos de Pica and Oxaya formations 62 Mafic volcanism occurred south and west of Galan both before its large eruption and afterwards in the valley of Antofagasta de la Sierra and may have continued to less than ten thousand years ago 54 The positions of the exact vents are controlled by recent fault systems in the region 63 Since about 10 million years ago the area has been subject to reverse faulting which has disrupted the basement along north south lines 57 forming a rift valley that also stretches from north to south 17 The magma erupted by the Galan system was likewise channelled along such fault systems 64 65 and neighbouring volcanoes were similarly influenced by them 65 the fault systems at Galan proper are known as the Diablillos Galan faults 26 66 Another major lineament in the area is the Archibarca lineament which is formed by a strike slip fault that extends from the northwest to the southeast in the region 3 and which intersects the Diablillos Galan faults at the location of the caldera 66 Composition edit Galan has erupted mainly potassium rich dacitic to rhyolitic rocks that are often called rhyodacitic 67 and which reflect a calc alkaline suite 45 Each ignimbrite has usually a uniform composition but there is some variation between individual ignimbrites 68 for example older rocks contain amphibole and younger rocks instead sanidine 69 Minerals contained in the eruption products include allanite apatite biotite hornblende ilmenite magnetite orthopyroxene plagioclase quartz sanidine and zircon Hydrothermal alteration has left calcite in some rocks 68 Trace element patterns are distinct in the Galan ignimbrite in comparison to the Toconquis Group rocks 70 The formation of the Galan magma has been explained with melting of lower crustal rocks under the influence of rising basaltic magmas that supplied the heat needed for the melting processes and which also directly contributed to magma formation through mixing events 71 Further metasomatism in the crust and fractional crystallization processes completed the magma genesis process 72 Probably under the influence of larger scale tectonics magma that accumulated into a mid crustal mush zone is eventually transferred into shallow magma chambers at depths of 8 4 kilometres 5 0 2 5 mi 73 recharge events where deep magma entered the shallow magma bodies may have triggered eruptions at Galan 74 After eruption a leftover pluton would have been generated inside the crust 75 Based on the presence of two separate populations of pumice in the Galan ignimbrite it has been inferred that there were two types of magma in the magmatic system during the Galan eruption a larger volume of so called white magma and a grey magma which was injected into the white magma pool and eventually rose above the latter 76 More generally it appears that before each eruption there were two batches of magma present beneath the volcano 74 which however were very similar owing perhaps to a homogenization process that took place deep in the crust 77 Before the eruption the magma is estimated to have been 790 820 C 1 450 1 510 F hot 69 Climate and biology editGalan lies in a region of arid climate with annual precipitation amounting to about 65 millimetres per year 2 6 in year 78 Frosts occur year round 79 Climate data are known for Salar de Hombre Muerto north of Galan average temperatures there are 8 23 C 46 73 F in summer and winter respectively Precipitation occurs mostly during the summer months 46 At high elevations there is no vegetation 79 Between 3 900 5 000 metres 12 800 16 400 ft elevation vegetation consists of high altitude steppe dominated by Poaceae grasses such as Festuca fescue and Stipa feather grass At lower altitudes wetlands have their own vegetation 49 In sheltered areas birds like ducks and flamingos can be observed 52 Eruptive history editVolcanic activity at Galan occurred in two separate stages 54 which are separated by an erosional unconformity 80 28 during which the ignimbrite apron of the Toconquis group was incised by deep valleys 81 Mechanistically the onset of the eruptions has been explained with delamination events during which parts of the lower crust broke off asthenospheric material replaced the crust lost by delamination and basaltic magmas penetrated the remaining crust 82 83 These stages have left an ignimbrite plateau that surrounds the caldera 4 except on its southern side and which is noticeable on satellite images 28 It covers a surface area of about 3 500 square kilometres 1 400 sq mi 17 and is the largest ignimbrite system in the Puna plateau 84 Toconquis Group edit The first stage occurred between 5 60 and 4 51 million years ago and consisted of the eruption of large ignimbrites such as the 22 Blanco 80 Cueva Negra 54 several Merihuaca ignimbrites 63 and Real Grande ignimbrite as well as lava domes all from north south trending fractures 80 54 forming the Toconquis Group formerly called the Toconquis Formation 85 The Real Grande and Cueva Negra ignimbrites were considered to be homologous as are the easterly Leon Muerto and several Merihuaca ignimbrites 86 but it was later found that the Leon Muerto and Merihuaca ignimbrites probably were erupted from distinct vent systems and have distinct compositions 87 and the Cueva Negra ignimbrite was later considered to be a separate formation from the other Toconquis group ignimbrites 88 The later classifications established a 6 5 5 5 million year old Blanco Merihuaca ignimbrites 4 8 million year old Pitas 4 7 million year old Real Grande 4 5 million year old Vega and 3 8 million year old Cueva Negra ignimbrite 55 The formation is fairly heterogeneous with some ignimbrites separated by sharp contacts and the degree of welding and crystal content of pumices varies from one ignimbrite to the other 63 Generally the ignimbrites are rich in crystals and pumice are unwelded and contain few flow structures 89 with the exception of the welded Cueva Negra ignimbrite 88 Some ignimbrite eruptions were preceded by the formation of Plinian eruption columns that generated ash fallout and there is evidence for pulsating flow in the ignimbrites 90 On the northern side of the Galan complex ignimbrites extend up to 80 kilometres 50 mi away from the caldera and may have reached even larger distances prior to erosion 88 and they have thicknesses of 300 metres 980 ft 91 The ignimbrites have a total volume of about 650 cubic kilometres 160 cu mi with the Real Grande ignimbrite comprising over half of its volume 34 92 The volume of the individual ignimbrites increases the younger they are 93 with the initial Blanco and Merihuaca ignimbrites having a volume of about 70 cubic kilometres 17 cu mi 92 The last eruption may have generated a caldera that was later obliterated 94 Emission of lava flows occurred during the Toconquis phase as well 95 in general there was vigorous volcanic activity between the eruptions that formed the main ignimbrites 96 The Cueva Negra ignimbrite was emplaced after the Toconquis Group and small lava domes and pyroclastic flows continued to be erupted until the Galan ignimbrite proper 97 The magmatic system shallowed during this time resulting in composition changes of the erupted ignimbrites 98 and a general increase of elevations in the region 99 Galan ignimbrite edit 2 08 0 02 million years ago 34 100 the rhyodacitic 101 Galan ignimbrite proper was emplaced Aside from a facies that remained inside the caldera and is minimally 1 4 kilometres 0 87 mi thick 54 64 ignimbrites extend outside of the caldera to distances of 80 kilometres 50 mi 88 but with an average runout distance of 40 square kilometres 15 sq mi 102 and have thicknesses of 200 10 metres 656 33 ft 54 64 closer to the caldera it has been largely eroded away and there are more complete exposures farther away from Galan 103 A contrary view is that the Galan ignimbrite was largely eroded only on its northern side by wind action forming yardangs 92 The resurgent dome consists of Galan ignimbrite material along with basement rocks 31 The Toba Dacitica 270 kilometres 170 mi outcrop away from the volcano was once considered part of the Galan eruption but later compositional differences were found 104 The Galan ignimbrite is fairly homogeneous and has a high crystal content 63 overall it appears that the eruption commenced and reached large dimensions fairly quickly without leaving time for an eruption column or distinct flow units to form except in some places 105 106 100 Conversely the produced flows were relatively slow flows 107 that had little capacity to pass above topographic obstacles or to move rocks around 108 It nevertheless spread over large distances since the topography of the region had been flattened by the previous Toconquis ignimbrites 109 and was still hot by the time it came to a standstill 110 Pumice is scarce and usually present in only small fragments and lithic fragments are also uncommon except at the bases of the deposit Fiamme structures on the other hand are fairly common especially where the ignimbrite crossed river valleys The ignimbrite displays varying degrees of welding but has often spectacular columnar joints 28 111 At first it was assumed that this ignimbrite crops out over a surface of 7 500 square kilometres 2 900 sq mi but later it was found that it covers a surface closer to 2 400 square kilometres 930 sq mi 88 Between the intracaldera ignimbrite the parts of the ignimbrite that extend away from the caldera and outcrops at large distance the volume is about 650 cubic kilometres 160 cu mi 92 down from earlier estimated of volumes exceeding 1 000 cubic kilometres 240 cu mi 96 but the Galan eruption is still one of the biggest known volcanic eruptions 100 and the volcano has produced almost half of the volume of ignimbrites in the southern Puna 112 The Galan ignimbrite is the largest ignimbrite erupted by this centre 26 there is a tendency of the volume of individual ignimbrites to increase as the volcanoes grow younger not only at Galan but also at other Puna ignimbrite centres and this may be a consequence of progressive changes in the crust 113 Such giant eruptions have not been observed during historical time and are considered to be among the most dangerous volcanic phenomena known 114 Kay et al proposed that the Galan ignimbrite consisted of three separate units an intracaldera one emplaced 2 13 million years ago and two extracaldera ones 2 09 and 2 06 million years ago 75 Post Galan volcanism edit The main Galan caldera formed during the Galan ignimbrite eruption 94 and it is possible that the collapse of the magma chamber roof actually started the eruption 106 Later it was found that a trapdoor collapse is a more plausible interpretation of the caldera structure 30 and that the caldera appears to be much smaller than its present day topographic expression 32 Most likely a lake formed within the caldera after its eruption 115 41 Later volcanic activity resulted in lava flows of dacitic composition being erupted along the ring fault of the caldera as well as the formation of the resurgent dome by about 2 kilometres 1 2 mi uplift along the eastern caldera margin fault 54 This uplift encompasses both Galan ignimbrite rocks but also parts of the basement the latter especially in the southern part of the dome 31 Post caldera volcanism occurred on the northern margin of the caldera 2 01 0 28 million years ago 116 and several small ignimbrites were emplaced after the main Galan eruption until less than 2 million years ago 102 These ignimbrites have similar compositions to the Galan ignimbrite 117 and were formed from magma left over by the main Galan eruption 118 The onset of resurgence within the caldera may have been triggered by the same magma that is responsible for the post caldera volcanism along the eastern caldera rims 115 The post caldera volcanic systems appear to be rather ill defined however The most recent activity was of tectonic nature and consists of movements along the faults and mafic volcanism Incahuasi Formation 119 farther west 41 113 Seismic tomography indicates that there is still a melt zone under Galan 120 the Cerro Galan Mush Body 121 An earthquake swarm was recorded on the 25 January 2009 mainly under the resurgent dome and may reflect hydrothermal or magmatic activity 122 See also edit nbsp Andes portal Cerro Beltran List of volcanoes in ArgentinaNotes edit Silicic volcanic rocks are volcanic rocks such as dacite and rhyolite that contain at least 63 silicon dioxide Volcanoes erupting such rocks tend to undergo explosive eruptions 15 The Altiplano Puna Magma Body is a layer underneath the Altiplano that consists of large amounts of molten magma with a volume of about 10 000 cubic kilometres 2 400 cu mi 21 A volcanic rock relatively rich in iron and magnesium relative to silicon 60 References edit Cerro Galan Global Volcanism Program Smithsonian Institution Retrieved 10 October 2018 a b c Sparks et al 1985 p 206 a b Folkes et al 2011 p 1429 a b c d e Sparks et al 1985 p 211 Folkes et al 2011 p 1431 HONGN et al 2001 p 76 Williams Veronica Villegas Paula Williams Veronica Villegas Paula 2017 Rutas y senderos prehispanicos como paisajes Las quebradas altas del valle Calchaqui Medio Salta Boletin del Museo Chileno de Arte Precolombino 22 1 71 94 doi 10 4067 S0718 68942017005000201 hdl 11336 63253 ISSN 0718 6894 S2CID 186178862 OLIVERA DANIEL ENZO TCHILINGUIRIAN PABLO CASANOVA MENENDEZ MARTIN TOMAS PEREZ MARTINA INES GRANT JENNIFER GENTILE MARIA CECILIA CLUR ALEJO DE ZELA PAULA MIRANDA 2023 Tamberias El Peinado y Laguna Diamante mineria inka y circulaciond de bienes en la Puna meridional argentina XXI Congreso Nacional de Arqueologia Argentina in Spanish Corrientes Puente amp Martel 2023 p 570 Perez Martina Ines Clur Alejo Adrian Zela Paula Miranda De Olivera Daniel Perez Martina Ines Clur Alejo Adrian Zela Paula Miranda De Olivera Daniel May 2023 Resultados iniciales del analisis del primer enterratorio inkaico contextualizado en Antofagasta de la Sierra Puna meridional argentina Relaciones 48 13 14 doi 10 24215 18521479e049 ISSN 1852 1479 Folkes et al 2011 p 1456 Folkes et al 2011 p 1427 a b Folkes et al 2011 p 1428 Silva 1989 p 1102 silicic Glossay USGS Retrieved 6 September 2018 Sparks et al 1985 p 206 207 a b c d e f Francis et al 1978 p 749 a b Lesti et al 2011 p 1537 Silva 1989 p 1104 Francis et al 1989 p 515 Chmielowski Josef Zandt George Haberland Christian 15 March 1999 The Central Andean Altiplano Puna magma body Geophysical Research Letters 26 6 785 Bibcode 1999GeoRL 26 783C doi 10 1029 1999GL900078 S2CID 129812369 a b Folkes et al 2011 p 1457 Francis et al 1978 p 751 Francis et al 1980 p 257 Kay Coira amp Mpodozis 2008 p 118 a b c Cas et al 2011 p 1584 Farias 2020 p v a b c d e Francis et al 1983 p 52 a b Francis et al 1983 p 51 a b c Folkes et al 2011 p 1443 a b c Folkes et al 2011 p 1444 a b Folkes et al 2011 p 1446 Folkes et al 2011 p 1447 a b c Grocke Andrews amp de Silva 2017 p 297 a b c Francis et al 1989 p 516 Sparks et al 1985 p 236 a b Sancho Tomas Maria Somogyi Andrea Medjoubi Kadda Bergamaschi Antoine Visscher Pieter T van Driessche Alexander E S Gerard Emmanuelle Farias Maria E Contreras Manuel Philippot Pascal 5 September 2020 Geochemical evidence for arsenic cycling in living microbialites of a High Altitude Andean Lake Laguna Diamante Argentina Chemical Geology 549 7 Bibcode 2020ChGeo 549k9681S doi 10 1016 j chemgeo 2020 119681 ISSN 0009 2541 S2CID 219737424 Delph Jonathan R Ward Kevin M Zandt George Ducea Mihai N Beck Susan L January 2017 Imaging a magma plumbing system from MASH zone to magma reservoir Earth and Planetary Science Letters 457 322 Bibcode 2017E amp PSL 457 313D doi 10 1016 j epsl 2016 10 008 ISSN 0012 821X HONGN et al 2001 p 33 Farias 2020 p 113 a b c Francis et al 1978 p 750 Cas R A F Wright J V 1987 Volcanic Successions Modern and Ancient Dordrecht Springer Netherlands p 227 doi 10 1007 978 94 009 3167 1 ISBN 978 0 412 44640 5 a b Belluscio Ana 2 April 2010 Hostile volcanic lake teems with life Nature News doi 10 1038 news 2010 161 Rascovan Nicolas Maldonado Javier Vazquez Martin P Farias Maria Eugenia 2016 Metagenomic study of red biofilms from Diamante Lake reveals ancient arsenic bioenergetics in haloarchaea The ISME Journal 10 2 299 309 doi 10 1038 ismej 2015 109 ISSN 1751 7370 PMC 4737923 PMID 26140530 a b Sparks et al 1985 p 241 a b Godfrey L V Jordan T E Lowenstein T K Alonso R L May 2003 Stable isotope constraints on the transport of water to the Andes between 22 and 26 S during the last glacial cycle Palaeogeography Palaeoclimatology Palaeoecology 194 1 3 303 Bibcode 2003PPP 194 299G doi 10 1016 S0031 0182 03 00283 9 ISSN 0031 0182 Vinante D Alonso R N 2006 Evapofacies del Salar Hombre Muerto Puna argentina distribucion y genesis Revista de la Asociacion Geologica Argentina 61 2 286 297 ISSN 0004 4822 Archived from the original on 2016 01 21 Retrieved 2018 02 22 HONGN et al 2001 p 51 a b Grant Jennifer 2016 Isotopos estables en camelidos y vegetales modernos de Antofagasta de la Sierra hacia una ecologia isotopica de la Puna Meridional argentina Intersecciones en Antropologia in Spanish 17 3 327 339 ISSN 1850 373X Folkes et al 2011 p 1440 Paoli Hector September 2002 Recursos Hidricos de la Puna Valles y Bolsones Aridos del Noroeste Argentino PDF in Spanish National Agricultural Technology Institute p 168 Retrieved 22 February 2018 a b Volcan Galan Turismo Catamarca in Spanish Catamarca Province Retrieved 20 February 2018 Conde Serra Alejandro 2016 Mision de Enfoque y Validacion Geotermica Caldera Cerro Blanco y Caldera Cerro Galan Dpto de Antofagasta de la Sierra Catamarca PDF in Spanish Servicio Geologico Minero Argentino p 13 Retrieved 15 June 2018 a b c d e f g h i Francis et al 1989 p 517 a b c Kay et al 2011 p 1488 Sparks et al 1985 p 207 a b Sparks et al 1985 p 209 HONGN et al 2001 p 8 Sparks et al 1985 p 209 211 Pinti Daniele 2011 Mafic and Felsic Encyclopedia of Astrobiology Springer Berlin Heidelberg p 938 doi 10 1007 978 3 642 11274 4 1893 ISBN 978 3 642 11271 3 Kay Coira amp Mpodozis 2008 p 124 Silva 1989 p 1103 a b c d Francis et al 1989 p 518 a b c Sparks et al 1985 p 244 a b Francis et al 1980 p 258 a b Lesti et al 2011 p 1538 Folkes et al 2011 p 1459 1462 a b Francis et al 1989 p 519 a b Grocke Andrews amp de Silva 2017 p 298 Kay et al 2011 p 1495 Francis et al 1989 p 542 Francis et al 1989 p 543 Kay et al 2011 p 1507 a b Folkes et al 2011 p 1475 a b Kay et al 2011 p 1508 Wright et al 2011 p 1531 Folkes et al 2011 p 1476 Lesti et al 2011 p 1555 a b Puente amp Martel 2023 p 571 a b c Sparks et al 1985 p 213 Sparks et al 1985 p 234 Kay et al 2011 p 1509 Kay Coira amp Mpodozis 2008 p 125 Kay et al 2011 p 1487 Folkes et al 2011 p 1432 Sparks et al 1985 p 214 Sparks et al 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Patrick Chen Chen Kay Suzanne M Brown Larry D Isacks Bryan L Sandvol Eric Heit Benjamin Yuan Xiaohui Coira Beatriz L August 2014 Central Andean mantle and crustal seismicity beneath the Southern Puna plateau and the northern margin of the Chilean Pampean flat slab Tectonics 33 8 1654 1655 Bibcode 2014Tecto 33 1636M doi 10 1002 2013TC003393 hdl 11336 35932 S2CID 129847828 Bibliography edit Cas Ray A F Wright Heather M N Folkes Christopher B Lesti Chiara Porreca Massimiliano Giordano Guido Viramonte Jose G 1 December 2011 The flow dynamics of an extremely large volume pyroclastic flow the 2 08 Ma Cerro Galan Ignimbrite NW Argentina and comparison with other flow types Bulletin of Volcanology 73 10 1583 1609 Bibcode 2011BVol 73 1583C doi 10 1007 s00445 011 0564 y hdl 11336 14555 ISSN 0258 8900 S2CID 129502026 Delph Jonathan R Shimizu Kei Ratschbacher Barbara C 2021 The Architecture of the Southern Puna Magmatic System Integrating Seismic and Petrologic Observations With Geochemical Modeling Journal of Geophysical Research Solid Earth 126 7 e2020JB021550 Bibcode 2021JGRB 12621550D doi 10 1029 2020JB021550 ISSN 2169 9356 S2CID 237890337 Farias Maria Eugenia ed 2020 Microbial Ecosystems in Central Andes Extreme Environments Biofilms Microbial Mats Microbialites and Endoevaporites Cham Springer International Publishing doi 10 1007 978 3 030 36192 1 ISBN 978 3 030 36191 4 S2CID 218912960 Folkes Chris B Silva Shanaka L de Wright Heather M Cas Raymond A F 1 December 2011 Geochemical homogeneity of a long lived large silicic system evidence from the Cerro Galan caldera NW Argentina Bulletin of Volcanology 73 10 1455 1486 Bibcode 2011BVol 73 1455F doi 10 1007 s00445 011 0511 y ISSN 0258 8900 S2CID 129705347 Folkes Chris B Wright Heather M Cas Raymond A F Silva Shanaka L de Lesti Chiara Viramonte Jose G 1 December 2011 A re appraisal of the stratigraphy and volcanology of the Cerro Galan volcanic system NW Argentina Bulletin of Volcanology 73 10 1427 1454 Bibcode 2011BVol 73 1427F doi 10 1007 s00445 011 0459 y hdl 11336 14538 ISSN 0258 8900 S2CID 54087442 Francis P W Hammill M Kretzschmar G Thorpe R S 1978 The Cerro Galan Caldera North west Argentina and its tectonic setting Nature 274 5673 749 751 Bibcode 1978Natur 274 749F doi 10 1038 274749a0 ISSN 1476 4687 S2CID 4173154 Francis P W O Callaghan L Kretzschmar G A Thorpe R S Sparks R S J Page R N Barrio R E de Gillou G Gonzalez O E 1983 The Cerro Galan ignimbrite Nature 301 5895 51 53 Bibcode 1983Natur 301 51F doi 10 1038 301051a0 ISSN 1476 4687 S2CID 4252925 Francis P W Sparks R S J Hawkesworth C J Thorpe R S Pyle D M Tait S R Mantovani M S McDermott F 1989 Petrology and geochemistry of volcanic rocks of the Cerro Galan caldera northwest Argentina Geological Magazine 126 5 515 547 Bibcode 1989GeoM 126 515F doi 10 1017 S0016756800022834 ISSN 1469 5081 S2CID 128614585 Francis P W Thorpe R S Moorbath S Kretzschmar G A Hammill M July 1980 Strontium isotope evidence for crustal contamination of calc alkaline volcanic rocks from Cerro Galan northwest Argentina Earth and Planetary Science Letters 48 2 257 267 Bibcode 1980E amp PSL 48 257F doi 10 1016 0012 821X 80 90189 2 ISSN 0012 821X Grocke Stephanie B Andrews Benjamin J de Silva Shanaka L November 2017 Experimental and petrological constraints on long term magma dynamics and post climactic eruptions at the Cerro Galan caldera system NW Argentina Journal of Volcanology and Geothermal Research 347 296 311 Bibcode 2017JVGR 347 296G doi 10 1016 j jvolgeores 2017 09 021 ISSN 0377 0273 HONGN D SEGGIARO R E MONALDI C R ALONSO R N GONZALEZ R E IGARZABAL A P RAMALLO E GODEAS M FUERTES A GARCIA R MOYA F GONZALEZ O 2001 Hoja Geologica 2566 III Cachi Provincias de Salta y Catamarca Report Boletin 248 in Spanish Buenos Aires Instituto de Geologia y Recursos Minerales Servicio Geologico Minero Argentino Kay Suzanne Mahlburg Coira Beatriz Mpodozis Constantino 2008 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 Vol 13 pp 117 181 doi 10 1130 2008 0013 05 ISBN 978 0 8137 0013 7 Kay Suzanne Mahlburg Coira Beatriz Worner Gerhard Kay Robert W Singer Bradley S 1 December 2011 Geochemical isotopic and single crystal 40Ar 39Ar age constraints on the evolution of the Cerro Galan ignimbrites Bulletin of Volcanology 73 10 1487 1511 Bibcode 2011BVol 73 1487K doi 10 1007 s00445 010 0410 7 ISSN 0258 8900 Lesti Chiara Porreca Massimiliano Giordano Guido Mattei Massimo Cas Raymond A F Wright Heather M N Folkes Chris B Viramonte Jose 1 December 2011 High temperature emplacement of the Cerro Galan and Toconquis Group ignimbrites Puna plateau NW Argentina determined by TRM analyses Bulletin of Volcanology 73 10 1535 1565 Bibcode 2011BVol 73 1535L doi 10 1007 s00445 011 0536 2 ISSN 0258 8900 S2CID 128626947 Puente Veronica Martel Alvaro September 2023 Ceramica internodal Aportes a las interacciones entre la Puna meridional y los Valles Calchaquies Argentina Latin American Antiquity 34 3 569 588 doi 10 1017 laq 2022 49 S2CID 251996977 Silva S L de 1 December 1989 Altiplano Puna volcanic complex of the central Andes Geology 17 12 1102 Bibcode 1989Geo 17 1102D doi 10 1130 0091 7613 1989 017 lt 1102 APVCOT gt 2 3 CO 2 ISSN 0091 7613 Sparks R S J Francis P W Hamer R D Pankhurst R J O Callaghan L O Thorpe R S Page R May 1985 Ignimbrites of the Cerro Galan caldera NW Argentina Journal of Volcanology and Geothermal Research 24 3 4 205 248 Bibcode 1985JVGR 24 205S doi 10 1016 0377 0273 85 90071 X ISSN 0377 0273 Wright Heather M N Folkes Chris B Cas Raymond A F Cashman Katharine V 1 December 2011 Heterogeneous pumice populations in the 2 08 Ma Cerro Galan Ignimbrite implications for magma recharge and ascent preceding a large volume silicic eruption Bulletin of Volcanology 73 10 1513 1533 Bibcode 2011BVol 73 1513W doi 10 1007 s00445 011 0525 5 ISSN 0258 8900 S2CID 129628410 Further reading editCerro Galan Caldera Archived 2017 02 18 at the Wayback Machine Oregon State University Cerro Galan Caldera Argentina from How Volcanoes Work by Vic Camp Department of Geological Sciences San Diego State University Cerro Galan Global Volcanism Program Smithsonian Institution Ben G Mason David M Pyle Clive Oppenheimer 2004 The size and frequency of the largest explosive eruptions on Earth Bulletin of Volcanology 66 8 735 748 Bibcode 2004BVol 66 735M doi 10 1007 s00445 004 0355 9 S2CID 129680497 Retrieved from https en wikipedia org w index php title Galan amp oldid 1212743749, wikipedia, wiki, book, books, library,

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