Tutupaca is a volcano in the region of Tacna in Peru. It is part of the Peruvian segment of the Central Volcanic Zone, one of several volcanic belts in the Andes. Tutupaca consists of three overlapping volcanoes formed by lava flows and lava domes made out of andesite and dacite, which grew on top of older volcanic rocks. The highest of these is usually reported to be 5,815 metres (19,078 ft) tall and was glaciated in the past.

Tutupaca
Tutupaca viewed from a southern direction.
Highest point
Elevation5,815 m (19,078 ft) Edit this on Wikidata
Coordinates17°01′34″S 70°22′19″W / 17.026°S 70.372°W / -17.026; -70.372[1]
Geography
Tutupaca is located in Peru
Tutupaca
Tutupaca
Location of Tutupaca
Geology
Mountain typeStratovolcanoes
Volcanic arcAndean Volcanic Belt
Last eruption1802

Several volcanoes in Peru have been active in recent times, including Tutupaca. Their volcanism is caused by the subduction of the Nazca Plate beneath the South America Plate. One of these volcanoes collapsed in historical time, probably in 1802, generating a large debris avalanche with a volume likely exceeding 0.6–0.8 cubic kilometres (0.14–0.19 cu mi) and a pyroclastic flow. The associated eruption was among the largest in Peru for which there are historical records. The volcano became active about 700,000 years ago, and activity continued into the Holocene, but whether there were historical eruptions was initially unclear; some eruptions were instead attributed to the less eroded Yucamane volcano. The Peruvian government plans to monitor the volcano for future activity. Tutupaca features geothermal manifestations with fumaroles and hot springs.

Oral tradition

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The people in Candarave considered Tutupaca to be a "bad" mountain, while Yucamane was the "good" one; this may reflect that Tutupaca had recent volcanic eruptions.[2] The Peruvian geographer Mateo Paz Soldán[3] dedicated an ode to Tutupaca.[4]

Geology and geomorphology

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Tutupaca is 25–30 kilometres (16–19 mi) north of the town of Candarave in the region of Tacna in Peru.[5][6] Lake Suches lies north of the volcano, and two rivers flow nearby: the Callazas River, flowing eastward to the north of the volcano, and then southward past Tutupaca's eastern flank, and the Tacalaya River, which flows south along Tutupaca's western flank.[7][a] The local climate is cold, and the terrain is stony, with little vegetation.[8] During the wet season, the mountain is snow-covered,[9] and meltwater from Tutupaca and other regional mountains is an important source of water for the rivers in the region.[10] In contrast, the volcano itself is largely unaffected by human activity.[11]

Tutupaca consists of two volcanic complexes: an older complex that is highly eroded, and two northerly peaks which formed more recently. Of these, the eastern peak ("eastern Tutupaca") consists of seven presumably Holocene lava domes[12] and is 5,790 metres (19,000 ft) high, while the western one ("western Tutupaca") consists of lava domes, lava flows and Plinian eruption deposits of Pleistocene age, and reaches a height of 5,815 metres (19,078 ft).[b][5] The Global Volcanism Program gives heights of 5,753 metres (18,875 ft) for the eastern and 5,801 metres (19,032 ft) for the western summit.[1] The western peak is the highest summit of Tutupaca.[14]

The base that Tutupaca rises from lies at elevations ranging from 4,400 metres (14,400 ft) to 4,600 metres (15,100 ft)[6] and the volcano covers a surface area of about 150–170 square kilometres (58–66 sq mi).[15] The older complex is formed mainly by lava flows, which during the Pleistocene were eroded by glaciers forming up to 100 metres (330 ft) thick moraines[6] and U-shaped glacial valleys.[16] Cirques and moraines are also found on the western summit, and tephra layers extend west of the volcano. The older complex, which includes lava domes in the form of small hills on its southern part,[17] was the source of ignimbrite that covers the western and southern parts of the volcano.[6] Postglacial lava flows emanating from a vent located between the two peaks have been identified.[1] Proglacial processes like frost shattering have altered young volcanic products.[18]

Composition

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The older complex and western Tutupaca have erupted andesite and dacite, while eastern Tutupaca has only produced dacite.[19] Trachyandesite and trachyte also occur.[20] The volcanic rocks erupted during the Holocene define a potassium-rich calc-alkaline suite.[21] Dacites from eastern Tutupaca contain amphibole, apatite, biotite, clinopyroxene, iron-titanium oxides, orthopyroxene, plagioclase, quartz, and sphene.[22] Mafic[c] rock fragments are rarely found embedded in Tutupaca rocks.[12] The basal volcanic rocks have suffered hydrothermal alteration, forming clays.[24] Elemental sulfur deposits have been identified at Tutupaca[25] and a 1996 map of the volcano shows a sulfur mine on its southeastern flank.[26]

Sector collapse

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A 1 kilometre (0.62 mi) wide amphitheater in eastern Tutupaca, open to the northeast, was formed by a major collapse of the volcano. Lava domes from the younger Tutupaca, as well as highly altered lavas from the older complex, are exposed within the collapse scar, which is the origin of a 6–8-kilometre (3.7–5.0 mi) long debris avalanche deposit. The deposit is mostly found within glacial valleys and is interlaid by the Paipatja pyroclastic flow which divides the debris into two units.[27] The pyroclastic flow reaches both Lake Suches north of the volcano and the Callazas River east of it.[28]

The two units of the debris avalanche are distinguished by their appearance. One features 100–200-metre (330–660 ft) long hummock-like hills, as is typical for volcanic debris avalanches, and the other has ridges which vary in length from 100 to 150 metres (330 to 490 ft). The ridges range from only a few meters to more than 0.5 metres (1 ft 8 in) in height, and from 10 to 30 metres (33 to 98 ft) in height.[29] Such ridges have been observed in other collapse deposits such as at Shiveluch volcano in Russia, and have been explained by sorting processes that take place within granular flows.[30] The differences between the two units appear to be because the first unit was formed from the basal part of Tutupaca, while the second unit was formed by the more recent lava domes of the eastern volcano and formed a granular flow.[31][32]

The collapse possibly started in the hydrothermal system of the volcano and progressed to affect a growing lava dome,[33] with a total volume probably exceeding 0.6–0.8 cubic kilometres (0.14–0.19 cu mi).[34] The total surface area covered by the collapse is about 12–13 square kilometres (4.6–5.0 sq mi).[13] This collapse was not the first in the history of Tutupaca: collapses on the southeast-east flanks of the volcano[13] occurred 6,000–7,500 years ago[35] and delivered debris through glacial valleys on the eastern and southeastern side of the volcano,[12] and on the western side of the volcano[36] a collapse took place before 17,000–25,000 years ago.[35] Such large collapses of volcanoes took place in historical time at Mount Bandai in 1888 and Mount St. Helens in 1980; they can produce large avalanches of debris.[37]

Geologic context

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Off the coast of Peru, the Nazca Plate subducts at 5–6 centimetres per year (2.0–2.4 in/year) beneath the South America Plate,[38][14] causing volcanism in three of the four volcanic belts in the Andes, including the Central Volcanic Zone where Tutupaca is located.[38][d] Other Peruvian volcanoes include Sara Sara, Solimana, Coropuna, the Andagua volcanic field, AmpatoSabancayaHualca Hualca, Chachani, El Misti, Ubinas, Huaynaputina, Ticsani, Yucamane, Purupuruni and Casiri.[40] During historical times, major eruptions took place in Peru at El Misti 2,000 years ago and at Huaynaputina in 1600,[38] the latter of which claimed 1,500 fatalities and disrupted the climate of Earth.[41]

The basement of the region consists of folded Mesozoic sediments, and Cenozoic volcanic and sedimentary cover which overlies the Mesozoic rocks.[42] There are many tectonic lineaments and faults which were active in the Tertiary;[43] one of these crosses Tutupaca from north to south,[7] and others influence the positions of geothermal features.[20] The Huaylillas ignimbrite complex[e] underlies some of the volcanic centres,[43] which include a first set of eroded volcanoes that were active between 8.4–5 and 4–2 million years ago, principally erupting lava flows. These were followed by a second set of volcanoes which were also mainly active with lava flows, such as Casiri, Tutupaca, and Yucamane. A third phase formed dacitic lava domes such as Purupuruni about 100,000 years ago.[45] Other, older stratovolcanoes are found at Tutupaca and are heavily eroded by glaciers.[46]

 
Tutupaca volcano

Climate and vegetation

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Most of the volcanoes in the Central Volcanic Zone are located at over 4,000 metres (13,000 ft) elevation where the climate is cold with frequent freezes. Most precipitation falls between January and March, at Tutupaca it amounts to 200–560 millimetres per year (7.9–22.0 in/year).[47] In the Western Cordillera, altitudes between 3,500–3,900 metres (11,500–12,800 ft) are dominated by vegetation such as cacti, herbs, Peruvian feather grass, and yareta, but also lichens and mosses. Wetlands, called bofedales, display a diverse plant life. Above 4,000 metres (13,000 ft) elevation plant life diminishes and in 2003–2012 by 5,800 metres (19,000 ft) there was perpetual snow.[48] The volcano is part of the Vilacota Maure Regional Conservation Area [es].[49]

Eruption history

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The oldest volcanic rocks of Tutupaca are 1,135,000 ± 17,000 years old.[24] The older complex was active at first with lava flows and then with a major explosive eruption;[6] a pumice-and-ash flow forms the "Callazas" deposit and may have been produced either by the older complex[50] or by western Tutupaca.[51] A long hiatus separated the activity of the older complex from that of western and eastern Tutupaca.[52] The small lava domes on the older complex have been dated to 260,000 ± 200,000[17] while more recent domes are 33,000±5,000 years old.[53] Volcanic activity continued into the Holocene,[1] and the volcano is considered to be potentially active.[5] Today, fumaroles occur on the summit of Tutupaca[54] and seismic activity has been recorded.[55]

There are reports of eruptions in 1780, 1787, 1802, 1862 and 1902,[6] supported by dates obtained through radiocarbon dating showing there were eruptions during this period.[37] Some authors believed that Yucamane volcano was a more likely source for these eruptions,[6] but Samaniego 2015 et al. showed that Yucumane last erupted 3,000 years ago,[56] implying that the reported eruptions, especially the 1802 and 1787 events, most likely occurred at Tutupaca.[1] Tutupaca is a possible source of the AD 400-720 Khonkho tephra in the Altiplano.[57]

The sector collapse of eastern Tutupaca was accompanied by an eruption that was among the largest in Peruvian history, reaching a volcanic explosivity index of 3 or 4. Contemporaneous chronicles document ashfall as far as 165 kilometres (103 mi) to the south in Arica.[58] The collapse has been dated to 1731–1802 with high probability[f] and is thought to be associated with the 1802 eruption.[2] The eruption was probably triggered by the entry of fresh, hot magma into a dacitic magma chamber.[59] Shortly before the collapse,[g] a pyroclastic flow erupted from the volcano[2] probably as a consequence of the collapse of a lava dome. It formed a deposit on the east flank of Tutupaca,[60] which reaches a thickness of 6 metres (20 ft).[17] The previous eruption may have destabilized the volcano and triggered the main collapse, which also generated the Paipatja pyroclastic flow. The area was thinly inhabited at the time, and thus the impact of the eruption was small.[61]

Hazards

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Based on the history of Tutupaca, a future eruption can be envisaged where renewed activity causes another collapse of the volcano. In this case, about 8,000–10,000 people, as well as neighboring geothermal power and mining infrastructure, would be in danger.[61] Several small towns, diversion dams, irrigation canals, and the two roads IloDesaguadero and TacnaTarata–Candarave would also be vulnerable.[5] Other dangers are ballistic rocks, pyroclastic flows, scoria avalanches, ash and pumice rains, volcanic gas and lahars.[62] Tutupaca along with Ubinas and Huaynaputina is one of the three volcanoes in Peru to have produced large explosive eruptions.[63]

The Peruvian Instituto Geológico, Minero y Metalúrgico[h] (INGEMMET) has published a volcano hazard map for Tutupaca.[66] In 2017, Tutupaca was identified as one of the volcanoes to be monitored by the future Peruvian Southern Volcano Observatory. This would entail surveillance of earthquake activity, changes in the composition of fumarole gases and deformation of the volcanoes, and real-time video. This project, budgeted to cost 18,500,000 Peruvian sols (4768041 US dollars) and involves the construction of thirty monitoring stations and the main observatory in the Sachaca District,[67] became active in 2019.[68] Publication of regular activity reports began in May 2019.[55] The volcano is classified as "moderately dangerous".[69]

Geothermal activity

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Tutupaca is also the name of a geothermal field in the neighborhood of the volcano, which includes the areas of Azufre Chico, Azufre Grande, Callazas River, Pampa Turun Turun, and Tacalaya River;[8] they are part of the same geothermal system whose temperature at depth is higher than 200 °C (392 °F).[70][71] The fields feature fumaroles, geysers,[45] mud pots and occurrences of sulfur, both solid and in the form of hydrogen sulfide gas,[8] as well as siliceous sinter and travertine deposits.[72] Hot springs at the foot of the Tutupaca volcano[73] discharge water into the rivers.[8]

Tutupaca has been mentioned as a potential site for geothermal power generation.[74] In 2013, Canada's Alterra Power and the Philippine Energy Development Corporation developed a joint venture to work on a geothermal prospect at Tutupaca,[75] although work at Tutupaca had not begun by October 2014.[76]

Notes

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  1. ^ The course of both rivers is influenced by tectonic lineaments.[8]
  2. ^ These heights are from a 2015 source.[13][5]
  3. ^ A volcanic rock relatively rich in iron and magnesium, relative to silicium.[23]
  4. ^ The Central Volcanic Zone is one of four volcanic belts in the Andes, together with the Northern Volcanic Zone, the Southern Volcanic Zone and the Austral Volcanic Zone.[39]
  5. ^ The Huaylillas ignimbrites were emplaced between 24 and 12 million years ago.[44]
  6. ^ The uncalibrated radiocarbon age of the samples is 218±14 years before present,[32] with 95% confidence; the calibrated age consists of two ranges, with an 85% probability that the date lies between 1731 and 1802.[2]
  7. ^ Stratigraphic relations imply that this pyroclastic flow predates the main collapse, but radiocarbon dating does not have sufficient resolution to separate the two events in time.[2]
  8. ^ A public agency[64] which is among other things responsible for monitoring volcanoes in Peru.[65]

References

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  1. ^ a b c d e "Tutupaca". Global Volcanism Program. Smithsonian Institution. Retrieved 21 March 2018.
  2. ^ a b c d e Samaniego et al. 2015, p. 13.
  3. ^ "U. Católica de Santa María rinde homenaje a siete científicos arequipeños por sus aportes a la ciencia". La República (in Spanish). 12 January 2012. Retrieved 8 April 2018.
  4. ^ Soldán, Mateo Paz (1863). Géographie du Pérou (in French). Firmin Didot Frères, Fils et Cie. p. 8. OCLC 253927093.
  5. ^ a b c d e "Volcán Tutupaca". INGEMMET (in Spanish). Archived from the original on 5 June 2020. Retrieved 7 March 2018.
  6. ^ a b c d e f g Samaniego et al. 2015, p. 3.
  7. ^ a b Samaniego et al. 2015, p. 2.
  8. ^ a b c d e Pauccara & Matsuda 2015, p. 1.
  9. ^ Amstutz, G. C. (1959). "On the Formation of Snow Penitentes". Journal of Glaciology. 3 (24): 309. doi:10.3189/S0022143000023972. ISSN 0022-1430.
  10. ^ Begazo, Jesús Gordillo (15 February 2017). "Desarrollo regional tardío y ocupación inca en la pre-cordillera de Tacna". Ciencia & Desarrollo (in Spanish) (3): 73–81. doi:10.33326/26176033.1996.3.68. ISSN 2304-8891. S2CID 198573899.
  11. ^ Bernard et al. 2022, p. 4.
  12. ^ a b c Manrique et al. 2019, p. 2.
  13. ^ a b c Samaniego et al. 2015, p. 4.
  14. ^ a b Valderrama et al. 2016, p. 3.
  15. ^ Mariño Salazar et al. 2019, p. 12.
  16. ^ Mariño Salazar et al. 2019, p. 26.
  17. ^ a b c "Geología del volcán Tutupaca". INGEMMET (in Spanish). Archived from the original on 8 August 2022. Retrieved 7 March 2018.
  18. ^ Bernard et al. 2022, p. 5.
  19. ^ Samaniego et al. 2015, pp. 3–4.
  20. ^ a b Pauccara & Matsuda 2015, p. 3.
  21. ^ Samaniego et al. 2015, p. 11.
  22. ^ Samaniego et al. 2015, pp. 11–12.
  23. ^ Pinti, Daniele (2011), "Mafic and Felsic", Encyclopedia of Astrobiology, Springer Berlin Heidelberg, p. 938, doi:10.1007/978-3-642-11274-4_1893, ISBN 9783642112713
  24. ^ a b Mariño et al. 2021, p. 8.
  25. ^ Perales, Oscar J.P. (1994). "General overview and prospects of the mining and metallurgical industry in peru". Resources Processing. 41 (2): 75. doi:10.4144/rpsj1986.41.72. ISSN 1883-9150.
  26. ^ Defense Mapping Agency (1996). "Tarata, Peru; Bolivia; Chile" (Map). Latin America, Joint Operations Graphic (2 ed.). 1:250000.
  27. ^ Valderrama et al. 2016, p. 2.
  28. ^ Samaniego et al. 2015, p. 5.
  29. ^ Valderrama et al. 2016, pp. 3, 5.
  30. ^ Valderrama et al. 2016, p. 7.
  31. ^ Valderrama et al. 2016, p. 4.
  32. ^ a b Valderrama et al. 2016, p. 10.
  33. ^ Valderrama et al. 2016, p. 6.
  34. ^ Samaniego et al. 2015, p. 6.
  35. ^ a b Mariño et al. 2021, p. 15.
  36. ^ Mariño et al. 2021, p. 11.
  37. ^ a b Valderrama et al. 2016, p. 1.
  38. ^ a b c Samaniego et al. 2015, p. 1.
  39. ^ Stern, Charles R. (2004). "Active Andean volcanism: its geologic and tectonic setting" (PDF). Revista Geológica de Chile. 31 (2): 161–206. doi:10.4067/S0716-02082004000200001. ISSN 0716-0208.
  40. ^ Mariño et al. 2021, p. 2.
  41. ^ Mariño Salazar et al. 2019, p. 11.
  42. ^ Scandiffio, Verastegui & Portilla 1992, p. 346.
  43. ^ a b Scandiffio, Verastegui & Portilla 1992, p. 347.
  44. ^ Pauccara & Matsuda 2015, p. 2.
  45. ^ a b Scandiffio, Verastegui & Portilla 1992, p. 348.
  46. ^ Mariño Salazar et al. 2019, p. 23.
  47. ^ Mariño Salazar et al. 2019, p. 15.
  48. ^ Gałaś, Andrzej; Panajew, Paweł; Cuber, Piotr (30 November 2015). "Stratovolcanoes in the Western Cordillera – Polish Scientific Expedition to Peru 2003–2012 reconnaissance research". Geotourism/Geoturystyka. 37 (2): 66. doi:10.7494/geotour.2014.37.61. ISSN 2353-3641.
  49. ^ Del Carpio Calienes et al. 2022, p. 46.
  50. ^ Centeno Quico & Rivera 2020, p. 26.
  51. ^ Mariño et al. 2021, p. 9.
  52. ^ Mariño et al. 2021, p. 14.
  53. ^ Mariño et al. 2021, p. 10.
  54. ^ Pauccara & Matsuda 2015, p. 9.
  55. ^ a b Centeno Quico & Rivera 2020, p. 27.
  56. ^ "Yucamane". Global Volcanism Program. Smithsonian Institution. Retrieved 21 March 2018.
  57. ^ Marsh, Erik J; Harpel, Christopher J; Damby, David E (December 2024). "The Khonkho tephra: A large-magnitude volcanic eruption coincided with the rise of Tiwanaku in the Andes". The Holocene. 34 (12): 1870, 1865. doi:10.1177/09596836241275000.
  58. ^ Samaniego et al. 2015, pp. 14–15.
  59. ^ Manrique et al. 2019, p. 23.
  60. ^ Samaniego et al. 2015, pp. 4–5.
  61. ^ a b Samaniego et al. 2015, p. 16.
  62. ^ Mariño Salazar et al. 2019, pp. 106–107.
  63. ^ Del Carpio Calienes et al. 2022, p. 18.
  64. ^ "Quiénes Somos". INGEMMET (in Spanish). Archived from the original on 7 October 2020. Retrieved 9 April 2018.
  65. ^ "Funciones y Organigrama". INGEMMET (in Spanish). Archived from the original on 29 September 2020. Retrieved 9 April 2018.
  66. ^ Hancco, Nelly (18 April 2017). "Ingemmet elabora el mapa de peligro del volcán Sara Sara" (in Spanish). Diario Correo. Retrieved 7 March 2018.
  67. ^ Hancco, Nelly (31 October 2017). "IGP vigilará los 10 volcanes más peligrosos del Perú". Diario Correo (in Spanish). Retrieved 7 March 2018.
  68. ^ Centeno Quico & Rivera 2020, p. 13.
  69. ^ Del Carpio Calienes et al. 2022, p. 3.
  70. ^ Pauccara & Matsuda 2015, p. 8.
  71. ^ Scandiffio, Verastegui & Portilla 1992, p. 370.
  72. ^ Steinmüller, Klaus (September 2001). "Modern hot springs in the southern volcanic Cordillera of Peru and their relationship to Neogene epithermal precious-metal deposits". Journal of South American Earth Sciences. 14 (4): 381. Bibcode:2001JSAES..14..377S. doi:10.1016/S0895-9811(01)00033-5. ISSN 0895-9811.
  73. ^ Scandiffio, Verastegui & Portilla 1992, p. 355.
  74. ^ Quispe, Juan Luis Silvera (27 May 2013). "Perú tiene reserva geotérmica para generar 3 mil MW de electricidad". La República (in Spanish). Retrieved 7 March 2018.
  75. ^ Flores, Alena Mae S. (19 June 2013). "EDC signs Peru, Chile contracts". Manila Standard Today. Retrieved 8 May 2018.
  76. ^ Poma, Sandy (22 October 2014). "En Tacna hay alto potencial geotérmico". Diario Correo (in Spanish). Retrieved 8 May 2018.

Sources

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