Earth:El Negrillar: Difference between revisions

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| name=El Negrillar
| name=El Negrillar
| other_name=Negros de Aras
| other_name=Negros de Aras
| map=Chile
| photo=El Negrillar.jpg
| photo=El Negrillar.jpg
| photo_alt=Black lava flows and cinder cones in the image centre.
| photo_alt=Black lava flows and cinder cones in the image centre.
| photo_caption=The cones in the image centre and associated black lava flows form the El Negrillar [[Earth:Volcanic field|volcanic field]].
| photo_caption=The cones in the image centre and associated black lava flows form the El Negrillar [[Earth:Volcanic field|volcanic field]], which covers about 220 square kilometres.
| elevation_m=3500
| elevation_m=3500
| elevation_ref=<ref name=GVP />
| elevation_ref=<ref name=GVP />
| coordinates={{coord|24.18|S|68.25|W}}
| coordinates={{coord|24.18|S|68.25|W}}
| coordinates_ref=<ref name=GVP />}}
| coordinates_ref=<ref name=GVP />}}
'''El Negrillar''' or '''Negros de Aras''' is a [[Earth:Volcanic field|volcanic field]] in the [[Place:Andes|Andes]]. Located south of the Salar de Atacama<ref name="AguileraUreta2022" /> and west of the Cordón de Púlar, it generated [[Earth:Cinder cone|cinder cone]]s and andesitic lava flows. The volcanic field may be of [[Earth:Holocene|Holocene]] age.
'''El Negrillar''' is a [[Earth:Volcanic field|volcanic field]] in the [[Place:Andes|Andes]]. Located south of the Salar de Atacama and west of the Cordón de Púlar, it generated [[Earth:Cinder cone|cinder cone]]s and lava flows. Covering a surface area of {{convert|220|km2}}, it is the largest volcanic field in northern Chile, with almost a hundred vents that produced mainly lava flows. Owing to the [[Earth:Arid|arid]] climate, landforms are well preserved. [[Physics:Radiometric dating|Radiometric dating]] has yielded ages of less than 1.5 million years, with the most recent eruption occurring about 141,000 years ago. Parts of the [[Earth:Holocene|Holocene]] [[Earth:Socompa|Socompa]] debris avalanche overlie the field. A [[Earth:Groundwater|groundwater]] system underlies the volcanic field and some cones formed through phreatomagmatic eruptions. El Negrillar is located in a complex tectonic regime, characterized by numerous [[Earth:Fault (geology)|fault]]s. The town of Tilomonte and various power lines, mines and water wells are in the area.  


Covering a surface area of {{convert|190|km2}}, it is the largest volcanic field in northern Chile.<ref name="Vilches2022" /> There are 66 vents, 44 of which are cones with shapes ranging from rings over horseshoes to irregular shapes. It has about 0.23 vents per square kilometre.<ref name="AguileraUreta2022" /> The cones have volumes of less than {{convert|0.1|km3}} and lava flows are thin and branch out dendritically.<ref name="Deruelle1982" /> Lava flows are up to {{convert|100|m}} thick and overlie the Salín Formation.<ref name="RissmannLeybourne2015" /> They feature surface landforms channels, folds, levees, lobes, ogives and<ref name="Vilches2022" /> rafts. Owing to the [[Earth:Arid|arid]] climate, landforms are well preserved. A [[Earth:Groundwater|groundwater]] system underlies the volcanic field and some cones formed through phreatomagmatic eruptions. El Negrillar is located in a complex tectonic regime, with ongoing compression but possibly local extensional tectonics<ref name="AguileraUreta2022" /> and is located within the Negros de Aras [[Earth:Graben|graben]].<ref name="Vilches2022" />
== Geography and geomorphology ==


[[Physics:Radiometric dating|Radiometric dating]] has yielded ages of less than 1.5 million years and of 600,000 ± 400,000 years.<ref name="AguileraUreta2022" /> While the field was sometimes considered to be of [[Earth:Holocene|Holocene]] age, the [[Earth:Global Volcanism Program|Global Volcanism Program]] considers it of [[Earth:Pleistocene|Pleistocene]] age as none of the volcanoes are younger than a 100,000 year old volcano farther north. Parts of the [[Earth:Holocene|Holocene]] [[Earth:Socompa|Socompa]] debris avalanche overlie the field;<ref name=GVP /> it formed about 7,200 years ago. The town of Tilomonte and various power lines, mines and water wells are in the area.<ref name="AguileraUreta2022" /> Reconstructed effusion rates exceed {{convert|100|m3/s}}.<ref name="Vilches2022" />
The Central Volcanic Zone (CVZ) of the Andes is a northwest-south trending [[Earth:Volcanic arc|volcanic arc]] that extends from Peru over Bolivia to Chile and Argentina.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=2}} Most of its 44{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} volcanoes are young [[Earth:Stratovolcano|stratovolcano]]es, but there are also monogenetic volcanoes and the Altiplano-Puna volcanic complex, which has produced more than {{convert|15000|km3}} of volcanic rocks.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=3}} Stratovolcanoes in the El Negrillar area include [[Earth:Socompa|Socompa]] to the south, Pular to the east of the volcanic field,{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=2}} and Aguas Delgadas.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=4}} Towns in the area include Monturaqui, {{ill|Peine, Chile|es|Peine (Chile)|lt=Peine}}, Tilomonte, Tilopozo,{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} and a mining camp southwest of the field,{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=2}} there are cross-border power lines,{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=3}} and the local [[Earth:Aquifer|aquifer]] is pumped by various mining companies in the area{{sfn|Anderson|Low|Foot|2002|p=135}} just south of the volcanic field.{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=2}} Interest in the monogenetic volcanoes of the area arose in the 2010s and 2020s.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=3}}


El Negrillar has erupted [[Earth:Basaltic andesite|basaltic andesite]] containing [[Chemistry:Olivine|olivine]], [[Earth:Andesite|andesite]] containing either olivine-[[Chemistry:Pyroxene|pyroxene]], pyroxene or pyroxene-[[Chemistry:Hornblende|hornblende]], and [[Earth:Dacite|dacite]]. It defines a [[Earth:Volcanic arc|volcanic arc]]-type magma.<ref name="AguileraUreta2022" /> The origin of the more basic lavas of this field has been explained with [[Chemistry:Olivine|olivine]] differentiation.<ref name=Actas />
The El Negrillar field, also known as Negros de Aras,<ref name=GVP /> is south of the Salar de Atacama,{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=4}} not far from the border between Argentina and Chile,{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=2}} and consists of numerous unvegetated{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=5}} scoria cones and lava flows.{{sfn|Aguilera|Ureta|Grosse|Németh|2022|p=4}} It includes 51 vents{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=4}} named after Atacama flora and fauna,{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=5}} and 98 separate lava flows{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=7}} that extend downslope,{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=7}} making it the largest [[Earth:Monogenetic volcanic field|monogenetic volcanic field]] of northern Chile.{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=3}} Vents have produced mostly lava flows, but there are [[Earth:Maar|maar]]s and scoria cones as well.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} Some cones have been breached when lava flowed out.{{sfn|Aguilera|Ureta|Grosse|Németh|2022|p=15}} The lava flows are blocky and have flow forms like scarps, ogives and levees{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=5}} that are well-conserved by the arid climate of the field;{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=3}} the longest flow has a length of {{convert|12|km}}.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=9}} The vents are spread over three sectors,{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=2}} and the northern in an eastern and a western sector.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=4}} The northern and central sectors lie on the Tilomonte and Tilocalár ridges and the southern sector on the northwestern flank of the Aguas Delgadas volcano.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=3}} The total area covered by the field exceeds {{convert|220|km2}}.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=6}}


==See also==
== Geology ==
* [[Earth:Socompa|Socompa]]
 
Off the western coast of South America, the [[Earth:Nazca Plate|Nazca Plate]] subducts beneath the [[Earth:South American Plate|South American Plate]]. The subduction is responsible for the volcanism of the CVZ{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=3}} and the other two volcanic zones, the Northern Volcanic Zone and the Southern Volcanic Zone.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} A fourth volcanic zone is known as the Austral Volcanic Zone.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=2}}
 
El Negrillar is part of a wider field of monogenetic volcanoes south of Salar de Atacama, which includes Morro Punta Negra, [[Earth:La Negrillar|La Negrillar]], Tilocalar and [[Earth:Cerro Tujle|Cerro Tujle]]. Their formation was probably influenced by [[Earth:Fault (geology)|fault]]ing, as there are north-south trending [[Earth:Thrust fault|thrust fault]]s, northwest-southeast trending transverse faults{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=2}} and various types of folds,{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=15}} which enable magma ascent{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=2}} through the {{convert|70|km}} thick crust.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=3}} Monogenetic activity in the area has progressively migrated north, with the youngest age being the 77,000 ± 54,000 years of [[Earth:Cerro Overo|Cerro Overo]],{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=14}} and the volcanoes share a common magma source.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=8}} El Negrillar is by far the largest of all these monogenetic volcanic fields.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=14}}
 
The surrounding and underlying terrain consists mostly of various volcanic rocks and [[Earth:Alluvial fan|alluvial fan]]s.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=4}} A {{convert|60|km}} long north-south trending depression runs south from Salar de Atacama and is filled by water-containing volcanic rocks{{sfn|Rissmann|Leybourne|Benn|Christenson|2015|p=165}} of the Salín Formation.{{sfn|Anderson|Low|Foot|2002|p=135}} They form the Monturaqui-Negrillar-Tilopozo [[Earth:Groundwater|groundwater]] system, which conveys water to the Tilopozo area of Salar de Atacama. The flow{{sfn|Rissmann|Leybourne|Benn|Christenson|2015|p=167}} and composition of its waters are influenced by the El Negrillar volcanic field,{{sfn|Rissmann|Leybourne|Benn|Christenson|2015|p=170}} which lies in the middle of the groundwater body and separates it into two halves.{{sfn|Anderson|Low|Foot|2002|p=139}}
 
Rocks erupted at El Negrillar have compositions ranging from [[Earth:Basaltic andesite|basaltic andesite]] to [[Earth:Dacite|dacite]], with some trachytic components, and define a calc-alkaline suite{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=8}} with five distinct members.{{sfn|Aguilera|Ureta|Grosse|Németh|2022|p=3}} They contain [[Earth:Phenocryst|phenocryst]]s of [[Chemistry:Amphibole|amphibole]], [[Chemistry:Olivine|olivine]], [[Chemistry:Plagioclase|plagioclase]] and [[Chemistry:Pyroxene|pyroxene]]; [[Chemistry:Quartz|quartz]] has been reported as well.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=9}} Composition varies from the northern to the southern sector, as magmas of the southern sector are more primitive with fewer crystals and volatiles.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=12}} The [[Earth:Adakite|adakite]]-like composition implies that the magmas originated at great depths, where [[Chemistry:Garnet|garnet]] is stable,{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=11}} from melting of a small fraction of crustal and mantle rocks. The magmas underwent fractional crystallization{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=14}} and during their ascent they absorbed varying quantities of [[Earth:Crust (geology)|crust]]al material.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2024|p=12}} Their total volume is about {{convert|6.8|km3}},{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=17}} making it one of the largest monogenetic volcanic fields worldwide.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=4}}
 
== Eruption history ==
 
El Negrillar formed during the last 1.5 million years{{sfn|Aguilera|Ureta|Grosse|Németh|2022|p=3}} in the [[Earth:Pleistocene|Pleistocene]]{{efn|Between 1.8 million years and 11,700 years ago.{{sfn|International Chronostratigraphic Chart|2018}}}}. Eruptions produced lava flows, with subordinate [[Earth:Explosive eruption|explosive activity]],{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=2}} at effusion rates reaching from a few to a few tens of cubic metres per second. Some eruptions may have lasted more than a year.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=11}} Ages of the volcanoes range from 982,000 ± 8,000 to 141,000 ± 72,000 years,{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=10}} and often do not match the appearance of the vents.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=14}} It is possible that a change in tectonic regimen from compressive to extensive 780,000 years ago allowed the ascent of magma.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=3}} Monogenetic eruptions can happen in areas without previous volcanic activity, and are a threat to the Salar de Atacama area{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} and the infrastructure there.{{sfn|Aguilera|Ureta|Grosse|Németh|2022|p=3}}{{sfn|Vilches|Ureta|Grosse|Németh|2022|p=12}}
 
The three vents Copao, Sandillón and Ruda erupted phreatomagmatically; they are tuff cones with infilling [[Earth:Lava dome|lava dome]]s.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|pp=7-9}} The phreatomagmatic activity is probably a consequence of magma interaction with the Monturaqui-Negrillar-Tilopozo aquifer.{{sfn|Loaiza|Larrea|Salinas|Parra-Encalada|2023|p=13}} About 7,000 years ago, Socompa volcano collapsed{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=2}} and partly buried the El Negrillar volcanoes.{{sfn|Parra-Encalada|Larrea|Loaiza|Cartagena|2022|p=4}}
 
==Notes==
 
{{notelist}}


==References==
==References==
{{reflist|refs=
{{reflist|refs=
<ref name="Vilches2022">{{cite journal |last1=Vilches |first1=Matias |last2=Ureta |first2=Gabriel |last3=Grosse |first3=Pablo |last4=Németh |first4=Károly |last5=Aguilera |first5=Felipe |last6=Aguilera |first6=Mauricio |title=Effusion rate estimation based on solidified lava flows: Implications for volcanic hazard assessment in the Negros de Aras monogenetic volcanic field, northern Chile |journal=Journal of Volcanology and Geothermal Research |date=1 February 2022 |volume=422 |pages=107454 |doi=10.1016/j.jvolgeores.2021.107454 |s2cid=245151778 |url=https://www.sciencedirect.com/science/article/pii/S0377027321002833 |language=en |issn=0377-0273}}</ref>
<ref name=GVP>{{cite gvp| vn = 355106| name = El Negrillar| accessdate = 3 September 2015}}</ref>}}
<ref name="AguileraUreta2022">{{cite journal |last1=Aguilera |first1=Mauricio |last2=Ureta |first2=Gabriel |last3=Grosse |first3=Pablo |last4=Németh |first4=Károly |last5=Aguilera |first5=Felipe |last6=Vilches |first6=Matias |title=Geomorphological, morphometric, and spatial distribution analysis of the scoria cones in the Negros de Aras monogenetic volcanic field, northern Chile |journal=Journal of Volcanology and Geothermal Research |date=1 February 2022 |volume=422 |pages=107458 |doi=10.1016/j.jvolgeores.2021.107458 |s2cid=245460492 |url=https://www.sciencedirect.com/science/article/pii/S0377027321002870 |language=en |issn=0377-0273}}</ref>
 
<ref name=GVP>{{cite gvp| vn = 355106| name = El Negrillar| accessdate = 3 September 2015}}</ref>
=== Sources ===
<ref name="Deruelle1982">{{cite journal|last1=Deruelle|first1=Bernard|title=Petrology of the plio-quaternary volcanism of the South-Central and Meridional Andes|journal=[[Earth:Journal of Volcanology and Geothermal Research|Journal of Volcanology and Geothermal Research]]|volume=14|issue=1–2|year=1982|pages=77–124|issn=0377-0273|doi=10.1016/0377-0273(82)90044-0}}</ref>
{{refbegin}}
<ref name="RissmannLeybourne2015">{{cite journal|last1=Rissmann|first1=Clinton|last2=Leybourne|first2=Matthew|last3=Benn|first3=Chris|last4=Christenson|first4=Bruce|title=The origin of solutes within the groundwaters of a high Andean aquifer|journal=[[Chemistry:Chemical Geology|Chemical Geology]]|volume=396|year=2015|pages=164–181|issn=0009-2541|doi=10.1016/j.chemgeo.2014.11.029}}</ref>
* {{cite journal |last1=Aguilera |first1=Mauricio |last2=Ureta |first2=Gabriel |last3=Grosse |first3=Pablo |last4=Németh |first4=Károly |last5=Aguilera |first5=Felipe |last6=Vilches |first6=Matias |title=Geomorphological, morphometric, and spatial distribution analysis of the scoria cones in the Negros de Aras monogenetic volcanic field, northern Chile |journal=Journal of Volcanology and Geothermal Research |date=February 2022 |volume=422 |pages=107458 |doi=10.1016/j.jvolgeores.2021.107458|bibcode=2022JVGR..42207458A |s2cid=245460492 }}
<ref name=Actas>{{cite book|title=Actas, II Congreso Geologico Chileno: ciudad de arica del 6 al 11 de Agosto de 1979|url=https://books.google.com/books?id=oRUeAQAAMAAJ|year=1980|publisher=Instituto de Investigaciones Geologicas|page=218|language=fr}}</ref>}}
* {{Cite journal |last1=Anderson |first1=Mark |last2=Low |first2=Rob |last3=Foot |first3=Stephen |date=January 2002 |title=Sustainable groundwater development in arid, high Andean basins |url=https://www.lyellcollection.org/doi/10.1144/GSL.SP.2002.193.01.11 |journal=Geological Society, London, Special Publications |language=en |volume=193 |issue=1 |pages=133–144 |doi=10.1144/GSL.SP.2002.193.01.11 |bibcode=2002GSLSP.193..133A |s2cid=130277537 |issn=0305-8719}}
* {{cite journal |last1=Loaiza |first1=Camila |last2=Larrea |first2=Patricia |last3=Salinas |first3=Sergio |last4=Parra-Encalada |first4=Daniela |last5=Cartagena |first5=Rubén |last6=Godoy |first6=Benigno |title=The temporal evolution of monogenetic volcanism in the Central Andes: 40Ar/39Ar geochronology of El Negrillar volcanic field, Chile |journal=Bulletin of Volcanology |date=2 December 2023 |volume=86 |issue=1 |doi=10.1007/s00445-023-01691-8 |s2cid=265517708 |url=https://link.springer.com/article/10.1007/s00445-023-01691-8 |language=en}}
* {{cite journal |last1=Parra-Encalada |first1=Daniela |last2=Larrea |first2=Patricia |last3=Loaiza |first3=Camila |last4=Cartagena |first4=Rubén |last5=Salinas |first5=Sergio |last6=Godoy |first6=Benigno |last7=Grosse |first7=Pablo |last8=Le Roux |first8=Petrus |title=Physical and chemical evolution of the largest monogenetic lava field in the Central Andes: El Negrillar Volcanic Field, Chile |journal=Journal of Volcanology and Geothermal Research |date=June 2022 |volume=426 |pages=107541 |doi=10.1016/j.jvolgeores.2022.107541|bibcode=2022JVGR..42607541P |s2cid=247926473 }}
* {{cite journal |last1=Parra-Encalada |first1=Daniela |last2=Larrea |first2=Patricia |last3=Loaiza |first3=Camila |last4=Cartagena |first4=Rubén |last5=Salinas |first5=Sergio |last6=Godoy |first6=Benigno |last7=Le Roux |first7=Petrus |title=Decoding subcontinental lithosphere processes: The key role of fractional crystallization in Central Andes monogenetic volcanism - Insight from El Negrillar volcanic field, Chile |journal=Lithos |date=January 2024 |volume=464-465 |pages=107427 |doi=10.1016/j.lithos.2023.107427|doi-access=free |bibcode=2024Litho.46407427P }}
* {{cite journal |last1=Rissmann |first1=Clinton |last2=Leybourne |first2=Matthew |last3=Benn |first3=Chris |last4=Christenson |first4=Bruce |title=The origin of solutes within the groundwaters of a high Andean aquifer |journal=Chemical Geology |date=March 2015 |volume=396 |pages=164–181 |doi=10.1016/j.chemgeo.2014.11.029|bibcode=2015ChGeo.396..164R }}
* {{cite web|title=International Chronostratigraphic Chart|url=http://www.stratigraphy.org/icschart/ChronostratChart2018-08.pdf|archive-url=https://web.archive.org/web/20180731123434/http://www.stratigraphy.org/icschart/ChronostratChart2018-08.pdf|archive-date=31 July 2018|publisher=International Commission on Stratigraphy|access-date=22 October 2018|date=August 2018|ref={{harvid|International Chronostratigraphic Chart|2018}}}}
* {{cite journal |last1=Vilches |first1=Matias |last2=Ureta |first2=Gabriel |last3=Grosse |first3=Pablo |last4=Németh |first4=Károly |last5=Aguilera |first5=Felipe |last6=Aguilera |first6=Mauricio |title=Effusion rate estimation based on solidified lava flows: Implications for volcanic hazard assessment in the Negros de Aras monogenetic volcanic field, northern Chile |journal=Journal of Volcanology and Geothermal Research |date=February 2022 |volume=422 |pages=107454 |doi=10.1016/j.jvolgeores.2021.107454|bibcode=2022JVGR..42207454V |s2cid=245151778 }}
{{refend}}




[[Category:Volcanic fields]]
[[Category:Volcanic fields]]


{{Sourceattribution|El Negrillar}}
{{Sourceattribution|El Negrillar}}

Latest revision as of 22:07, 13 May 2025

Short description: Volcanic field in the Andes
El Negrillar
Negros de Aras
Black lava flows and cinder cones in the image centre.
The cones in the image centre and associated black lava flows form the El Negrillar volcanic field, which covers about 220 square kilometres.
Highest point
Elevation3,500 m (11,500 ft) [1]
Coordinates [ ⚑ ] 24°11′S 68°15′W / 24.18°S 68.25°W / -24.18; -68.25[1]
Geography
El Negrillar is located in Chile
El Negrillar
El Negrillar

El Negrillar is a volcanic field in the Andes. Located south of the Salar de Atacama and west of the Cordón de Púlar, it generated cinder cones and lava flows. Covering a surface area of 220 square kilometres (85 sq mi), it is the largest volcanic field in northern Chile, with almost a hundred vents that produced mainly lava flows. Owing to the arid climate, landforms are well preserved. Radiometric dating has yielded ages of less than 1.5 million years, with the most recent eruption occurring about 141,000 years ago. Parts of the Holocene Socompa debris avalanche overlie the field. A groundwater system underlies the volcanic field and some cones formed through phreatomagmatic eruptions. El Negrillar is located in a complex tectonic regime, characterized by numerous faults. The town of Tilomonte and various power lines, mines and water wells are in the area.

Geography and geomorphology

The Central Volcanic Zone (CVZ) of the Andes is a northwest-south trending volcanic arc that extends from Peru over Bolivia to Chile and Argentina.[2] Most of its 44[3] volcanoes are young stratovolcanoes, but there are also monogenetic volcanoes and the Altiplano-Puna volcanic complex, which has produced more than 15,000 cubic kilometres (3,600 cu mi) of volcanic rocks.[4] Stratovolcanoes in the El Negrillar area include Socompa to the south, Pular to the east of the volcanic field,[5] and Aguas Delgadas.[6] Towns in the area include Monturaqui, Peine, Chile (es), Tilomonte, Tilopozo,[3] and a mining camp southwest of the field,[5] there are cross-border power lines,[7] and the local aquifer is pumped by various mining companies in the area[8] just south of the volcanic field.[5] Interest in the monogenetic volcanoes of the area arose in the 2010s and 2020s.[9]

The El Negrillar field, also known as Negros de Aras,[1] is south of the Salar de Atacama,[10] not far from the border between Argentina and Chile,[5] and consists of numerous unvegetated[11] scoria cones and lava flows.[12] It includes 51 vents[6] named after Atacama flora and fauna,[13] and 98 separate lava flows[14] that extend downslope,[15] making it the largest monogenetic volcanic field of northern Chile.[7] Vents have produced mostly lava flows, but there are maars and scoria cones as well.[3] Some cones have been breached when lava flowed out.[16] The lava flows are blocky and have flow forms like scarps, ogives and levees[11] that are well-conserved by the arid climate of the field;[7] the longest flow has a length of 12 kilometres (7.5 mi).[17] The vents are spread over three sectors,[2] and the northern in an eastern and a western sector.[6] The northern and central sectors lie on the Tilomonte and Tilocalár ridges and the southern sector on the northwestern flank of the Aguas Delgadas volcano.[4] The total area covered by the field exceeds 220 square kilometres (85 sq mi).[18]

Geology

Off the western coast of South America, the Nazca Plate subducts beneath the South American Plate. The subduction is responsible for the volcanism of the CVZ[4] and the other two volcanic zones, the Northern Volcanic Zone and the Southern Volcanic Zone.[3] A fourth volcanic zone is known as the Austral Volcanic Zone.[19]

El Negrillar is part of a wider field of monogenetic volcanoes south of Salar de Atacama, which includes Morro Punta Negra, La Negrillar, Tilocalar and Cerro Tujle. Their formation was probably influenced by faulting, as there are north-south trending thrust faults, northwest-southeast trending transverse faults[2] and various types of folds,[20] which enable magma ascent[2] through the 70 kilometres (43 mi) thick crust.[4] Monogenetic activity in the area has progressively migrated north, with the youngest age being the 77,000 ± 54,000 years of Cerro Overo,[21] and the volcanoes share a common magma source.[22] El Negrillar is by far the largest of all these monogenetic volcanic fields.[23]

The surrounding and underlying terrain consists mostly of various volcanic rocks and alluvial fans.[6] A 60 kilometres (37 mi) long north-south trending depression runs south from Salar de Atacama and is filled by water-containing volcanic rocks[24] of the Salín Formation.[8] They form the Monturaqui-Negrillar-Tilopozo groundwater system, which conveys water to the Tilopozo area of Salar de Atacama. The flow[25] and composition of its waters are influenced by the El Negrillar volcanic field,[26] which lies in the middle of the groundwater body and separates it into two halves.[27]

Rocks erupted at El Negrillar have compositions ranging from basaltic andesite to dacite, with some trachytic components, and define a calc-alkaline suite[28] with five distinct members.[29] They contain phenocrysts of amphibole, olivine, plagioclase and pyroxene; quartz has been reported as well.[30] Composition varies from the northern to the southern sector, as magmas of the southern sector are more primitive with fewer crystals and volatiles.[31] The adakite-like composition implies that the magmas originated at great depths, where garnet is stable,[32] from melting of a small fraction of crustal and mantle rocks. The magmas underwent fractional crystallization[33] and during their ascent they absorbed varying quantities of crustal material.[34] Their total volume is about 6.8 cubic kilometres (1.6 cu mi),[35] making it one of the largest monogenetic volcanic fields worldwide.[10]

Eruption history

El Negrillar formed during the last 1.5 million years[29] in the Pleistocene[lower-alpha 1]. Eruptions produced lava flows, with subordinate explosive activity,[2] at effusion rates reaching from a few to a few tens of cubic metres per second. Some eruptions may have lasted more than a year.[37] Ages of the volcanoes range from 982,000 ± 8,000 to 141,000 ± 72,000 years,[38] and often do not match the appearance of the vents.[21] It is possible that a change in tectonic regimen from compressive to extensive 780,000 years ago allowed the ascent of magma.[4] Monogenetic eruptions can happen in areas without previous volcanic activity, and are a threat to the Salar de Atacama area[3] and the infrastructure there.[29][39]

The three vents Copao, Sandillón and Ruda erupted phreatomagmatically; they are tuff cones with infilling lava domes.[40] The phreatomagmatic activity is probably a consequence of magma interaction with the Monturaqui-Negrillar-Tilopozo aquifer.[41] About 7,000 years ago, Socompa volcano collapsed[3] and partly buried the El Negrillar volcanoes.[10]

Notes

  1. Between 1.8 million years and 11,700 years ago.[36]

References

  1. 1.0 1.1 1.2 "El Negrillar". Smithsonian Institution. https://volcano.si.edu/volcano.cfm?vn=355106. 
  2. 2.0 2.1 2.2 2.3 2.4 Loaiza et al. 2023, p. 2.
  3. 3.0 3.1 3.2 3.3 3.4 3.5 Parra-Encalada et al. 2022, p. 2.
  4. 4.0 4.1 4.2 4.3 4.4 Loaiza et al. 2023, p. 3.
  5. 5.0 5.1 5.2 5.3 Vilches et al. 2022, p. 2.
  6. 6.0 6.1 6.2 6.3 Loaiza et al. 2023, p. 4.
  7. 7.0 7.1 7.2 Vilches et al. 2022, p. 3.
  8. 8.0 8.1 Anderson, Low & Foot 2002, p. 135.
  9. Parra-Encalada et al. 2024, p. 3.
  10. 10.0 10.1 10.2 Parra-Encalada et al. 2022, p. 4.
  11. 11.0 11.1 Parra-Encalada et al. 2022, p. 5.
  12. Aguilera et al. 2022, p. 4.
  13. Loaiza et al. 2023, p. 5.
  14. Loaiza et al. 2023, p. 7.
  15. Parra-Encalada et al. 2022, p. 7.
  16. Aguilera et al. 2022, p. 15.
  17. Parra-Encalada et al. 2022, p. 9.
  18. Loaiza et al. 2023, p. 6.
  19. Parra-Encalada et al. 2024, p. 2.
  20. Loaiza et al. 2023, p. 15.
  21. 21.0 21.1 Loaiza et al. 2023, p. 14.
  22. Parra-Encalada et al. 2024, p. 8.
  23. Parra-Encalada et al. 2022, p. 14.
  24. Rissmann et al. 2015, p. 165.
  25. Rissmann et al. 2015, p. 167.
  26. Rissmann et al. 2015, p. 170.
  27. Anderson, Low & Foot 2002, p. 139.
  28. Parra-Encalada et al. 2022, p. 8.
  29. 29.0 29.1 29.2 Aguilera et al. 2022, p. 3.
  30. Loaiza et al. 2023, p. 9.
  31. Parra-Encalada et al. 2022, p. 12.
  32. Parra-Encalada et al. 2024, p. 11.
  33. Parra-Encalada et al. 2024, p. 14.
  34. Parra-Encalada et al. 2024, p. 12.
  35. Loaiza et al. 2023, p. 17.
  36. International Chronostratigraphic Chart 2018.
  37. Parra-Encalada et al. 2022, p. 11.
  38. Loaiza et al. 2023, p. 10.
  39. Vilches et al. 2022, p. 12.
  40. Loaiza et al. 2023, pp. 7-9.
  41. Loaiza et al. 2023, p. 13.

Sources



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