Nevado Ojos del Salado is a dormant complex volcano in the Andes on the Argentina–Chile border. It is the highest volcano on Earth and the highest peak in Chile. The upper reaches of Ojos del Salado consist of several overlapping lava domes, lava flows and volcanic craters, with sparse ice cover. The complex extends over an area of 70–160 square kilometres (27–62 sq mi) and its highest summit reaches an altitude of 6,893 metres (22,615 ft) above sea level. Numerous other volcanoes rise around Ojos del Salado.
Ojos del Salado | |
---|---|
Highest point | |
Elevation | 6,893 m (22,615 ft) |
Parent peak | Aconcagua |
Isolation | 630.5 km (391.8 mi) to Aconcagua[1] |
Listing | Volcanic Seven Summits Seven Second Summits Country high point Ultra |
Coordinates | 27°06′32″S 68°32′28″W / 27.109°S 68.541°W |
Geography | |
Location | Argentina–Chile |
Parent range | Andes |
Geology | |
Mountain type | stratovolcano |
Last eruption | 750 CE ± 250 years |
Climbing | |
First ascent | February 26, 1937, by Jan Alfred Szczepański and Justyn Wojsznis |
Easiest route | Scramble |
Being close to the Arid Diagonal of South America, the mountain has extremely dry conditions, which prevent the formation of substantial glaciers and a permanent snow cover. Despite the arid climate, there is a permanent crater lake about 100 m (330 ft) in diameter at an elevation of 6,480 metres (21,260 ft)-6,500 metres (21,300 ft) within the summit crater and east of the main summit. This is the highest lake of any kind in the world. Owing to its altitude and the desiccated climate, the mountain lacks vegetation.
Ojos del Salado was volcanically active during the Pleistocene[a] and Holocene,[b] during which it mainly produced lava flows. Activity was in two phases and a depression or caldera formed in the course of its growth. The volcano was also impacted by eruptions of its neighbour to the west, Nevado Tres Cruces. The last eruption occurred around 750 CE; steam emissions observed in November 1993 may have constituted another eruptive event.
An international highway between Argentina and Chile crosses north of the mountain. Ojos del Salado can be ascended from both countries; the first ascent was made in 1937 by Jan Alfred Szczepański and Justyn Wojsznis , members of a Polish expedition in the Andes. During the middle of the 20th century there was a debate on whether Ojos del Salado or Aconcagua was the highest mountain in South America which was eventually resolved in favour of Aconcagua.
Name
editThe name Ojos del Salado [ˈo.xos d̪el saˈla.ð̞o] refers to a river, Río Salado[c] ("Salty River"), that a 1937 Polish expedition used to reach the mountain.[5] It is unclear whether the name was already used before by a Chile-Argentina boundary commission.[5] Another theory posits that the name means "salty eyes" or "salty springs", referring to mineral deposits on its flanks.[6] The mountain is often referred to as Cerro Ojos del Salado and Nevado Ojos del Salado; the former is a common term for "mountain" in Chile and the latter means "snowy", referring to snow-covered mountains.[7] There are two summits, known as the eastern or Argentine and western or Chilean summit; both lie along the international boundary and get their names after the country from which they can be more easily reached.[8]
Geography and geomorphology
editOjos del Salado is part of the High Andes[9] and rises from the southern end of the Puna de Atacama,[10] a high plateau next to the Atacama Desert with an average elevation of 4,000 metres (13,000 ft).[11] The border between Argentina and Chile runs across the summit of the mountain in east-west direction.[9] The Argentine part is within Catamarca Province[12] and the Chilean in Copiapo Province[13] of the Atacama Region.[14] The highway Chile Route 31 runs between the city of Copiapo west of the volcano and the Paso San Francisco[d] to Argentina,[9] lying about 20 kilometres (12 mi) north of the volcano, making it more accessible than many other volcanoes there.[18] The region is uninhabited and lacks water resources; many parts are only accessible through dirt roads.[19]
Ojos del Salado is a dormant volcano that rises to 6,893 metres (22,615 ft),[20][10][11] 6,879 metres (22,569 ft)[21] or 6,887 metres (22,595 ft) elevation.[18] It is the world's highest volcano[e] and the second-highest summit of the Andes,[23] and the highest summit in Chile.[24] Ojos del Salado is not a single conical summit but a massif/complex volcano[18][25] formed by overlapping smaller volcanoes,[26] with over 20 craters.[27] Two edifices, less than 2.5 kilometres (1.6 mi) wide, flank the 1.3-by-0.5-kilometre-wide (0.81 mi × 0.31 mi) summit crater on its eastern and western side.[28] Basalt, gravel, pumice and scoria crop out in its rim, which is lower on the northern side.[29] A second 300–400-metre-wide (980–1,310 ft) crater lies just west of the summit crater.[27] Reportedly, the summit is separated by a deep gap into two separate peaks.[30] Thick short dacitic lava flows make up the core 13 by 12 kilometres (8.1 mi × 7.5 mi) area of the volcano but pyroclastic fall material covers much of the summit area.[31]
The massif rises about 2 kilometres (1.2 mi) above the surrounding terrain and covers an oval area of about 70 square kilometres (27 sq mi)[18]–160 square kilometres (62 sq mi),[32] consisting of lava domes, lava flows,[33] pyroclastic cones and volcanic craters[21] that rise about 2 kilometres (1.2 mi) above the surrounding terrain.[22] The massif appears to feature a buried caldera,[21] visible through a slope break from the western side,[34] and/or a 2.5-kilometre-wide (1.6 mi) depression.[35] The occurrence of a rift-like structure with numerous small craters has also been reported.[36] Volcanic cones form a north-northeast trending alignment on the western flank.[37] Cerro Solo and El Fraile are large lava domes on the flanks of Ojos del Salado,[33] and produced pyroclastic flows.[38]
Wind-driven erosion has produced megaripple sand fields on the northern flank. Above 6,000 metres (20,000 ft) elevation talus-covered slopes and lava flows form the bulk of the surface, while the desert plains begin below 5,000 metres (16,000 ft) elevation.[39] The ground above 4,000–5,600 metres (13,100–18,400 ft) elevation is expected to contain permafrost,[40] which is likely continuous at higher elevations[41] and overlaid with a thin active layer.[42] Cryoturbation[f] landforms were not conspicuous according to Nagy et al. 2019,[43] presumably because wind-driven phenomena overprint the effects of cryoturbation.[44] Mass movements have left traces on the mountain.[45]
Lakes
editOjos del Salado hosts the highest lake in the world[46][47][g] in the form of the crater lake[49] in the summit crater.[50] Fed by permafrost and snowfields, it lies at 6,480–6,500 metres (21,260–21,330 ft) elevation. It is surrounded by fumaroles and covers an area of 6,000 square metres (65,000 sq ft). Waters in a creek flowing into this lake reach temperatures of 40.8 °C (105.4 °F).[51][49]
There are two lakes at 5,900 metres (19,400 ft) elevation on the northeastern slope, c. 4 kilometres (2.5 mi) away from the higher lake. Each has an area of 2,500 square metres (27,000 sq ft) and an estimated depth of 1 metre (3 ft 3 in).[51][49] Ephemeral lakes[h] occur at 5,900–6,000 metres (19,400–19,700 ft) elevation,[40] when meltwater from permafrost accumulates in closed depressions.[53] Such ponds may form in depressions at 6,380 metres (20,930 ft) elevation.[54] Some of the lakes may be permanently frozen.[55] Lakes might disappear with climate change owing to the breakdown of permafrost.[53]
Surroundings
editThe landscape is dominated by volcanoes,[56] many of Pleistocene or Holocene age,[57] and is the highest volcanic region in the world.[58] Young volcanoes have conical shapes and often feature summit craters.[59] Travellers have called the region a "moonscape".[60] There are hot springs in the region,[61] such as the Termas Laguna Verde at the shores of Laguna Verde, which are frequented by visitors.[62]
The volcano lies in the middle of an over 80-kilometre (50 mi) long east–west trending chain of volcanoes[18] that form a drainage divide and includes the volcanoes Nevado Tres Cruces, Incahuasi[63] and Cerro Blanco. This chain of volcanoes appears to be part of the Ojos del Salado-San Buenaventura tectonic lineament,[64] which corresponds to a geographic (southern boundary of the Puna de Atacama)[64] and tectonic discontinuity in the region.[65] The lineament may be a consequence of the subduction of the Copiapo Ridge at this latitude.[65] An alternative view is that the subducting Copiapo Ridge is actually located north of the lineament; this would be more consistent with the theory that the subduction of such ridges gives rise to gaps in the volcanic chain.[66]
Ice and glaciers
editExcept for firn and small glaciers in sheltered parts of the mountain, Ojos del Salado lacks substantial ice cover. This is due to the arid climate of the region, which causes the equilibrium line altitude of ice to rise above the top of the mountain[40] and keeps most peaks in the area ice-free.[10] Only farther south at Tronquitos does more extensive glaciation begin.[56] Temporary ice and snow accumulations can be mistaken for glaciers,[67] and glacier areas shown on maps are often actually immobile firn fields.[68] The ice reaches thicknesses of only 10–15 metres (33–49 ft) and areal extents of a few hundred metres. Meltwater feeds streams.[69]
Climbing parties in 1956 reported two glaciers on the northwestern slope,[70] a 1958 report indicated that an ice body at 6,600 metres (21,700 ft) elevation descends into two branches and is followed at lower elevation by another glacier also with two branches—but in neither case with any evidence of movement—[71] and in 2014 there was ice in the summit crater[72] and substantial glaciers on the eastern and southern slopes, which reached elevations below 6,000 metres (20,000 ft).[73] There have been increases in ice area between 1974 and 1983[74] but between 1986 and 2000, ice area decreased by 40%.[75] The melting of the ice is expected to produce an increased discharge at first, but eventually ice diminishes to the point that runoff will decline.[76]
Penitentes have been encountered by climbers as early as 1937,[52] in 1949 there were reportedly 5–8 metres (16–26 ft) high penitentes on Ojos del Salado.[77] Penitentes are high ice spires[78] which form when ice sublimates in the intense insolation.[73]
Subsurface ice
editIce buried beneath sand[79] and encased in moraines is more important than surface ice at Ojos del Salado. It is retreating but the insulating effect of the cover slows the retreat.[80] Cryokarst,[81] erosional gullies and so-called "infilled valleys"[i] have been observed; they most likely form when buried ice and snow melt.[83] The combined effect of erosion by the meltwater and the disappearance of ice volume creates cavities that collapse and form the valleys and pseudokarst landforms.[80] Pseudokarst landforms and dolines are other structures generated by the melting of buried ice.[84]
Past glaciation
editLateral moraines altered by wind erosion occur north of Ojos del Salado[44] and some lava flows bear traces of glaciation.[31][85] Research published in 2019 found cirques and U-shaped valleys on Ojos del Salado.[86] However, there is no evidence of Pleistocene glacier advances in the region[87][88][89] nor any indication of a Pleistocene snowline,[90][91] although cirques have been reported from Nevado Tres Cruces[91] and some sources propose the existence of glaciers 19,000 years ago.[92] The monsoon reached farther south during the Pleistocene but did not reach Ojos del Salado, allowing the development of glaciers only at more northern latitudes.[88] Westerly winds did not regularly influence the climate at the volcano, either.[93]
Geology
editIn South America, there are about 200 volcanoes with evidence of eruptions during the Pleistocene and Holocene[94] along the western coast, where the Nazca Plate and Antarctic Plate subducts beneath the South America Plate in the Peru-Chile Trench. Volcanic activity is localized in four major volcanic belts, the Northern, Central (CVZ), Southern and Austral Volcanic Zones; these are separated by belts without volcanic activity[95] and form part of the Pacific Ring of Fire.[96] Where volcanic activity occurs, the subduction process releases fluids from the downgoing slab which trigger the formation of melts in the mantle that eventually ascend to the surface and give rise to volcanism.[94][j]
The CVZ spans Peru, Bolivia, Chile and Argentina and contains about 1,100 recognized volcanoes, many of which are extremely old and are still recognizable owing to the low erosion rates in the region.[94] Apart from stratovolcanoes, the CVZ includes numerous calderas, isolated lava domes and lava flows, maars and pyroclastic cones. Most of the volcanoes are remote and thus constitute a low hazard.[99] Ojos del Salado is part of the CVZ and constitutes its southern boundary.[k] South of the volcano[95] volcanism ceased during the last six million years[103] and until 32° south, subduction takes place at a shallow angle and volcanism is absent in the "Pampean flat-slab". The shallow angle may be a consequence of the subduction of submarine topography, such as the Copiapo Ridge at the northern end of the Juan Fernández Ridge at the southern margin of the gap.[104][94]
Local
editThe basement in the region crops out in the Cordillera Claudio Gay area, and consists of sedimentary rocks of Devonian[l]-Carboniferous[m] age. The rocks are intruded by and covered by granites and rhyolites associated with Permian volcanic rocks and the Choiyoi Group. Oligocene[n] to recent volcanic rocks and volcano-sedimentary formations cover this basement.[58] The topography at Ojos del Salado bears evidence of what may have been past magmatic uplift.[105] Seismic tomography has yielded evidence of a low seismic velocity anomaly underneath the volcano that may constitute the pathway through which water emanating from the downgoing slab rises through the mantle and gives rise to melting.[106]
Volcanism in the region commenced 26 million years ago, when the Farallon Plate broke up and subduction speed increased. Initially between 26 and 11 million years ago activity was concentrated in the Maricunga region 60 kilometres (37 mi) west of the Ojos del Salado region, where only small-volume volcanism took place and which constituted the back-arc to the Maricunga arc. Between 8–5 million years ago activity declined in the Maricunga region and increased in the Ojos del Salado region, until Maricunga volcanism ceased 4 million years ago. This shift coincided with a gradual flattening of the subduction process since the Miocene[o] and was accompanied by change in crustal and mantle properties that are reflected in the isotope ratios of erupted volcanic rocks.[107] During the Quaternary, volcanism formed the edifices of Cerro Solo, El Fraile, Incahuasi, El Muerto, El Muertito, Falso Azufre, Nevado San Francisco, Nevado Tres Cruces and Ojos del Salado, which together cover over half of the area.[33] Apart from the large volcanoes, many smaller mafic monogenetic volcanoes developed in the area, especially east of Ojos del Salado.[108] Pleistocene volcanism was limited to the Ojos del Salado area, where recent faulting offset volcanic rocks.[109] The large dimensions of Ojos del Salado indicate that magmatism was focused here.[110]
Composition
editVolcanic rocks erupted by Ojos del Salado form a calc-alkaline[111] potassium-rich suite of dacitic rocks,[18] with occasional andesite and rhyodacite.[112] Earlier in the geological history of the region more mafic magmas also erupted. The rocks contain phenocrysts like augite, biotite, hornblende, hypersthene, opaque minerals, plagioclase, pyroxene and quartz.[31][18] Magma mixing phenomena produced olivine and pyroxene xenocrysts and amphibole reaction rims.[38]
Eruption history
editVolcanic activity probably commenced 3.3–1.5 million years ago[33] or during the late Pleistocene.[18] The 3.7±0.2 million years old Las Lozas Andesite may have been a precursor of Ojos del Salado.[33] The oldest rocks of Ojos del Salado are 3.5–3.4 million years old dacites in the lower parts of the volcano.[31] Argentine geological maps define a "Ojos del Salado basal complex", which consists of a number of Miocene volcanoes that have erupted andesite and dacite, partially in glacial environments.[113]
The volcano developed in two stages, with the more recent one grown on top of the older.[27] A somma volcano structure may have formed during an eruption that generated the pumice deposits on the lower slopes of the volcano, and there are potential air fall deposits north of it. Ojos del Salado may[18] or may not have produced pyroclastic flows; the neighbouring Nevado Tres Cruces c. 67,000 years ago produced extensive deposits on and around Ojos del Salado and in the valley between the two volcanoes; these were originally interpreted to have originated at Ojos del Salado.[114][115][32] A pyroclastic flow erupted by Ojos del Salado descended the Cazadero valley and constitutes the "El Quemado Ignimbrite".[116] Cerro Solo, whose emplacement was probably accompanied by intense pyroclastic flow activity,[117] and lava domes in the summit region are of Pleistocene age.[35] The long-term growth rate of Ojos del Salado amounts to 0.03–0.04 cubic kilometres per kiloare (0.0072–0.0096 cu mi/ka).[118]
Radiometric dating has yielded ages of 1.53 ± 0.13,[31] 1.2 ± 0.3 million and less than one million years ago for rocks in the northwestern part of Ojos del Salado,[119] 1.08 ± 0.09 million years for flows underlying the summit,[28] 1.08 ± 0.04 million years for the northern flank of Ojos del Salado, 700,000±50,000 for its western flank, 450,000±60,000 for El Muerto,[112] 340,000 ± 190,000 years for the summit rocks,[28] and 230,000±40,000 years for El Fraile.[112] Lava flows and a lava dome on the northern flank have yielded ages of 100,000 ± 17,000 and 35,000 years, respectively.[32][120] The "El Quemado Ignimbrite" may be either 200,000 or less than 50,000 years old.[121] The youngest dates reported are 30,000 years ago.[92]
Holocene and historical activity
editThe volcano produced lava flows during the Holocene,[21] which cover an area of 120 square kilometres (46 sq mi), as well as pumice deposits at Laguna Verde and elongated fractures in the summit region.[35] A rhyodacitic eruption[18] was dated with tephrochronology to have occurred 750 ± 250 CE,[122] and may have deposited tephra over the Bolson de Fiambala and in the Tafí and Villa Vil areas of northwestern Argentina.[123] Many volcanic rocks have a fresh appearance but there is no clear evidence of recent activity.[32]
There are no confirmed historical eruptions[21][p] and the volcano is presently inactive.[61] In November 1993, observers witnessed ash and steam columns on two separate days[125] but no deformation of the volcano was observed by satellites during this occasion.[126] An ash cloud observed on June 13, 2015, and which led to a warnings about volcanic ash to aircraft turned out to be wind-blown volcanic ash in the Fiambala valley.[127] Seismic activity has been reported.[128]
Hazards
editThere is no information on volcanic hazards at Ojos del Salado[18] and volcanic hazards in the Central Volcanic Zone are poorly reconnoitred,[129] but a 2018 presentation at the University of Auckland ranked it 14th of 38 Argentine volcanoes[130] and the Chilean geological agency SERNAGEOMIN 75th out of 92, thus as a very low risk volcano.[131] The latter has published hazard maps for the Chilean part of the volcano.[132] Future eruptions would most likely produce lava domes, lava flows and minor explosive activity,[115] and the presence of ice on the mountain makes it a potential source for lahars.[133] Effects would most likely be limited to the direct surroundings of the volcano, such as highway Chile Route 31 .[115]
Fumarolic activity
editThere are fumaroles that emit sulfurous fumes.[61] Polish climbers in 1937 first observed this activity, 200 metres (650 ft) below the summit[3] and in the summit crater.[27] Fumarolic activity appears to be linked to a rift structure on the volcano.[18] Climbers in 1957 reported that the fumaroles were noisy and the emissions intense enough that with unfavourable winds they could suffocate people.[70] The fumaroles can be observed from satellites in the form of temperature anomalies which reach 4 K (7.2 °F) above background temperatures,[134] but the steam plumes are poorly visible from the ground except from close distance[135] or during episodes of increased fumarolic activity.[136] Geysers have been reported in the summit region.[137] Hot springs occur at the shores of Laguna Verde[138] which may be part of a hydrothermal circulation system of Ojos del Salado.[139] According to a 2020 publication, the mountain was being evaluated for the generation of geothermal power.[140]
Climate
editDetailed climate data do not exist for the area.[60] The Puna de Atacama region has an extreme climate with strong wind, high elevation, a dry climate[11] and high insolation;[141] the area is in[142] or just south of the Arid Diagonal.[56]
Temperatures at lower elevations can exceed 10 °C (50 °F) but mean annual temperatures only reach −10 °C (14 °F).[143] Mean winds at Laguna Verde reach maximum speeds of 8–10 metres per second (26–33 ft/s) in winter, on the mountaintops they can exceed 10 metres per second (33 ft/s) and can impede climbing attempts. Winds blow strongest in the afternoon.[141] The winds produce aeolian landforms such as aeolian sediments,[121] dunes, gravel pavements, abraded rocks and megaripples at lower elevations,[144] and redeposit snow.[141]
Precipitation consists mostly of hail and snow.[19] It either amounts to less than 150 millimetres (5.9 in) per year[145] or reaches 300–500 millimetres (12–20 in) per year. Compared to sites farther north, precipitation falls primarily during winter,[56] although snowfall is common in summer.[145] Precipitation probably peaks at 5,500 metres (18,000 ft) where the cloud base lies;[141] above that elevation it decreases to about 200 millimetres (7.9 in).[146] Snow cover in the area is sporadic[147] and quickly sublimates,[41] which hinders its measurement;[145] the average snow cover is less than 5 centimetres (2.0 in) thick.[148]
Vegetation and fauna
editDue to the dry climate, the region is a desert with little vegetation occurring above 4,600 metres (15,100 ft) elevation,[41] and none above 4,900 metres (16,100 ft).[149] However, lichens and mosses have been found at higher elevations[150] and green growths have been reported from the summit region.[137] As of 2007[update], there were no reports of plants in the waterbodies on Ojos del Salado.[47] Salt, acid and cold-tolerant bacteria have been recovered from sediments in the lakes on Ojos del Salado, consistent with microorganism samples from similar dry volcanic environments.[151]
A diverse flora and fauna has been described in the lower elevation regions south-southeast of Ojos del Salado.[152] Birds such as ducks, flamingos and geese and mammals such as guanacos and vicuñas occur in the Santa Rosa-Maricunga-Negro Francisco region.[13] Chinchillas and vicuñas live in the valleys south of Ojos del Salado, and have drawn humans to the region.[153] Mice venture to elevations of 5,250 metres (17,220 ft),[154] and earwigs have been observed at 5,960 metres (19,550 ft) elevation.[155]
Human history
editAs Ojos del Salado is hidden behind[156] and nested among many peaks of similar elevation, for centuries travellers and mountaineers paid little attention to the mountain.[5] Its remoteness meant that for a long time, both its elevation and exact topography were unclear.[60] The positions and names of the mountains were frequently confused.[157][5]
The Inca used the Paso San Francisco as a major crossing of the Andes[158] but there is no evidence of them building any structures on Ojos del Salado[q][161] even though a number of such sites exist in the surrounding region.[15] The Spanish conquistador Diego de Almagro[162] crossed the Andes at Ojos del Salado but did not mention it.[5][r] Ojos del Salado is likewise absent from the 1861 plans of William Wheelwright for a railway across Paso San Francisco.[78] The explorer Walter Penck crossed the area in 1912/13 and 1913/14[61] but did not identify the mountain.[163]
Ascents and debate on elevation
editIn 1896, 1897 and 1903 the Chile-Argentina boundary commission identified a peak in the area and named it "Ojos del Salado";[5] according to a myth[164] their "Ojos del Salado" was a much smaller mountain and the actual Ojos del Salado was their "Peak 'e'".[5] The Polish climbers Justyn Wojsznis and Jan Szczepański from the Second Polish Andean Expedition[165] reached the summit on February 26, 1937[156] and left a cairn[s][166] but most of the maps and report they drafted were lost during World War II.[167]
After the Polish expedition, the mountain remained unclimbed until 1955, although expeditions went to its lower slopes and sometimes confused other peaks for Ojos del Salado. In that year an expedition from Tucumán[3] ascended a mountain south of Ojos del Salado, which they mistook for the volcano. They stated that the peak may be higher than Aconcagua, which media reported as if it were proven fact.[168] These measurements set off a debate whether Ojos del Salado was higher than Aconcagua and thus the highest summit of the Western Hemisphere,[169] and drew attention to the mountain. Three separate Chilean, Argentine and Austrian parties went to Ojos del Salado in 1956; the Chilean party measured an elevation of 7,084 metres (23,241 ft) with a barometer, a value that was once again presented as proven by the press[168] despite the unreliability of this technique.[170] The Chilean party also claimed seeing the Argentine pampa and the Pacific Ocean from the summit.[29] In 1957, the official elevation of Ojos del Salado was 6,870 metres (22,540 ft) according to Argentina and 6,880 metres (22,570 ft) according to Chile.[171]
The debate on the elevation and confusion about which mountain was Ojos del Salado and who climbed which peak prompted an expedition by the American Alpine Club in 1956.[170] The expedition was hindered by bad weather conditions[172] and a gust of wind stretching a measurement line may have almost frustrated the goal to determine the summit elevation of Ojos del Salado.[173] The same party later used geodetic methods to establish the elevation of Ojos del Salado as 6,885.5 ± 3 metres (22,590.2 ± 9.8 ft) and lower than[174] the 6,960 metres (22,830 ft) high Aconcagua.[175] In 1989, Francesco Santon of the University of Padua in Italy, with Argentine assistance, used GPS-based positioning to determine an elevation of 6,900 ± 5 metres (22,638 ± 16 ft).[176]
Mountaineering and tourism
editOjos del Salado and the surrounding mountains draw fewer mountaineers than Aconcagua, with only several hundred climbers every year. Since the 1990s commercial tours have become important facilitators for ascents,[177] and the number of climbers has increased in the 21st century. Ojos del Salado is one of the Second Seven Summits and Volcanic Seven Summits mountaineering challenges. It is easier to climb than an eight thousander owing to its lower elevation and the absence of rock faces and ice,[178] but the high elevation,[t] cold, dry and windy weather[u] and impassable terrain are common challenges for would-be climbers[181] and only a third of all climbing attempts reach the summit.[142] Would-be mountaineers need to consult weather forecasts and prepare equipment before attempting an ascent.[182] The mountain can be ascended from both the Argentine and the Chilean side, but owing to the better logistics most ascents occur from the Chilean side.[177] The increasing mountaineering activities on Ojos del Salado have raised concerns about environmental impacts.[17]
Ascent from the Chilean side is easier as the first refuge can be reached by car, but the actual climb is easier from the Argentine side.[183] A dirt road departing from the Chile Route 31 highway to Paso San Francisco heads south to Ojos del Salado, past Refugio Murray to the bivouac Refugio Universidad de Atacama/Jorge Rojas at 5,200 metres (17,100 ft) elevation,[10] from there a path goes to Refugio Tejos at 5,825 metres (19,111 ft) elevation and eventually to the summit of Ojos del Salado through scree-covered slopes and a steep ridge/couloir at the end.[184][178] Ropes and supports are available.[178] Between 2004 and 2015, a Chilean company held a mountaineering concession for the Chilean side and maintained the infrastructure there; after the end of the concession maintenance resumed in 2018.[185] From Argentina, the path runs from Cazadero Grande (Quemadito hut) along a large creek to its origin at Aguas Calientes at 4,200 metres (13,800 ft). From there it continues first up dry valleys to Acqua di Vicuna at 4,950 metres (16,240 ft) elevation, to the El Arenal plateau at 5,500 metres (18,000 ft) elevation and eventually along various routes to Ojos del Salado.[186] The mountain is also accessible by vehicle, up to 6,650 metres (21,820 ft)[187] or 5,900 metres (19,400 ft) elevation, through a dirt road built after a helicopter accident in 1994.[188]
West of the volcano lies the Nevado Tres Cruces National Park[9] and in 1991/1994 there were plans to make a national park on the Argentine side as well.[189] As of 2020[update], the establishment of a "zone of touristic interest" encompassing Ojos del Salado was under discussion in Chile.[190]
Other uses
editAstronomers have surveyed the volcano for the possibility of creating an observatory there.[18][v] The landforms such as the gullies[83] and crater lakes and their conditions,[192] and climatic conditions around Ojos del Salado have also led researchers to investigate it as a potential analogue to environments on Mars.[143] The volcano is one of several depicted on Chilean passports.[193]
Numerous record-high altitude attempts with vehicles have been carried out at Ojos del Salado, including with cars,[194] electric vehicles,[195] motorcycles[196] and utility vehicles.[197] A modified car was driven to an elevation of 6,688 metres (21,942 ft) in 2015.[195]
See also
editNotes
edit- ^ The Pleistocene is the geological period between 2.58 million and 11,700 years ago.[2]
- ^ The Holocene is the geological period between 11,700 years ago and today.[2]
- ^ The river does not actually originate on Ojos del Salado;[3] according to the Deutscher Alpenverein map from 2004, the Rio Salado originates next to Cerro Solo.[4]
- ^ Paso San Francisco one of the most important crossings of the Andes[15] with over 8,100 people crossing in 2018[16] when the road was paved.[17]
- ^ Relative to sea level; relative to base level Mauna Loa is considerably higher.[22]
- ^ Cryoturbation landforms form when frost triggers deformation of the soil.[43]
- ^ There are waterbodies at 6,600 metres (21,700 ft) elevation;[48] if considered lakes they may be the highest lakes in the world.[46][47]
- ^ An early report of such lakes goes back to 1937.[52]
- ^ Several metres wide valleys that are filled with erosion debris.[82]
- ^ Zentilli 1974 considered the volcano linked to the so-called "Easter Hot Line" of volcanoes[97] but they do not have a common magma.[98]
- ^ Other Pliocene-recent volcanoes such as Cerro Bonete[100] and Incapillo occur south of Ojos del Salado[101] but volcanoes there are more isolated and farther inland than these north of Ojos del Salado.[102]
- ^ The Devonian is the geological period between 419.2 ±3.2 and 358.9 ±0.4 million years ago.[2]
- ^ The Carboniferous is the geological period between 358.9 ±0.4 and 298.9 ±0.15 million years ago.[2]
- ^ The Oligocene is the geological period between 33.9 and 23.03 million years ago.[2]
- ^ The Miocene is the geological period between 23.03 and 5.333 million years ago.[2]
- ^ Historical eruptions may have been missed, however, due to the remote location of the volcano.[124]
- ^ The explorer Johan Reinhard was referenced in a 2002 publication to have found an Inca archeological site on Ojos del Salado[159] but the archaeologist Nicholas J. Saunders reported an absence of ruins on the mountain in 1992[160] and Johan Reinhard likewise mentioned that there were no ruins on Ojos del Salado in that year.[161]
- ^ The large losses of animals and men during the crossing may have been the inspiration for the many death-themed mountain names in the region.[158]
- ^ Later Austrian climbers found out that the cairn was not located on the exact summit of Ojos del Salado.[156]
- ^ The topography of the region with the mountain rising sharply from a high-altitude region makes acclimatization difficult, and medical resources to deal with acute mountain sickness are far away.[179]
- ^ Winds are a significant nuisance for mountaineers, damaging equipment, blinding people and causing dangerous wind chill.[180]
- ^ Brunier 1989 discussed astronomical observations on Ojos del Salado rather than directly making an observatory there.[191]
References
edit- ^ Direct virtual measurement with Google Earth, Line Ruler tool
- ^ a b c d e f International Commission on Stratigraphy 2018.
- ^ a b c Carter 1957, p. 76.
- ^ Deutscher Alpenverein 2004.
- ^ a b c d e f g Carter 1957, pp. 74–75.
- ^ Bobylyova 2016, p. 125.
- ^ Williams & Ferrigno 1988, p. 1122.
- ^ Subsecretaría de Turismo 2019, pp. 7–8.
- ^ a b c d Gspurning, Lazar & Sulzer 2006, p. 60.
- ^ a b c d Nüsser & Dame 2015, p. 68.
- ^ a b c Nagy et al. 2019, p. 4.
- ^ González & Würschmidt 2008, p. 48.
- ^ a b Informacíon turística 2021.
- ^ Alvaro, Bertin & Orozco 2012, p. 7.
- ^ a b Subsecretaría de Turismo 2019, p. 6.
- ^ Subsecretaría de Turismo 2019, p. 16.
- ^ a b Nagy et al. 2023, p. 28.
- ^ a b c d e f g h i j k l m OSE 2021.
- ^ a b Nüsser & Dame 2015, p. 67.
- ^ Naranjo et al. 2019, p. 40.
- ^ a b c d e GVP 2021, General Information.
- ^ a b Siebert, Simkin & Kimberly 2019, p. 12.
- ^ Baker, Gonzalez-Ferrán & Rex 1987, p. 85.
- ^ Butelski 2020, p. 1.
- ^ Kaufmann 1998, p. 63.
- ^ Kay, Coira & Mpodozis 2008, p. 167.
- ^ a b c d Naranjo et al. 2019, p. 26.
- ^ a b c Kay, Coira & Mpodozis 2008, p. 169.
- ^ a b Carter 1957, p. 90.
- ^ Carter 1957, p. 91.
- ^ a b c d e Kay, Coira & Mpodozis 2008, p. 168.
- ^ a b c d Moreno & Gibbons 2007, p. 154.
- ^ a b c d e Mpodozis et al. 1996, p. 545.
- ^ Gonzalez-Ferran, Baker & Rex 1985, p. 434.
- ^ a b c GVP 2021, Photo Gallery.
- ^ Gonzalez-Ferran, Baker & Rex 1985, p. 436.
- ^ Kay, Coira & Mpodozis 2008, pp. 168–169.
- ^ a b Mpodozis et al. 1996, p. 546.
- ^ Nagy et al. 2019, p. 15.
- ^ a b c Nagy et al. 2019, p. 3.
- ^ a b c Aszalós et al. 2016, p. 603.
- ^ Dobiński 2020, p. 6.
- ^ a b Nagy et al. 2019, p. 9.
- ^ a b Nagy et al. 2019, p. 14.
- ^ Naranjo et al. 2019, p. 7.
- ^ a b Jacobsen & Dangles 2017, p. 21.
- ^ a b c Seimon, Halloy & Seimon 2007, p. 341.
- ^ Halloy 1983, p. 93.
- ^ a b c Aszalós et al. 2020, p. 742.
- ^ Vincent 2018, p. 15.
- ^ a b Aszalós et al. 2016, pp. 604–605.
- ^ a b Carter 1957, p. 75.
- ^ a b Aszalós et al. 2016, pp. 603–604.
- ^ Nagy, László & Zsolt, p. 53.
- ^ Jacobsen & Dangles 2017, p. 41.
- ^ a b c d Gspurning, Lazar & Sulzer 2006, p. 61.
- ^ Grosse et al. 2018, p. 4.
- ^ a b Mpodozis et al. 1996, p. 539.
- ^ Rubiolo et al. 2003, p. 56.
- ^ a b c Nüsser & Dame 2015, p. 66.
- ^ a b c d Kaufmann 1998, p. 53.
- ^ Subsecretaría de Turismo 2019, p. 9.
- ^ Gimenez et al. 2019, p. 471.
- ^ a b Mingari et al. 2017, p. 6761.
- ^ a b Gimenez et al. 2019, p. 474.
- ^ Le Roux et al. 2016, p. 46.
- ^ Gspurning, Lazar & Sulzer 2006, pp. 62–63.
- ^ Gspurning, Lazar & Sulzer 2006, p. 69.
- ^ Nagy et al. 2014, p. 454.
- ^ a b Carter 1957, p. 89.
- ^ Lliboutry, González & Simken 1958, p. 298.
- ^ Nüsser & Dame 2015, p. 70.
- ^ a b Nüsser & Dame 2015, p. 69.
- ^ Halloy 1983, p. 94.
- ^ Buchroithner 2010, p. 35.
- ^ Nagy et al. 2014, p. 461.
- ^ Lliboutry 1954, p. 334.
- ^ a b Nüsser & Dame 2015, p. 71.
- ^ Halloy 1983, p. 98.
- ^ a b Nagy et al. 2014, p. 455.
- ^ Kereszturi et al. 2022, p. 10.
- ^ Kereszturi 2020, p. 726.
- ^ a b Kereszturi 2020, p. 736.
- ^ Veress 2016, p. 465.
- ^ Rubiolo et al. 2003, p. 44.
- ^ Naranjo et al. 2019, pp. 9–10.
- ^ Núñez & Grosjean 1994, p. 16.
- ^ a b Messerli et al. 1992, p. 265.
- ^ Messerli et al. 1993, p. 124.
- ^ Hastenrath 1971, p. 263.
- ^ a b Haselton, Hilley & Strecker 2002, p. 221.
- ^ a b Kereszturi et al. 2022, p. 3.
- ^ Messerli et al. 1993, pp. 124, 127.
- ^ a b c d Moreno & Gibbons 2007, p. 147.
- ^ a b Geological Society of America 1991, p. 140.
- ^ Neukirchen 2022, pp. 218–219.
- ^ Gonzalez-Ferran, Baker & Rex 1985, p. 425.
- ^ Baker, Gonzalez-Ferrán & Rex 1987, p. 95.
- ^ Moreno & Gibbons 2007, p. 148.
- ^ Geological Society of America 1991, p. 141.
- ^ Mahlburg Kay & Mpodozis 2002, p. 49.
- ^ Bonatti et al. 1977, p. 2474.
- ^ Mahlburg Kay & Mpodozis 2002, p. 48.
- ^ Álvarez et al. 2014, p. 2.
- ^ Perkins et al. 2016, p. 1078.
- ^ Chen et al. 2020, p. 15.
- ^ Mpodozis et al. 1996, pp. 539, 547.
- ^ Grosse et al. 2020, p. 2.
- ^ Gonzalez-Ferran, Baker & Rex 1985, p. 440.
- ^ Geological Society of America 1991, pp. 151–152.
- ^ Baker, Gonzalez-Ferrán & Rex 1987, p. 90.
- ^ a b c Gonzalez-Ferran, Baker & Rex 1985, pp. 429–428.
- ^ Rubiolo et al. 2003, p. 36.
- ^ Gardeweg et al. 2000, p. 293.
- ^ a b c Alvaro, Bertin & Orozco 2012, p. 23.
- ^ Rubiolo et al. 2003, p. 45.
- ^ Gonzalez-Ferran, Baker & Rex 1985, p. 435.
- ^ Grosse et al. 2018, p. 20.
- ^ Mpodozis et al. 1996, p. 542.
- ^ Gardeweg et al. 2000, p. 292.
- ^ a b Rubiolo et al. 2003, p. 46.
- ^ GVP 2021, Eruptive History.
- ^ Báez et al. 2024, p. 12.
- ^ Siebert, Simkin & Kimberly 2019, p. 11.
- ^ GVP 2021, Latest Activity Reports.
- ^ Pritchard & Simons 2004, p. 10.
- ^ Mingari et al. 2017, pp. 6759–6760.
- ^ Murray-Bergquist et al. 2024.
- ^ Bertin et al. 2018, p. 15.
- ^ Bertin et al. 2018, p. 4.
- ^ SERNAGEOMIN 2019.
- ^ Alvaro, Bertin & Orozco 2012, Mapa1, Mapa2.
- ^ Seynova et al. 2017, p. 106.
- ^ Jay et al. 2013, p. 164.
- ^ Jay et al. 2013, p. 169.
- ^ Alam & Muñoz 2024, p. 5.
- ^ a b Halloy 1991, p. 248.
- ^ Alam & Muñoz 2024, p. 3.
- ^ Alam & Muñoz 2024, p. 7.
- ^ Picighelli 2023, p. 33.
- ^ a b c d Gspurning, Lazar & Sulzer 2006, p. 62.
- ^ a b Nagy et al. 2023, p. 25.
- ^ a b Kereszturi 2018, p. 1.
- ^ Nagy et al. 2019, pp. 9–10.
- ^ a b c Nagy et al. 2014, p. 453.
- ^ Naranjo et al. 2019, p. 10.
- ^ Nagy et al. 2019, p. 7.
- ^ Nagy et al. 2019, p. 10.
- ^ Storz et al. 2024, p. 729.
- ^ Halloy 1991, p. 252.
- ^ Aszalós et al. 2016, p. 612.
- ^ González & Würschmidt 2008, p. 59.
- ^ Roig 1955, p. 325.
- ^ Storz et al. 2024, pp. 729, 733.
- ^ Halloy 1983, p. 104.
- ^ a b c Carter 1957b, p. 241.
- ^ Roig 1955, p. 334.
- ^ a b Rundel & Kleier 2014, p. 3.
- ^ Ratto, Plá & Orgaz 2002, p. 276.
- ^ Saunders 1992, p. 170.
- ^ a b Reinhard 1992, p. 170.
- ^ Erdmann 1963, p. 18.
- ^ Kaufmann 1998, p. 54.
- ^ Echevarría 1999, p. 167.
- ^ Marek 2016, p. 88.
- ^ Carter 1957, p. 88.
- ^ Nüsser & Dame 2015, p. 72.
- ^ a b Carter 1957, p. 77.
- ^ Carter 1957, p. 74.
- ^ a b Carter 1957, p. 78.
- ^ Carter 1957b, p. 240.
- ^ Carter 1957, p. 83.
- ^ Carter 1957, p. 85.
- ^ Carter 1957, pp. 93, 96.
- ^ Marti 2014, p. 184.
- ^ Secor, Kukathas & Thomas 1999, p. 23.
- ^ a b Nüsser & Dame 2015, p. 74.
- ^ a b c Nagy et al. 2023, p. 24.
- ^ Nagy et al. 2023, p. 29.
- ^ Nagy et al. 2023, p. 32.
- ^ Nagy et al. 2023, p. 37.
- ^ Ministerio de Cultura y Turismo 2023.
- ^ Legienis 2014, p. 141.
- ^ Nüsser & Dame 2015, p. 75.
- ^ Nagy et al. 2023, pp. 27–28.
- ^ Legienis 2014, p. 142.
- ^ Nagy, László & Zsolt, p. 51.
- ^ Nagy et al. 2023, pp. 25–27.
- ^ Messerli, Grosjean & Vuille 1997, p. 236.
- ^ Subsecretaría de Turismo 2020.
- ^ Brunier 1989, pp. 366–369.
- ^ Aszalós et al. 2020, p. 752.
- ^ Acuña et al. 2024, p. 277.
- ^ Guinness World Records 2007.
- ^ a b Guinness World Records 2015.
- ^ Guinness World Records 2020.
- ^ Guinness World Records 2020b.
Sources
edit- Acuña, Valentina; Clunes, Matías; Riffo Valdebenito, Sebastián; Browning, John (May 31, 2024). "Intertwining volcanoes and society in Chile through arts and interdisciplinary connections". Andean Geology. 51 (2): 271. doi:10.5027/andgeov51n2-3676.
- Álvarez, O; Giménez, M; Folguera, A; Spagnotto, S (2014). El ridge Copiapó y su relación con la cadena volcánica ojos del salado-buena ventura, y con la zona de subducción plana pampeana. Actas del XIX Congreso Geológico Argentino (in Spanish). Vol. 20. Córdoba, Argentina – via ResearchGate.
- Alvaro, Amigo R.; Bertin, Daniel U.; Orozco, Gabriel L. (2012). Peligros volcánicos de la zona norte de Chile, regiones de Arica y Parinacota, Tarapacá, Antofagasta y Atacama, Escala 1:250.000 y 1:3.000.000 (PDF) (Report) (in Spanish). SERNAGEOMIN. Archived from the original (PDF) on June 29, 2021.
- Aszalós, Júlia Margit; Krett, Gergely; Anda, Dóra; Márialigeti, Károly; Nagy, Balázs; Borsodi, Andrea K. (September 2016). "Diversity of extremophilic bacteria in the sediment of high-altitude lakes located in the mountain desert of Ojos del Salado volcano, Dry-Andes". Extremophiles. 20 (5): 603–620. doi:10.1007/s00792-016-0849-3. ISSN 1433-4909. PMID 27315168. S2CID 16839088.
- Aszalós, Júlia Margit; Szabó, Attila; Felföldi, Tamás; Jurecska, Laura; Nagy, Balázs; Borsodi, Andrea K. (June 1, 2020). "Effects of Active Volcanism on Bacterial Communities in the Highest-Altitude Crater Lake of Ojos del Salado (Dry Andes, Altiplano-Atacama Region)". Astrobiology. 20 (6): 741–753. Bibcode:2020AsBio..20..741A. doi:10.1089/ast.2018.2011. ISSN 1531-1074. PMID 32525737. S2CID 219604666.
- Alam, Mohammad Ayaz; Muñoz, Adolfo (May 2024). "A critical evaluation of the role of a geothermal system in lithium enrichment of brines in the salt flats: A case study from Laguna Verde in the Atacama Region of Chile". Geothermics. 119: 102970. Bibcode:2024Geoth.11902970A. doi:10.1016/j.geothermics.2024.102970.
- Báez, W.; Bardelli, L.; Sampietro-Vattuone, M.M.; Peña Monné, J.L.; Bertea, E.; Cirer, M. (February 2024). "Revisiting the Holocene tephrochronology of northwestern Argentina: Insights from geochemical characterization of the tephras from the Tafí valley". Journal of South American Earth Sciences. 134: 104745. Bibcode:2024JSAES.13404745B. doi:10.1016/j.jsames.2023.104745. ISSN 1873-0647. S2CID 266392853.
- Baker, P. E.; Gonzalez-Ferrán, O.; Rex, D. C. (February 1, 1987). "Geology and geochemistry of the Ojos del Salado volcanic region, Chile". Journal of the Geological Society. 144 (1): 85–96. Bibcode:1987JGSoc.144...85B. doi:10.1144/gsjgs.144.1.0085. ISSN 0016-7649. S2CID 130046594.
- Bertin, Daniel; Baez, Walter; Caffe, Pablo; Elissondo, Manuela; Lindsay, Jan M. (2018). Active volcanoes of the Central Andes: An Argentinean perspective (Report). University of Auckland.
- Bobylyova, E. S. (December 15, 2016). "Structural-and-Semantic Analysis of Oronyms of Chile". RUDN Journal of Language Studies, Semiotics and Semantics (in Russian) (2): 123–127. ISSN 2411-1236.
- Bonatti, E.; Harrison, C. G. A.; Fisher, D. E.; Honnorez, J.; Schilling, J.-G.; Stipp, J. J.; Zentilli, M. (June 10, 1977). "Easter Volcanic Chain (southeast Pacific): A mantle hot line". Journal of Geophysical Research. 82 (17): 2457–2478. Bibcode:1977JGR....82.2457B. doi:10.1029/JB082i017p02457.
- Brunier, Serge (October 1989). "Extreme Astronomy". Sky and Telescope. 78: 366. Bibcode:1989S&T....78..366B.
- Buchroithner, M. F. (February 1–3, 2010). The glaciers of the Ojos del Salado-Tres Cruces Massifs, Atacama Andes (PDF). International Glaciological Conference VICC 2010 “Ice and Climate Change: A View from the South”. Valdivia, Chile.
- Butelski, Kazimierz (December 10, 2020). "Public Buildings of North Chile's Desert Architecture". IOP Conference Series: Materials Science and Engineering. 960 (2): 022059. Bibcode:2020MS&E..960b2059B. doi:10.1088/1757-899x/960/2/022059. S2CID 230590177.
- Carter, H. Adams (1957). Ojos del Salado (PDF) (Report). American Alpine Club.
- Carter, Adams (1957b). "The American Alpine Club Expedition to the Ojos del Salado". Geographical Review. 47 (2): 240–250. Bibcode:1957GeoRv..47..240C. doi:10.2307/211595. ISSN 0016-7428. JSTOR 211595. Retrieved March 7, 2018.
- Chen, Jing; Kufner, Sofia-Katerina; Yuan, Xiaohui; Heit, Benjamin; Wu, Hao; Yang, Dinghui; Schurr, Bernd; Kay, Suzanne (October 2020). "Lithospheric Delamination Beneath the Southern Puna Plateau Resolved by Local Earthquake Tomography". Journal of Geophysical Research: Solid Earth. 125 (10). arXiv:1912.00854. Bibcode:2020JGRB..12519040C. doi:10.1029/2019JB019040. S2CID 208527680.
- Deutscher Alpenverein (2004). Nevado Ojos del Salado (Map). 1:100000 (in German).
- Dobiński, Wojciech (September 1, 2020). "Permafrost active layer". Earth-Science Reviews. 208: 103301. Bibcode:2020ESRv..20803301D. doi:10.1016/j.earscirev.2020.103301. ISSN 0012-8252. S2CID 225304017.
- Echevarría, Evelio (1999). Chile andinista: su historia (in Spanish). El Mercurio. ISBN 978-956-288-500-3.
- Erdmann, L. Strube (1963). "La Ruta de D. Diego de Almagro a Chile: Preliminares". Revista de Historia de América (55/56): 1–26. ISSN 0034-8325. JSTOR 20138561.
- Gardeweg, M.C.; Clavero, J.; Mpodozis, C.; Pérez de A., C.; Villeneuve, M. (2000). EL MACIZO TRES CRUCES: UN COMPLEJO VOLCANICO LONGEVO Y POTENCIALMENTE ACTIVO EN LA ALTA CORDILLERA DE COPIAPO, CHILE (PDF). IX CONGRESO GEOLOGICO CHILENO (in Spanish). Puerto Varas, Chile. Archived from the original (PDF) on November 22, 2015.
- Harmon, Russell S.; Rapela, Carlos W. (1991). Andean Magmatism and Its Tectonic Setting. Geological Society of America Special Papers. Vol. 265. Geological Society of America. doi:10.1130/spe265. ISBN 978-0-8137-2265-8.
- Gimenez, Mario; Acosta, Gemma; Alvarez, Orlando; Pesce, Agustina; Lince Kinger, Federico; Folguera, Andres (November 1, 2019). "The subduction of the Copiapó aseismic ridge, is the causing of the formation of metallic minerals deposits in north of Chile and Argentina?". Geodesy and Geodynamics. 10 (6): 471–476. Bibcode:2019G&G....10..471G. doi:10.1016/j.geog.2019.04.007. hdl:11336/156053. ISSN 1674-9847. S2CID 197559051.
- "Highest altitude achieved on a motorcycle". Guinness World Records. Retrieved January 25, 2024.
- "Driving to the highest altitude by car (petrol/diesel)". Guinness World Records. Retrieved January 25, 2024.
- "Highest altitude achieved on an electric motorcycle". Guinness World Records. Retrieved January 25, 2024.
- "Highest altitude reached by a side-by-side utility task vehicle (UTV)". Guinness World Records. Retrieved January 25, 2024.
- González, Juan A.; Würschmidt, A. E. (December 7, 2008). "Contribución al conocimiento de la vegetación de alta montaña en la zona del volcán Ojos del Salado (Tinogasta, provincia de Catamarca, Argentina)". Lilloa (in Spanish): 47–60. ISSN 2346-9641.
- Gonzalez-Ferran, O.; Baker, P. E.; Rex, D. C. (March 1, 1985). "Tectonic-volcanic discontinuity at latitude 27° south Andean Range, associated with Nazca Plate Subduction". Tectonophysics. 112 (1): 423–441. Bibcode:1985Tectp.112..423G. doi:10.1016/0040-1951(85)90189-1. ISSN 0040-1951.
- Grosse, Pablo; Ochi Ramacciotti, María Luisa; Escalante Fochi, Florencia; Guzmán, Silvina; Orihashi, Yuji; Sumino, Hirochika (September 1, 2020). "Geomorphology, morphometry, spatial distribution and ages of mafic monogenetic volcanoes of the Peinado and Incahuasi fields, southernmost Central Volcanic Zone of the Andes". Journal of Volcanology and Geothermal Research. 401: 106966. Bibcode:2020JVGR..40106966G. doi:10.1016/j.jvolgeores.2020.106966. ISSN 1872-6097. S2CID 225294953.
- Grosse, Pablo; Orihashi, Yuji; Guzmán, Silvina R.; Sumino, Hirochika; Nagao, Keisuke (May 2018). "Eruptive history of Incahuasi, Falso Azufre and El Cóndor Quaternary composite volcanoes, southern Central Andes". Bulletin of Volcanology. 80 (5): 44. Bibcode:2018BVol...80...44G. doi:10.1007/s00445-018-1221-5. S2CID 134869390.
- Gspurning, Josef; Lazar, Reinhold; Sulzer, Wolfgang (2006). "Regional Climate and Snow/Glacier Distribution in Southern Upper Atacama (Ojos del Salado) – an integrated statistical, GIS and RS based approach" (PDF). Grazer Schriften der Geographie und Raumforschung. 41. University of Graz: 59–71.
- "Nevados Ojos del Salado". Global Volcanism Program. Smithsonian Institution. Retrieved October 15, 2021.
- Halloy, S. R. P. (1983). El límite superior de aridez, límite de vegetación y el problema de los lagos, nevés y glaciares activos en el" Núcleo Arido" de la Cordillera Andina. 1era Reunión Grupo Periglacial Argentino (in Spanish). Vol. 83. Mendoza: IANIGLA. pp. 91–108 – via ResearchGate.
- Halloy, S. (August 1, 1991). "Islands of Life at 6000 M Altitude: The Environment of the Highest Autotrophic Communities on Earth (Socompa Volcano, Andes)". Arctic and Alpine Research. 23 (3): 247–262. doi:10.1080/00040851.1991.12002843. ISSN 0004-0851.
- Haselton, Kirk; Hilley, George; Strecker, Manfred R. (March 1, 2002). "Average Pleistocene Climatic Patterns in the Southern Central Andes: Controls on Mountain Glaciation and Paleoclimate Implications". The Journal of Geology. 110 (2): 211–226. Bibcode:2002JG....110..211H. doi:10.1086/338414. ISSN 1537-5269. S2CID 18111576.
- Hastenrath, Stefan L. (1971). "On the Pleistocene Snow-Line Depression in the Arid Regions of the South American Andes". Journal of Glaciology. 10 (59): 255–267. Bibcode:1971JGlac..10..255H. doi:10.3189/S0022143000013228. ISSN 0022-1430. S2CID 222394688.
- "Informacíon turística" (in Spanish). Gobernacion Provincial de Copiapó. July 14, 2021. Retrieved October 23, 2021.
- "International Chronostratigraphic Chart" (PDF). International Commission on Stratigraphy. August 2018. Archived from the original (PDF) on July 31, 2018. Retrieved February 3, 2024.
- Jacobsen, Dean; Dangles, Olivier (2017). Ecology of High Altitude Waters. Oxford University Press. doi:10.1093/oso/9780198736868.001.0001. ISBN 978-0-19-873686-8.
- Jay, J. A.; Welch, M.; Pritchard, M. E.; Mares, P. J.; Mnich, M. E.; Melkonian, A. K.; Aguilera, F.; Naranjo, J. A.; Sunagua, M.; Clavero, J. (January 1, 2013). "Volcanic hotspots of the central and southern Andes as seen from space by ASTER and MODVOLC between the years 2000 and 2010". Geological Society, London, Special Publications. 380 (1): 161–185. Bibcode:2013GSLSP.380..161J. doi:10.1144/SP380.1. ISSN 0305-8719. S2CID 129450763.
- Kaufmann, Viktor (June 1998). "Topographic mapping of the volcano Nevado Ojos del Salado using optical and microwave image data". Geocarto International. 13 (2): 53–64. Bibcode:1998GeoIn..13...53K. doi:10.1080/10106049809354642. ISSN 1752-0762.
- Kay, Suzanne Mahlburg; Coira, Beatriz; Mpodozis, Constantino (January 1, 2008). "Field trip guide: Neogene evolution of the central Andean Puna plateau and southern Central Volcanic Zone". GSA Field Guide 13: Field Trip Guides to the Backbone of the Americas in the Southern and Central Andes: Ridge Collision, Shallow Subduction, and Plateau Uplift. Vol. 13. pp. 117–181. doi:10.1130/2008.0013(05). ISBN 978-0-8137-0013-7 – via ResearchGate.
- Kereszturi, Akos (September 16–21, 2018). Field work at Ojos del Salado: a new high altitude extreme Mars analogue candidate site in Atacama desert (PDF). European Planetary Science Congress 2018. Berlin, Germany: TU Berlin. Bibcode:2018EPSC...12..216K.
- Kereszturi, Ákos (June 1, 2020). "Unique and Potentially Mars-Relevant Flow Regime and Water Sources at a High Andes-Atacama Site". Astrobiology. 20 (6): 723–740. Bibcode:2020AsBio..20..723K. doi:10.1089/ast.2018.2013. ISSN 1531-1074. PMID 32525739. S2CID 219604978.
- Kereszturi, A.; Aszalos, J. M.; Zs, Heiling; Igneczi, Á.; Zs, Kapui; Cs, Kiraly; Sz, Leel-Ossy; Szalai, Z.; Zs, Nemerkenyi; Pal, B.; Skulteti, A.; Nagy, B. (May 15, 2022). "Wind-snow interactions at the Ojos del Salado region as a potential Mars analogue site in the Altiplano – Atacama desert region". Icarus. 378: 114941. Bibcode:2022Icar..37814941K. doi:10.1016/j.icarus.2022.114941. ISSN 0019-1035. S2CID 246848278.
- Legienis, Henryk (2014). "Wulkany świata atrakcją turystyki górskiej w Ameryce Północnej, Ameryce Południowej, Afryce". Zeszyty Naukowe. Turystyka I Rekreacja (in Polish). 2 (14): 137–148. ISSN 1899-7228.
- Le Roux, Jacobus P.; Achurra, Luciano; Henríquez, Álvaro; Carreño, Catalina; Rivera, Huber; Suárez, Mario E.; Ishman, Scott E.; Pyenson, Nicholas D.; Gutstein, Carolina S. (March 15, 2016). "Oroclinal bending of the Juan Fernández Ridge suggested by geohistory analysis of the Bahía Inglesa Formation, north-central Chile". Sedimentary Geology. 333: 32–49. Bibcode:2016SedG..333...32L. doi:10.1016/j.sedgeo.2015.12.003. ISSN 0037-0738.
- Lliboutry, Louis (1954). "The Origin of Penitents". Journal of Glaciology. 2 (15): 331–338. doi:10.3189/S0022143000025181. ISSN 0022-1430. S2CID 129096835.
- Lliboutry, L.; González, O.; Simken, J. (1958). "Les glaciers du désert chilien" (PDF). Extrait des Comptes Rendus et Rapports. Assemblee Generale de Toronto 4 (in French). 29. Retrieved August 18, 2024.
- Mahlburg Kay, Suzanne; Mpodozis, Constantino (April 2002). "Magmatism as a probe to the Neogene shallowing of the Nazca plate beneath the modern Chilean flat-slab". Journal of South American Earth Sciences. 15 (1): 39–57. Bibcode:2002JSAES..15...39M. doi:10.1016/S0895-9811(02)00005-6 – via ResearchGate.
- Marek, Aneta (2016). "Andy jako rejon eksploracji górskiej Polaków do 1989 r." (PDF). Słupskie Prace Geograficzne (in Polish). 13: 83–104. ISSN 1641-8468. Archived from the original (PDF) on June 16, 2023.
- Marti, Urs, ed. (2014). Gravity, Geoid and Height Systems: Proceedings of the IAG Symposium GGHS2012, October 9-12, 2012, Venice, Italy. International Association of Geodesy Symposia. Vol. 141. Springer International Publishing. Bibcode:2014gghs.book.....M. doi:10.1007/978-3-319-10837-7. ISBN 978-3-319-10836-0. S2CID 124740135.
- Messerli, Bruno; Grosjean, Martin; Graf, Kurt; Schotterer, Ueli; Schreier, Hans; Vuille, Mathias (1992). "Die Veränderungen von Klima und Umwelt in der Region Atacama (Nordchile) seit der Letzten Kaltzeit (Climate and Environmental Change in the Atacama Region (Northern Chile) since the Last Cold Maximum)". Erdkunde. 46 (3/4): 257–272. doi:10.3112/erdkunde.1992.03.09. ISSN 0014-0015. JSTOR 25646405.
- Messerli, Bruno; Grosjean, Martin; Bonani, Georges; Bürgi, Andreas; Geyh, Mebus A.; Graf, Kurt; Ramseyer, Karl; Romero, Hugo; Schotterer, Ueli; Schreier, Hans; Vuille, Mathias (1993). "Climate Change and Natural Resource Dynamics of the Atacama Altiplano during the Last 18,000 Years: A Preliminary Synthesis". Mountain Research and Development. 13 (2): 117–127. doi:10.2307/3673629. ISSN 0276-4741. JSTOR 3673629.
- Messerli, Bruno; Grosjean, Martin; Vuille, Mathias (1997). "Water Availability, Protected Areas, and Natural Resources in the Andean Desert Altiplano". Mountain Research and Development. 17 (3): 229–238. doi:10.2307/3673850. ISSN 0276-4741. JSTOR 3673850.
- Mingari, Leonardo A.; Collini, Estela A.; Folch, Arnau; Báez, Walter; Bustos, Emilce; Osores, María Soledad; Reckziegel, Florencia; Alexander, Peter; Viramonte, José G. (June 9, 2017). "Numerical simulations of windblown dust over complex terrain: the Fiambalá Basin episode in June 2015". Atmospheric Chemistry and Physics. 17 (11): 6759–6778. Bibcode:2017ACP....17.6759M. doi:10.5194/acp-17-6759-2017. ISSN 1680-7316.
- "Seismiles Fimabalá". Ministerio de Cultura y Turismo. Gobierno de Catamarca. Retrieved December 6, 2023.
- Moreno, Teresa; Gibbons, Wes, eds. (June 12, 2007). The Geology of Chile (First ed.). The Geological Society of London. doi:10.1144/goch. ISBN 978-1-86239-393-6 – via ResearchGate.
- Mpodozis, C; Kay, SM; Gardeweg, M; Coira, B (October 13–18, 1996). Geología de la región de Ojos del Salado Andes Centrales, 27°S: implicancias de la migración hacia el este del frente volcánico Cenozoico Superior. Congreso Geológico Argentino, 13. (in Spanish). Buenos Aires, Argentina. pp. 539–548 – via ResearchGate.
- Murray-Bergquist, Louisa; Garcia Pina, Ayon; Thorwart, Martin; Ulloa, Christopher; van Ginkel, Janneke; van Huisstede, Lisanne; Wessels, Richard; Beniest, Anouk (March 11, 2024). Seismic Investigation of the Ojos del Salado Volcano, Chile: The Highest Altitude Volcano in the World. EGU General Assembly 2024. doi:10.5194/egusphere-egu24-17156.
- Nagy, Balázs; Ignéczi, Ádám; Kovács, József; Szalai, Zoltán; Mari, László (January 2019). "Shallow ground temperature measurements on the highest volcano on Earth, Mt. Ojos del Salado, Arid Andes, Chile" (PDF). Permafrost and Periglacial Processes. 30 (1): 3–18. Bibcode:2019PPPr...30....3N. doi:10.1002/ppp.1989. ISSN 1099-1530. S2CID 135460843. Retrieved October 15, 2021.
- Nagy, Balázs; Mari, László; Kovács, József; Nemerkényi, Zsombor; Heiling, Zsolt (2014). Kóródi, Tibor; Sansumné Molnár, Judit; Siskáné Szilasi, Beáta; Dobos, Endre (eds.). AZ OJOS DEL SALADO MONITORING VIZSGÁLATA: JÉG-ÉS VÍZJELENLÉT A FÖLD LEGSZÁRAZABB MAGASHEGYSÉGÉBEN (PDF). VII. MAGYAR FÖLDRAJZI KONFERENCIA KIADVÁNYA (in Hungarian). Miskolc: University of Miskolc. ISBN 978-963-358-063-9. Archived from the original (PDF) on November 3, 2023. Retrieved October 23, 2021.
- Nagy, Balázs; László, Mari; Zsolt, Heiling. MAGASHEGYI KÖRNYEZETVÁLTOZÁS-MONITORING AZ OJOS DEL SALADÓN (6893 M): MÉRÉSSOROZAT–KEZDET ÉS KILÁTÁSOK (PDF) (Report) (in Hungarian). Retrieved October 24, 2021.
- Nagy, Balázs; Ignéczi, Ádám; Kovács-Székely, Ilona; Pereira, Sebastián Ruiz; Mihajlik, Gábor; Felkai, Péter; Mari, László (April 1, 2023). "The challenges of commercial mountaineering on the highest Volcanic Seven Summit, the Ojos del Salado". Hungarian Geographical Bulletin. 72 (1): 23–40. doi:10.15201/hungeobull.72.1.2. ISSN 2064-5147. Retrieved December 6, 2023.
- Naranjo, José Antonio S.; Hevia, Francisco C.; Arcos, Rodrigo R.; Polanco, Edmundo V. (2019). Geología de las áreas Nevado Ojos del Salado y Cerro El Fraile, Región de Atacama (Report) (in Spanish). SERNAGEOMIN.
- Neukirchen, Florian (2022), "Mountains and Plunging Plates: Subduction Zones", The Formation of Mountains, Cham: Springer International Publishing, pp. 207–302, doi:10.1007/978-3-031-11385-7_4, ISBN 978-3-031-11384-0, retrieved February 3, 2024
- Núñez, Lautaro; Grosjean, Martin (1994). "Cambios ambientales pleistoceno-holocénicos: Ocupación humana y uso de recursos en la Puna de Atacama (Norte de Chile)". Estudios Atacameños (11): 11–24. ISSN 0716-0925. JSTOR 25674629.
- Nüsser, Marcus; Dame, Juliane (2015). "Der Ojos del Salado in der Atacama: Forschungsgeschichte und aktuelle Probleme im trockensten Hochgebirge der Erde" (PDF). Universität Heidelberg (in German). 29. Heidelberger Geographische Gesellschaft.
- "Nevado Ojos del Salado". Oregon State University. Retrieved October 15, 2021.
- Perkins, Jonathan P.; Finnegan, Noah J.; Henderson, Scott T.; Rittenour, Tammy M. (August 1, 2016). "Topographic constraints on magma accumulation below the actively uplifting Uturuncu and Lazufre volcanic centers in the Central Andes". Geosphere. 12 (4): 1078–1096. Bibcode:2016Geosp..12.1078P. doi:10.1130/GES01278.1. ISSN 1553-040X.
- Picighelli, Cristian Sebastian (April 2023). "Energía geotérmica en la Argentina". Revista Ciencia e Tecnologia. Asociación Argentina para el Progreso de las Ciencias. ISSN 0009-6733.
- Pritchard, M. E.; Simons, M. (2004). "An InSAR-based survey of volcanic deformation in the central Andes". Geochemistry, Geophysics, Geosystems. 5 (2): n/a. Bibcode:2004GGG.....5.2002P. doi:10.1029/2003GC000610. S2CID 18453316. Archived from the original on July 8, 2023. Retrieved October 30, 2021.
- Ratto, Norma; Plá, Rita; Orgaz, Martín (2002). "Producción y distribución de bienes cerámicos durante la ocupación inca entre la región puneña de Chaschuil y el valle de Abaucán (Dpto. Tinogasta, Catamarca)". Relaciones de la Sociedad Argentina de Antropología (in Spanish). tomo 27.
- Reinhard, Johan (1992). "An archaeological investigation of Inca ceremonial platforms on the Volcano Copiapo, Central Chile". In Saunders, N. (ed.). Ancient America: Contribution to New World archaeology. Oxford: Oxbow Books. pp. 145–172. ISBN 9780946897483 – via Academia.edu.
- Roig, Fidel Antonio (1955). "Contribución al conocimiento de la zona del Ojos del Salado: (Catamarca)". Boletín de Estudios Geográficos (in Spanish). 9: 319–336. ISSN 0374-6186. Retrieved October 16, 2021.
- Rubiolo, Daniel; Pereyra, Fernando Xavier; Martínez, Liliana del Valle; Seggiaro, Raúl E.; Hongn, Fernando D.; Fernández Seveso, Fernando; Velasco, María S.; Sruoga, Patricia; Prieri, Ana; González Díaz, Emilio F. (2003). Hoja Geológica 2769- IV Fiambalá (Report). Programa Nacional de Cartas Geológicas de la República Argentina 1:250.000 (in Spanish). Servicio Geológico Minero Argentino. Instituto de Geología y Recursos Minerales. ISSN 0328-2333. Archived from the original (pdf) on October 30, 2021.
- Rundel, Philip W.; Kleier, Catherine C. (2014). "Parque Nacional Nevado de Tres Cruces, Chile: A Significant Coldspot of Biodiversity in a High Andean Ecosystem" (PDF). fs.fed.us. Retrieved October 22, 2021.
- Saunders, Nicholas J. (1992). Ancient America: Contributions to New World Archaeology. Oxbow Books. ISBN 978-0-946897-48-3.
- Secor, R. J.; Kukathas, Uma; Thomas, Crystal (1999). Aconcagua: A Climbing Guide. The Mountaineers Books. ISBN 978-0-89886-669-8.
- Seimon, Anton; Halloy, Stephan R. P.; Seimon, Tracie A. (May 2007). "Recent Observation of a Proliferation of Ranunculus trichophyllus Chaix. in High-altitude Lakes of the Mount Everest Region: Comment". Arctic, Antarctic, and Alpine Research. 39 (2): 340���341. doi:10.1657/1523-0430(2007)39[340:ROOAPO]2.0.CO;2. ISSN 1938-4246. S2CID 130181788.
- "Ranking de los Volcanes Según impacto de peligrosidad" (PDF). SERNAGEOMIN (in Spanish). 2019. Retrieved October 24, 2021.
- Seynova, I.B.; Chernomorets, S.S.; Dokukin, M.D.; Petrakov, D.A.; Savernyuk, E.A.; Lukashov, A.A.; Belousova, E.A. (2017). "Formation of water flow in lahars from active glacier-clad volcanoes". "Earth's Cryosphere". XXI (6): 103–111. doi:10.21782/EC1560-7496-2017-6(103-111). ISSN 1560-7496 – via ResearchGate.
- Siebert, Lee; Simkin, Tom; Kimberly, Paul (December 31, 2019), "Data Criteria and Context", Volcanoes of the World, University of California Press, pp. 1–46, doi:10.1525/9780520947931-002, ISBN 978-0-520-94793-1, S2CID 226546635, retrieved October 22, 2021
- Storz, Jay F.; Quiroga-Carmona, Marcial; Liphardt, Schuyler; Herrera, Nathanael D.; Bautista, Naim M.; Opazo, Juan C.; Rico-Cernohorska, Adriana; Salazar-Bravo, Jorge; Good, Jeffrey M.; D’Elía, Guillermo (June 1, 2024). "Extreme High-Elevation Mammal Surveys Reveal Unexpectedly High Upper Range Limits of Andean Mice". The American Naturalist. 203 (6): 726–735. Bibcode:2024ANat..203..726S. doi:10.1086/729513. PMID 38781524.
- Ficha de Solicitud Declaración Zona de Interés Turístico (ZOIT) "Salar de Maricunga Ojos del Salado" (PDF) (Report) (in Spanish). Subsecretaría de Turismo. September 2019.
- "ZOIT Salar de Maricunga Ojos del Salado" (in Spanish). Subsecretaría de Turismo. February 13, 2020. Retrieved October 23, 2021.
- Veress, Márton (2016). Covered Karsts. Springer Geology. Springer Netherlands. Bibcode:2016coka.book.....V. doi:10.1007/978-94-017-7518-2. ISBN 978-94-017-7516-8. S2CID 199492881.
- Vincent, Warwick F. (January 25, 2018). Lakes: A Very Short Introduction. Very Short Introductions. Oxford University Press. ISBN 978-0-19-876673-5.
- Williams, Richard S.; Ferrigno, Jane G. (1988). Satellite image atlas of glaciers of the world: Professional Paper 1386 (Report). U.S. Geological Survey. doi:10.3133/pp1386.
Bibliography
edit- Biggar, John (2005). The Andes: A Guide for Climbers. Andes. ISBN 978-0-9536087-2-0.
- Radehose, Eckehard (2002). Traumberge Amerikas: von Alaska bis Feuerland (in German). Bergverlag Rother GmbH. ISBN 978-3-7633-3006-5.
External links
edit- Fleischer, K. (2004). Erstellung der Alpenvereinskarte "Nevado Ojos del Salado" (Thesis) (in German).
- Complete description of Ojos del Salado in Andeshandbook
- December 1, 2006, Star Trails at 19,000 Feet – NASA Astronomy Picture of the Day
- Andes information
- Ojos del Salado Satellite Elevation Data
- Peak bagger
- Summit post
- Peak list
- Virtual Aerial Video Archived May 5, 2019, at the Wayback Machine
- Guided Peaks