Laguna Lejía is a salt lake located in the Altiplano of the Antofagasta Region of northern Chile. The landscape of the area is dominated by the volcanoes Chiliques, Lascar, Aguas Calientes and Acamarachi. It is shallow and has no outlet, covering a surface area of about 1.9 square kilometres (0.73 sq mi) in the present-day.
Laguna Lejía | |
---|---|
Location | Antofagasta Region |
Coordinates | 23°30′00″S 67°41′33″W / 23.50000°S 67.69250°W |
Catchment area | 193 km2 (75 sq mi)[1] |
Basin countries | Chile |
Surface area | 1.9 km2 (0.73 sq mi)[1] |
Surface elevation | 4,325 m (14,190 ft)[1] |
References | [2][1] |
During glacial times, the lake was considerably larger owing to decreased evaporation and increased precipitation rates, with bioherms developing around the waterbody. Presently, flamingos and a number of microorganisms live in the lake.
Geography and geology
editLejía Lake lies in the Puna de Atacama[3] of Chile, close to the border with Argentina.[4] The city of San Pedro de Atacama lies 103 kilometres (64 mi) northwest of Lejía Lake.[5] The lake basin is surrounded by volcanoes, such as Aguas Calientes, Lascar, Tumisa, Lejía, Chiliques and Cordon de Puntas Negras,[5] and smaller centres like Cerro Overo and La Albòndiga.[6] The lake is endorheic and has a 193 square kilometres (75 sq mi) large catchment,[5] and a lava flow forms its southern shore.[7] Farther south lie two other lakes, Laguna Miscanti and Laguna Miniques.[8]
Hydrology
editLejía Lake is a circular,[8] shallow lake[5] at an elevation of 4,325 metres (14,190 ft)[1] with a surface area of 1.9 square kilometres (0.73 sq mi)[5][1] or 2 square kilometres (0.77 sq mi). It is a polymictic lake which freezes over occasionally[9] and whose waters are turned over quickly,[10] mainly through evaporation.[11] Winds sometimes create foam on the lake surface and blow them onto the shores.[12] Water temperatures have been measured to range between 3–10.6 °C (37.4–51.1 °F), and the lake is about 1.2 metres (3 ft 11 in) deep.[13]
The waters of the lake are oligohaline[14] and salinity is often different in one part of the lake from the rest.[15] Sulfate and sodium are the principal salts in the lake water, with chloride and magnesium secondary and calcium, potassium, silica and strontium subordinate.[11]
The lake is nourished from the north through two creeks, one originates on Aguas Calientes and the other from two tributaries on Lascar and Cerro del Abra. From Chiliques and Lejia in the south other creeks run north and enter the southern part of the lake.[8] A groundwater outlet appears to exist, considering that there is no halite accumulating in the lake,[16] and Cerro Overo is a maar that formed through groundwater-magma interaction.[17]
Lake history
editThe lake lies in a tectonic depression, which is geologically related to the fault system Miscanti-Callejón de Varela;[5] once it was thought that the lake was in a caldera.[12] The Altos de Toro Blanco mountains separate Lejía Lake's drainage basin from the Salar de Aguas Calientes catchment.[5] A lineament known as the Tumisa line runs along the southern shore of the lake,[7] and appears to have been the site of three earthquakes in post-glacial time.[18] The lake is influenced by volcanic activity from the neighbouring Lascar; ash and pyroclastic material entered Lejía Lake in 1993,[19] and the large Soncor eruption from this volcano 26,450 years before present filled the lake.[20]
During glacial times, the lake was considerably larger, reaching a surface area of 10 square kilometres (3.9 sq mi)[9] with water levels rising to about 25 metres (82 ft) above present-day level; the lake was filled with freshwater at that time.[21] A volcanic marker dated to 16,700 ± 2,000 years before present pre-dates the lake highstand;[22] this volcanic marker is a tephra erupted by the Cerro Corona lava dome south of Lascar.[23] Lake levels stayed high until the Holocene and then decreased; the timing of Holocene changes is unknown.[21] These earlier larger lakes have left terraces around Lejía Lake which contain bioherms and stromatolith leftovers.[19] Even older deposits associated with the Lake Minchin wet period are not present at Lejía Lake unlike other Altiplanic lakes, probably owing to volcanic activity that disrupted the sediments.[20] Weathered sediments at Laguna Lejía have been used as analogues for sediments left by ancient lakes on Mars.[24]
The increase in surface area was a consequence of increased precipitation and increased cloud cover which decreased its evaporation rate.[10] Sediment cores have shown evidence of separate lake stages with water levels mostly higher than today;[11] higher moisture levels owing to a displacement of the tropical circulation during the Lake Tauca stage have been invoked to explain higher lake levels in Lejía and other regional waterbodies.[25] Glaciers developed in the region as well but did not reach the lake. [26]
Climate
editPrecipitation around the lake is about 200 millimetres per year (7.9 in/year) mostly during the summer months, considerably less than the annual evaporation rate. Temperatures range −6–7 °C (21–45 °F) with an average temperature of 2 °C (36 °F);[9] night temperatures can drop to −18 – −25 °C (0 – −13 °F).[27] There is strong daily and interannual variability of the weather.[28] During glacial highstands, precipitation was about double that of today.[29]
Biology
editLejía Lake is colonized by diatoms, including Amphora coffeaeformis, Cyclotella michiganiana, Cyclotella stelligera, Cymbella pusilla, Navicula halophila, and Navicula radiosa.[21] Algal[12] and bacterial mats also occur in the lake.[30]
Ostracods in the lake include Limnocythere species. The occurrence of their shells in lake sediments has been used to reconstruct the history of the lake, including its salinity.[21] Crustaceans are also found, such as Alona species, Diacyclops andinus, Harpacticoida species, and Macrothrix palearis.[31] Finally, chironomid flies have been encountered at Lejía Lake.[32]
Flamingos, phalaropes[33] and their parasites exist at the lake.[34] High altitude Andean lakes such as Lejía Lake are studied as potential analogues to waterbodies on Mars, given similarities between their present-day environment and the environments of early Mars.[35]
Shoreline vegetation consists of Calandrinia, Deyeuxia, Puccinellia and Stipa species, which occur close to waterbodies and springs.[28] Grass and shrub vegetation of the Puna occurs in the lake basin at elevations of less than 4,500 metres (14,800 ft); at higher elevation bunch grass, cushion plants and rosette plants form a distinct and sparse vegetation.[26] Humans have pastures at the lake.[36]
Archeology
editArcheological artifacts from the archaic period have been found on an upper terrace of the lake,[21] indicating that ancient hunters did head to Lejía Lake at that time.[37]
References
edit- ^ a b c d e f (in Spanish) IRD en Chile: Laguna Lejía Archived 27 November 2006 at the Wayback Machine
- ^ Earth Info, earth-info.nga.mil webpage: "GNS: Country Files". Archived from the original on 4 May 2012. Retrieved 6 April 2007.
- ^ Grosjean 1994, p. 89.
- ^ Grosjean 1994, p. 90.
- ^ a b c d e f g De los Ríos, Muñoz-Pedreros & Möller 2013, p. 1636.
- ^ Ureta et al. 2021, p. 2.
- ^ a b Matthews & Vita-Finzi 1993, p. 115.
- ^ a b c Niemeyer, Hans F. "HOYAS HIDROGRÁFICAS DE CHILE: SEGUNDA REGIÓN" (PDF) (in Spanish). Dirección General de Aguas. p. 196. Archived from the original (PDF) on 4 March 2016. Retrieved 3 February 2018.
- ^ a b c Grosjean 1994, p. 92.
- ^ a b Grosjean 1994, p. 94.
- ^ a b c Grosjean 1994, p. 95.
- ^ a b c Simoneit, Bernd R. T.; Halpern, H. I.; Didyk, B. M. (1980). "Lipid Productivity of a High Andean Lake". Biogeochemistry of Ancient and Modern Environments. p. 201. doi:10.1007/978-3-662-26582-6_21. ISBN 978-0-85847-062-0.
- ^ Cabrol et al. 2009, p. 3.
- ^ Muñoz-Pedreros, Andrés; de Los Ríos, Patricio; Möller, Patricia (2013). "Zooplankton de Laguna Lejía, un humedal desértico de la alta puna del norte de Chile" (PDF). Biblioteca digital CEDOC-CIREN (in Spanish). Retrieved 3 February 2018.
- ^ De los Ríos, Muñoz-Pedreros & Möller 2013, p. 1640.
- ^ Munk, Lee Ann; Boutt, David F.; Hynek, Scott A.; Moran, Brendan J. (August 2018). "Hydrogeochemical fluxes and processes contributing to the formation of lithium-enriched brines in a hyper-arid continental basin". Chemical Geology. 493: 50. Bibcode:2018ChGeo.493...37M. doi:10.1016/j.chemgeo.2018.05.013. ISSN 0009-2541. S2CID 134531576.
- ^ Ureta et al. 2021, p. 18.
- ^ Matthews & Vita-Finzi 1993, p. 116.
- ^ a b Cabrol et al. 2009, p. 4.
- ^ a b Gardeweg, Sparks & Matthews 1998, p. 100.
- ^ a b c d e Grosjean 1994, p. 97.
- ^ Grosjean 1994, p. 96.
- ^ Gardeweg, Sparks & Matthews 1998, p. 92.
- ^ Bishop, Janice L.; Vega, María Ángeles Lezcano; Parro, Victor; Cabrol, Nathalie A.; Sánchez-García, Laura; Rhodes, Kimberly Warren; Hinman, Nancy W. (28 June 2021). VNIR Spectral Analyses of Paleolake sediments at Lejía in the Altiplano region of Chile. European Planetary Science Congress 2021. doi:10.5194/epsc2021-453.
- ^ Grosjean 1994, p. 95,96.
- ^ a b Graf, Kurt (1994). "Discussion of palynological methods and paleoclimatical interpretations in northern Chile and the whole Andes" (PDF). Revista Chilena de Historia Natural (67): 405–415. Archived (PDF) from the original on 4 February 2018. Retrieved 3 February 2018.
- ^ Cabrol et al. 2009, p. 7.
- ^ a b De los Ríos, Muñoz-Pedreros & Möller 2013, p. 1637.
- ^ Moran, Brendan J.; Boutt, David F.; Munk, Lee Ann (2019). "Stable and Radioisotope Systematics Reveal Fossil Water as Fundamental Characteristic of Arid Orogenic-Scale Groundwater Systems". Water Resources Research. 55 (12): 11298. Bibcode:2019WRR....5511295M. doi:10.1029/2019WR026386. ISSN 1944-7973. S2CID 212895806.
- ^ Cabrol et al. 2009, p. 10.
- ^ De los Ríos, Muñoz-Pedreros & Möller 2013, p. 1639.
- ^ Cabrol et al. 2009, p. 16.
- ^ Hurlbert, Stuart H.; Lopez, Matilde; Keith, James O. (1984). "Wilson's Phalarope in the Central Andes and its Interaction with the Chilean Flamingo" (PDF). Revista Chilena de Historia Natural. 57: 53. Archived (PDF) from the original on 4 February 2018. Retrieved 3 February 2018.
- ^ Redón, Stella; Vasileva, Gergana P.; Georgiev, Boyko B.; Gajardo, Gonzalo (1 October 2020). "Exploring parasites in extreme environments of high conservational importance: Artemia franciscana (Crustacea: Branchiopoda) as intermediate host of avian cestodes in Andean hypersaline lagoons from Salar de Atacama, Chile". Parasitology Research. 119 (10): 3377–3390. doi:10.1007/s00436-020-06768-3. ISSN 1432-1955. PMID 32638100. S2CID 220397989.
- ^ Cabrol et al. 2009, p. 2.
- ^ Morales, Héctor; Garcés, Alejandro; González, Luis; Dibona, Gisella; Vilches, Juan Carlos; Azócar, Rodrigo; Morales, Héctor; Garcés, Alejandro; González, Luis; Dibona, Gisella; Vilches, Juan Carlos; Azócar, Rodrigo (June 2019). "Del viaje familiar hasta los grandotes: Mercancías, comunidad y frontera en la Puna Atacameña del Siglo XX". Diálogo Andino (59): 21–35. doi:10.4067/S0719-26812019000200021. ISSN 0719-2681.
- ^ Grosjean 1994, p. 99.
Sources
edit- Cabrol, Nathalie A.; Grin, Edmond A.; Chong, Guillermo; Minkley, Edwin; Hock, Andrew N.; Yu, Youngseob; Bebout, Leslie; Fleming, Erich; Häder, Donat P.; Demergasso, Cecilia; Gibson, John; Escudero, Lorena; Dorador, Cristina; Lim, Darlene; Woosley, Clayton; Morris, Robert L.; Tambley, Cristian; Gaete, Victor; Galvez, Matthieu E.; Smith, Eric; Uskin-Peate, Ingrid; Salazar, Carlos; Dawidowicz, G.; Majerowicz, J. (1 June 2009). "The High-Lakes Project". Journal of Geophysical Research: Biogeosciences. 114 (G2): G00D06. Bibcode:2009JGRG..114.0D06C. doi:10.1029/2008JG000818. ISSN 2156-2202.
- De los Ríos, Patricio; Muñoz-Pedreros, Andrés; Möller, Patricia (1 January 2013). "Zooplankton in Laguna Lejía, a high-altitude Andean shallow lake of the Puna in northern Chile" (PDF). Crustaceana. 86 (13–14): 1634–1643. doi:10.1163/15685403-00003265. ISSN 1568-5403. Retrieved 3 February 2018 – via Centro de Estudios Agrarios y Ambientales.
- Gardeweg, M. C.; Sparks, R. S. J.; Matthews, S. J. (1 February 1998). "Evolution of Lascar Volcano, Northern Chile". Journal of the Geological Society. 155 (1): 89–104. Bibcode:1998JGSoc.155...89G. doi:10.1144/gsjgs.155.1.0089. ISSN 0016-7649. S2CID 128916568.
- Grosjean, Martin (May 1994). "Paleohydrology of the Laguna Lejía (north Chilean Altiplano) and climatic implications for late-glacial times". Palaeogeography, Palaeoclimatology, Palaeoecology. 109 (1): 89–100. Bibcode:1994PPP...109...89G. doi:10.1016/0031-0182(94)90119-8. ISSN 0031-0182.
- Matthews, Steve; Vita-Finzi, Claudio (September 1993). "Neotectonics at Laguna Lejia, Atacama desert, Northern Chile" (PDF). Horizon documentation-IRD. pp. 115–116. Retrieved 3 February 2018.
- Ureta, Gabriel; Németh, Károly; Aguilera, Felipe; Zimmer, Martin; Menzies, Andrew (4 March 2021). "A window on mantle-derived magmas within the Central Andes: eruption style transitions at Cerro Overo maar and La Albóndiga lava dome, northern Chile". Bulletin of Volcanology. 83 (4): 19. Bibcode:2021BVol...83...19U. doi:10.1007/s00445-021-01446-3. ISSN 1432-0819. S2CID 232108256.