| PEP-I: The Argentinian Altiplano | |
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Project: Dinámica cultural y ambiental - Uso del espacio por sociedades del pasado en la Puna meridional (Chaschuil, Tinogasta, Catamarca) Argentina Period: 1995- 1997 Funding: Universidad Nacional de Catamarca, Argentina; Consejo Superior de Investigaciones Científicas, CSIC, España Principal Investigators: Norma Ratto (U.N. Catamarca) & limnogeologia Valero-Garcés (IPE) Sites: Laguna El Peinado and San Francisco Basin
El Peinado Lake (26° 29' 59" S, 68° 05 ' 32" W, 3820 m a.s.l.) lies on an N-S elongated, topographically-closed basin, north of El Peinado volcano and at the southern end of the Salar de Antofalla. Waters are saline (Electric conductivity: 55,500 µS/cm) and alkaline (pH= 7.6), and dominated by sulfate-chloride-carbonate anions, and calcium and sodium cations. The San Francisco Basin can be subdivided into two sub-basins. In the northern subbasin, a hummocky topography of small hills and shallow depressions forms a landscape dotted with shallow, small playa lakes; two of these small playa lakes were cored (26° 55' 42" S; 68° 07' 21" W, 3980 m a.s.l.). The southern sub-basin contains a larger playa lake (26° 57' 47" S, 68° 10' 16" W, 4000 m a.s.l.), named Las Coladas Salar. Las Coladas waters are saline (E.C. = 41,900 µS/cm), alkaline (pH=8.5), Ca - poor (73 ppm versus 2653 ppm in El Peinado), with lower Boron (47 ppm) and Strontium (1 ppm) values and much higher Mg/Ca ratio than El Peinado (11 versus 0.25).
Publications Valero-Garcés, B.L., Delgado-Huertas, A., Navas, A. & Ratto, N., 1999. Large 13C enrichment in primary carbonates from Andean Altiplano lakes, Northwest Argentina. Earth and Planetary Science Letters, 171, 236-266. ABSTRACT. We report here extreme 13C enrichments up to + 13 ‰ PDB in primary calcite and aragonite precipitates in saline, well oxygenated waters from high altitude lakes in the southern Andean Altiplano, northwestern Argentina. Biological effects, as well as variations in carbon source inputs, and in the exchange rate with atmospheric CO2, are commonly considered the main controls on the carbon isotope values of authigenic lacustrine carbonate. We present sedimentological and geochemical evidence that favor physical processes - evaporation effects and CO2- degassing - as major controls on 13C enrichment. We propose that large enrichments may result from the non-equilibrium gas - transfer isotope fractionation during CO2-degassing from thermal springs and evaporation effects in arid environments. The dilution effect by large quantities of 14C - free CO2 hinders accurate 14C chronology of these lake records based on lacustrine organic matter and aquatic plants. Our results indicate that geothermal and volcanic CO2 sources in lake basins located in volcanic settings, and physical fractionation may have a greater significance than commonly accepted to explain lacustrine carbon isotope records. Figure. Isotopic composition of carbonates and organic matter in Andean lakes Valero-Garcés, B.L., Delgado-Huertas, A., Navas, y Ratto, N., 2000. Paleohydrological evolution of Andean saline lakes from sedimentological and isotopic records, northwestern Argentina. Journal of Paleolimnology. (in press). ABSTRACT. The paleohydrological evolution of several high altitude, saline lakes located in the southernmost Altiplano (El Peinado and San Francisco basins, Catamarca province, NW Argentina) was reconstructed applying sedimentological, geochemical and isotopic techniques. Several playa lakes from the San Francisco basin (26° 56' S; 68° 08' W, 3800-3900 m a.s.l.) show evidence of a recent raise in the watertable that led to modern deposition of carbonate and diatomaceous muds. A 2 m - long core from El Peinado Lake (26° 29' 59" S, 68° 05 ' 32" W, 3820 m a.s.l.) consists of calcitic crusts (unit 3), overlaid by an alternation of macrophyte-rich and travertine clast- rich, laminated muds (unit 2), and topped by travertine facies (unit 1). This sedimentary sequence illustrates a paleohydrological evolution from a subaerial exposure (unit 3) to a high lake stand (unit 2), and a subsequent smaller decrease in lake level (unit 1). The d 13Corganic matter record also reflects the lake transgression between units 3 and 2. Although there is a general positive correlation between d18Ocarbonate and salinity proxies (Na, Li and B content), the large data dispersion indicates that other factors besides evaporation effects control chemical and isotopic composition of lakewater. Consequently, the oxygen isotopic composition cannot be interpreted exclusively as an indicator of salinity or evaporation ratio. The degassing of CO2 during groundwater discharge can explain the enriched d 13C values for primary carbonates precipitated. The carbon budget in these high altitude, saline lakes seems to be controlled by physical rather than biological processes.The Altiplano saline lakes contain records of environmental and climatic change, although accurate 14C dating of these lacustrine sediments is hindered by the scarcity of terrestrial organic material, and the large reservoir effects. Sedimentologic evidence, a 210Pb-based chronology, and a preliminary U/Th chronology indicate a very large reservoir effect in El Peinado, likely as a result of old groundwaters and large contributions of volcanic and geothermal 14C-free CO2 to the lake system. Alternative chronologies are needed to place these paleorecords in a reliable chronological framework. A period of increased water balance in the San Francisco basin ended at about 1660 ± 82 yr B.P. (calendar year U/Th age), and would correlates with the humid phase between 3000 and 1800 yr B.P detected in other sites of the southern Altiplano. Both, 210Pb and preliminary U/Th dating favor a younger age for the paleohydrological changes in El Peinado. The arid period reflected by subaerial exposure and low lake levels in unit 3 would have ended with a large increase in effective moisture during the late 17th century. The increased lake level during deposition of unit 2 would represent the period between AD1650- 1900, synchronous to the Little Ice Age. This chronological framework is coherent with other regional records that show an abrupt transition from more arid to more humid conditions in the early 17th century, and a change to modern conditions in the late 19th century. Although there are local differences, the Little Ice Age stands as a significant climatic event in the Andean Altiplano. Figure. The El Peinado Record.
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