First snow, glacier and groundwater contribution quantification in the upper Mendoza River basin using stable water isotopes

“…In the Mendoza River basin (Central Andes, Argentina), Crespo et al, found clear differences in ionic and stable isotope chemistry between the main mountain ranges of the catchment basin related to different precipitation systems (Pacific and Atlantic moisture) and geological settings [32]. In another study in the same catchment basin, Crespo et al [20] showed that glacial input accounted for 50%, periglacial 15%, groundwater 18% and snowmelt 17% of the total contribution [20]. In that study, Crespo et al [20] highlighted that more than 83% of water input originates from "not-snow" water source in dry periods in the Mendoza River basin and pointed out the importance of quantifying the water source contribution from a large diversity of sources.…”

“…In another study in the same catchment basin, Crespo et al [20] showed that glacial input accounted for 50%, periglacial 15%, groundwater 18% and snowmelt 17% of the total contribution [20]. In that study, Crespo et al [20] highlighted that more than 83% of water input originates from "not-snow" water source in dry periods in the Mendoza River basin and pointed out the importance of quantifying the water source contribution from a large diversity of sources.…”

“…This extraordinary event occurred in the hottest decade of the last 100 years and would seem to have no analogy in the last millennium, according to precipitation and streamflow reconstructions in the area [6,7]. Long-term climate projections also do The socio-economic development and subsistence of the region is strongly linked to the meltwater from the Andes, which also includes the buffering effect of glaciers in dry periods [19,20]. However, this information has not been estimated in this basin yet for other water sources than snowmelt.…”

“…As was proposed by Peña and Nazarala [22] for the whole Central Andes, this cryoforms contribute to approximately 67% of the total summer flow. The glacial melt streamflow buffer effect limits the drought, so droughts in the Central Andes do not reach more critical situations [19,20].…”

“…Differences in glacio-genesis features and melting conditions provide distinct air and sediment contact times of each water source and thus different chemical characteristics in terms of ionic and stable isotope water composition [20,32]. This specific chemical composition could allow the identification of every water source and the quantification of their input contribution for each season.…”

Where Does the Chilean Aconcagua River Come from? Use of Natural Tracers for Water Genesis Characterization in Glacial and Periglacial Environments

“…In the Mendoza River basin (Central Andes, Argentina), Crespo et al, found clear differences in ionic and stable isotope chemistry between the main mountain ranges of the catchment basin related to different precipitation systems (Pacific and Atlantic moisture) and geological settings [32]. In another study in the same catchment basin, Crespo et al [20] showed that glacial input accounted for 50%, periglacial 15%, groundwater 18% and snowmelt 17% of the total contribution [20]. In that study, Crespo et al [20] highlighted that more than 83% of water input originates from "not-snow" water source in dry periods in the Mendoza River basin and pointed out the importance of quantifying the water source contribution from a large diversity of sources.…”

“…In another study in the same catchment basin, Crespo et al [20] showed that glacial input accounted for 50%, periglacial 15%, groundwater 18% and snowmelt 17% of the total contribution [20]. In that study, Crespo et al [20] highlighted that more than 83% of water input originates from "not-snow" water source in dry periods in the Mendoza River basin and pointed out the importance of quantifying the water source contribution from a large diversity of sources.…”

“…This extraordinary event occurred in the hottest decade of the last 100 years and would seem to have no analogy in the last millennium, according to precipitation and streamflow reconstructions in the area [6,7]. Long-term climate projections also do The socio-economic development and subsistence of the region is strongly linked to the meltwater from the Andes, which also includes the buffering effect of glaciers in dry periods [19,20]. However, this information has not been estimated in this basin yet for other water sources than snowmelt.…”

“…As was proposed by Peña and Nazarala [22] for the whole Central Andes, this cryoforms contribute to approximately 67% of the total summer flow. The glacial melt streamflow buffer effect limits the drought, so droughts in the Central Andes do not reach more critical situations [19,20].…”

“…Differences in glacio-genesis features and melting conditions provide distinct air and sediment contact times of each water source and thus different chemical characteristics in terms of ionic and stable isotope water composition [20,32]. This specific chemical composition could allow the identification of every water source and the quantification of their input contribution for each season.…”

Where Does the Chilean Aconcagua River Come from? Use of Natural Tracers for Water Genesis Characterization in Glacial and Periglacial Environments

Isotopic signature of a glacial influenced hydrological system in northern Patagonia, Argentina

Review: Hydrogeology of Northern Mendoza (Argentina), from the Andes to the eastern plains, in the context of climate change