Climate Change Increasing Calcium and Magnesium Leaching from Granitic Alpine

Climate Change Increasing Calcium and Magnesium Leaching from Granitic Alpine

Climate change can reverse trends of decreasing calcium and magnesium [Ca + Mg] leaching to surface waters in granitic alpine regions recovering from acidification. Despite decreasing concentrations of strong acid anions (-1.4 μeq L^sup -1^ yr^sup -1^) during 2004-2016 in nonacidic alpine lakes in t...

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Bibliographic Details
Published in:Environmental science & technology Vol. 51; no. 1; p. 159
Main Authors: Kopácek, Jirí, Kana, Jirí, Bicárová, Svetlana, Fernandez, Ivan J, Hejzlar, Josef, Kahounová, Marie, Norton, Stephen A, Stuchlík, Evzen
Format: Journal Article
Language:English
Published: Easton American Chemical Society 03-01-2017
Subjects:
Acidification
Climate change
Leaching
Precipitation
Soil erosion
Surface water
Watersheds
Central Europe
Tatra Mountains
Poland, Tatra Mts
ANE, Europe
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Summary:Climate change can reverse trends of decreasing calcium and magnesium [Ca + Mg] leaching to surface waters in granitic alpine regions recovering from acidification. Despite decreasing concentrations of strong acid anions (-1.4 μeq L^sup -1^ yr^sup -1^) during 2004-2016 in nonacidic alpine lakes in the Tatra Mountains (Central Europe), the average [Ca + Mg] concentrations increased (2.5 μeq L^sup -1^ yr^sup -1^), together with elevated terrestrial export of bicarbonate (HCO^sub 3^-; 3.6 μeq L^sup -1^ yr^sup -1^). The percent increase in [Ca + Mg] concentrations in nonacidic lakes (0.3-3.2% yr^sup -1^) was significantly and positively correlated with scree proportion in the catchment area and negatively correlated with the extent of soil cover. Leaching experiments with freshly crushed granodiorite, the dominant bedrock, showed that accessory calcite and (to a lesser extent) apatite were important sources of Ca. We hypothesize that elevated terrestrial export of [Ca + Mg] and HCO^sub 3^- resulted from increased weathering caused by accelerated physical erosion of rocks due to elevated climate-related mechanical forces (an increasing frequency of days with high precipitation amounts and air temperatures fluctuating around 0 °C) during the last 2-3 decades. These climatic effects on water chemistry are especially strong in catchments where fragmented rocks are more exposed to weathering, and their position is less stable than in soil.
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ISSN:0013-936X