Factors controlling the water quality of rock glacier springs in European and American mountain ranges.

Rock glaciers (RGs) provide significant water resources in mountain areas under climate change. Recent research has highlighted high concentrations of solutes including trace elements in RG-fed waters, with negative implications on water quality. Yet, sparse studies from a few locations hinder concl...

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Bibliographic Details
Published in:Science of The Total Environment
Main Authors: Brighenti, Stefano, Colombo, Nicola, Wagner, Thomas, Pettauer, Michael, Guyennon, Nicolas, Krainer, Karl, Tolotti, Monica, Rogora, Michela, Paro, Luca, Steingruber, Sandra M, Del Siro, Chantal, Scapozza, Cristian, Sileo, Noelia R, Villarroel, Cristian D, Hayashi, Masaki, Munroe, Jeffrey, Liaudat, Dario Trombotto, Cerasino, Leonardo, Tirler, Werner, Comiti, Francesco, Freppaz, Michele, Salerno, Franco, Litaor, M Iggy, Cremonese, Edoardo, di Cella, Umberto Morra, Winkler, Gerfried
Format: Article in Journal/Newspaper
Language:English
Published: Elsevier Science 2024
Subjects:
Climate change
Hydrochemistry
Icy seeps
Mountain springs
Permafrost hydrology
Trace elements
Ice
permafrost
Online Access:https://doi.org/10.1016/j.scitotenv.2024.175706
https://pubmed.ncbi.nlm.nih.gov/39197760
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Summary:Rock glaciers (RGs) provide significant water resources in mountain areas under climate change. Recent research has highlighted high concentrations of solutes including trace elements in RG-fed waters, with negative implications on water quality. Yet, sparse studies from a few locations hinder conclusions about the main drivers of solute export from RGs. Here, in an unprecedented effort, we collected published and unpublished data on rock glacier hydrochemistry around the globe. We considered 201 RG springs from mountain ranges across Europe, North and South America, using a combination of machine learning, multivariate and univariate analyses, and geochemical modeling. We found that 35 % of springs issuing from intact RGs (containing internal ice) have water quality below drinking water standards, compared to 5 % of springs connected to relict RGs (without internal ice). The interaction of ice and bedrock lithology is responsible for solute concentrations in RG springs. Indeed, we found higher concentrations of sulfate and trace elements in springs sourcing from intact RGs compared to water originating from relict RGs, mostly in specific lithological settings. Enhanced sulfide oxidation in intact RGs is responsible for the elevated trace element concentrations. Challenges for water management may arise in mountain catchments rich in intact RGs, and where the predisposing geology would make these areas geochemical RG hotspots. Our work represents a first comprehensive attempt to identify the main drivers of solute concentrations in RG waters.

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