Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)

Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)

To avoid the improper disqualification of a watershed for which the water–rock interaction (WRI) may produce trace element concentrations exceeding established guidelines, it is of the utmost importance to properly establish natural geochemical backgrounds. Using the example of the crystalline Upper...

Full description

Bibliographic Details
Main Authors: Nathalie Gassama, Florence Curie, Pierre Vanhooydonck, Xavier Bourrain, David Widory
Format: Article
Language:English
Published: MDPI AG 2021-07-01
Series:Water
Subjects:
trace metals and metalloids
stream waters
dissolved concentration
geochemical background
monolithologic watersheds
Online Access:https://www.mdpi.com/2073-4441/13/13/1845
id doaj-997a7529b87c478cb1db1e43e7742baf
record_format Article
spelling doaj-997a7529b87c478cb1db1e43e7742baf2021-07-15T15:48:36ZengMDPI AGWater2073-44412021-07-01131845184510.3390/w13131845Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)Nathalie Gassama0Florence Curie1Pierre Vanhooydonck2Xavier Bourrain3David Widory4Faculty of Sciences, University of Tours, E.A. 6392 GéoHydorsystèmes Continentaux, Parc de Grandmont, 37200 Tours, FranceFaculty of Sciences, University of Tours, E.A. 6392 GéoHydorsystèmes Continentaux, Parc de Grandmont, 37200 Tours, FranceFaculty of Sciences, University of Tours, E.A. 6392 GéoHydorsystèmes Continentaux, Parc de Grandmont, 37200 Tours, FranceAgence de l’Eau Loire-Bretagne, CS 36339, CEDEX 2, 45063 Orléans, FranceGEOTOP, Earth and Atmosphere Sciences Department, UQAM, Montréal, QC H3C 3P8, CanadaTo avoid the improper disqualification of a watershed for which the water–rock interaction (WRI) may produce trace element concentrations exceeding established guidelines, it is of the utmost importance to properly establish natural geochemical backgrounds. Using the example of the crystalline Upper Loire River Basin, we are proposing a methodology based on the selection and chemical characterization of water and sediment samples from 10 monolithologic watersheds supposedly lowly impacted by anthropogenic inputs. We collected water samples from each watershed’s spring down to its outlet and measured dissolved major, minor and selected trace elements (Al, As, Ba, Cd, Co, Cr, Cs, Cu, La, Ni, Pb, U, V and Zn) at low- and high-water stages. Results show that the chemical signature of the stream waters is controlled by mineral weatherability rather than by the available rock stock. As a result, the variability in dissolved metal concentrations between the principal lithologies is similar to that observed within each of them. While some elements mostly result from WRI, others clearly identify high inputs from topsoil leaching. Comparison with published data evidences the need to subdivide studied watersheds into distinct sectors, according to the distance from the spring, in order to define reliable natural backgrounds.https://www.mdpi.com/2073-4441/13/13/1845trace metals and metalloidsstream watersdissolved concentrationgeochemical backgroundmonolithologic watersheds
collection DOAJ
language English
format Article
sources DOAJ
author Nathalie Gassama
Florence Curie
Pierre Vanhooydonck
Xavier Bourrain
David Widory
spellingShingle Nathalie Gassama
Florence Curie
Pierre Vanhooydonck
Xavier Bourrain
David Widory
Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
Water
trace metals and metalloids
stream waters
dissolved concentration
geochemical background
monolithologic watersheds
author_facet Nathalie Gassama
Florence Curie
Pierre Vanhooydonck
Xavier Bourrain
David Widory
author_sort Nathalie Gassama
title Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
title_short Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
title_full Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
title_fullStr Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
title_full_unstemmed Determining the Regional Geochemical Background for Dissolved Trace Metals and Metalloids in Stream Waters: Protocol, Results and Limitations—The Upper Loire River Basin (France)
title_sort determining the regional geochemical background for dissolved trace metals and metalloids in stream waters: protocol, results and limitations—the upper loire river basin (france)
publisher MDPI AG
series Water
issn 2073-4441
publishDate 2021-07-01
description To avoid the improper disqualification of a watershed for which the water–rock interaction (WRI) may produce trace element concentrations exceeding established guidelines, it is of the utmost importance to properly establish natural geochemical backgrounds. Using the example of the crystalline Upper Loire River Basin, we are proposing a methodology based on the selection and chemical characterization of water and sediment samples from 10 monolithologic watersheds supposedly lowly impacted by anthropogenic inputs. We collected water samples from each watershed’s spring down to its outlet and measured dissolved major, minor and selected trace elements (Al, As, Ba, Cd, Co, Cr, Cs, Cu, La, Ni, Pb, U, V and Zn) at low- and high-water stages. Results show that the chemical signature of the stream waters is controlled by mineral weatherability rather than by the available rock stock. As a result, the variability in dissolved metal concentrations between the principal lithologies is similar to that observed within each of them. While some elements mostly result from WRI, others clearly identify high inputs from topsoil leaching. Comparison with published data evidences the need to subdivide studied watersheds into distinct sectors, according to the distance from the spring, in order to define reliable natural backgrounds.
topic trace metals and metalloids
stream waters
dissolved concentration
geochemical background
monolithologic watersheds
url https://www.mdpi.com/2073-4441/13/13/1845
work_keys_str_mv AT nathaliegassama determiningtheregionalgeochemicalbackgroundfordissolvedtracemetalsandmetalloidsinstreamwatersprotocolresultsandlimitationstheupperloireriverbasinfrance
AT florencecurie determiningtheregionalgeochemicalbackgroundfordissolvedtracemetalsandmetalloidsinstreamwatersprotocolresultsandlimitationstheupperloireriverbasinfrance
AT pierrevanhooydonck determiningtheregionalgeochemicalbackgroundfordissolvedtracemetalsandmetalloidsinstreamwatersprotocolresultsandlimitationstheupperloireriverbasinfrance
AT xavierbourrain determiningtheregionalgeochemicalbackgroundfordissolvedtracemetalsandmetalloidsinstreamwatersprotocolresultsandlimitationstheupperloireriverbasinfrance
AT davidwidory determiningtheregionalgeochemicalbackgroundfordissolvedtracemetalsandmetalloidsinstreamwatersprotocolresultsandlimitationstheupperloireriverbasinfrance
_version_ 1721298207121604608

Similar Items