Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment

Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment

Abstract Climate change affects the occurrence of high‐discharge (HD) events and associated nutrient exports in catchment stream water. Information on colloidal events‐based losses of important nutrients, such as organic C(Corg), N, P, and S, remain relatively scarce. We hypothesized that contributi...

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Main Authors: Dymphie J. Burger, Johnny Vogel, Annemieke M. Kooijman, Roland Bol, Eva de Rijke, Jorien Schoorl, Andreas Lücke, Nina Gottselig
Format: Article
Language:English
Published: Wiley 2021-05-01
Series:Vadose Zone Journal
Online Access:https://doi.org/10.1002/vzj2.20126
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spelling doaj-f77faa0599c84ad882b08294e50ab6bd2021-06-08T17:12:20ZengWileyVadose Zone Journal1539-16632021-05-01203n/an/a10.1002/vzj2.20126Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchmentDymphie J. Burger0Johnny Vogel1Annemieke M. Kooijman2Roland Bol3Eva de Rijke4Jorien Schoorl5Andreas Lücke6Nina Gottselig7Institute of Crop Science and Resource Conservation, Soil Science and Soil Ecology Univ. of Bonn Nussallee 13 Bonn 53115 GermanyForschungszentrum Jülich Institute of Bio‐ and Geosciences IBG‐3: Agrosphere, Wilhelm Johnen Str Jülich 52425 GermanyInstitute for Biodiversity and Ecosystem Dynamics Univ. of Amsterdam Science Park 904 GE Amsterdam 1090 The NetherlandsForschungszentrum Jülich Institute of Bio‐ and Geosciences IBG‐3: Agrosphere, Wilhelm Johnen Str Jülich 52425 GermanyInstitute for Biodiversity and Ecosystem Dynamics Univ. of Amsterdam Science Park 904 GE Amsterdam 1090 The NetherlandsInstitute for Biodiversity and Ecosystem Dynamics Univ. of Amsterdam Science Park 904 GE Amsterdam 1090 The NetherlandsForschungszentrum Jülich Institute of Bio‐ and Geosciences IBG‐3: Agrosphere, Wilhelm Johnen Str Jülich 52425 GermanyInstitute of Crop Science and Resource Conservation, Soil Science and Soil Ecology Univ. of Bonn Nussallee 13 Bonn 53115 GermanyAbstract Climate change affects the occurrence of high‐discharge (HD) events and associated nutrient exports in catchment stream water. Information on colloidal events‐based losses of important nutrients, such as organic C(Corg), N, P, and S, remain relatively scarce. We hypothesized that contributions of colloidal exported N, S, and P due to differing hydrological mechanisms vary between HD events in late winter and spring. We examined one combined snowmelt and rainfall event (March 2018) with one rainfall event (May 2018) for temporal Corg, N, P, and S dynamics. The catchment exports of colloids and their subset nanoparticles were analyzed by asymmetric‐flow field flow fractionation (P) and a filtration cascade (N and S). The Corg source in both events was assessed by δ13C composition of the stream water in relation to that of the soil. In winter, <6% of stream water P was transported by colloids (>0.1 μm), but this was 29–64% in spring and was associated with Corg, Fe, and Al. Colloidal N and particulate S (>1 μm) were higher during both events, but the majority of losses were dissolved (<0.1 μm). The δ13C values of dissolved organic matter (13CDOM) showed that in winter, most Corg was exported from the hydrologically connected hillslopes by water flowing through mineral horizons, due to snowmelt. During and after the rainfall events, export from organic horizons dominated the nutrient losses as particulates, including colloids. These events highlight the need for a better quantification of often underreported particulate, colloid, and nanoparticle contributions to weather‐driven nutrient losses from catchments.https://doi.org/10.1002/vzj2.20126
collection DOAJ
language English
format Article
sources DOAJ
author Dymphie J. Burger
Johnny Vogel
Annemieke M. Kooijman
Roland Bol
Eva de Rijke
Jorien Schoorl
Andreas Lücke
Nina Gottselig
spellingShingle Dymphie J. Burger
Johnny Vogel
Annemieke M. Kooijman
Roland Bol
Eva de Rijke
Jorien Schoorl
Andreas Lücke
Nina Gottselig
Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
Vadose Zone Journal
author_facet Dymphie J. Burger
Johnny Vogel
Annemieke M. Kooijman
Roland Bol
Eva de Rijke
Jorien Schoorl
Andreas Lücke
Nina Gottselig
author_sort Dymphie J. Burger
title Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
title_short Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
title_full Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
title_fullStr Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
title_full_unstemmed Colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
title_sort colloidal catchment response to snowmelt and precipitation events differs in a forested headwater catchment
publisher Wiley
series Vadose Zone Journal
issn 1539-1663
publishDate 2021-05-01
description Abstract Climate change affects the occurrence of high‐discharge (HD) events and associated nutrient exports in catchment stream water. Information on colloidal events‐based losses of important nutrients, such as organic C(Corg), N, P, and S, remain relatively scarce. We hypothesized that contributions of colloidal exported N, S, and P due to differing hydrological mechanisms vary between HD events in late winter and spring. We examined one combined snowmelt and rainfall event (March 2018) with one rainfall event (May 2018) for temporal Corg, N, P, and S dynamics. The catchment exports of colloids and their subset nanoparticles were analyzed by asymmetric‐flow field flow fractionation (P) and a filtration cascade (N and S). The Corg source in both events was assessed by δ13C composition of the stream water in relation to that of the soil. In winter, <6% of stream water P was transported by colloids (>0.1 μm), but this was 29–64% in spring and was associated with Corg, Fe, and Al. Colloidal N and particulate S (>1 μm) were higher during both events, but the majority of losses were dissolved (<0.1 μm). The δ13C values of dissolved organic matter (13CDOM) showed that in winter, most Corg was exported from the hydrologically connected hillslopes by water flowing through mineral horizons, due to snowmelt. During and after the rainfall events, export from organic horizons dominated the nutrient losses as particulates, including colloids. These events highlight the need for a better quantification of often underreported particulate, colloid, and nanoparticle contributions to weather‐driven nutrient losses from catchments.
url https://doi.org/10.1002/vzj2.20126
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