Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia

Boreal mire landscapes are rich in soil carbon and significantly contribute to the carbon input of aquatic ecosystems. They are composed of different mesoscale ecohydrological subunits, whose individual contributions to the water and carbon export of mire catchments are not well understood. The spri...

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Published in:	Hydrological Processes
Main Authors:	Avagyan, Armine, Runkle, Benjamin R. K., Hennings, Nina, Haupt, Hannes, Virtanen, Tarmo, Kutzbach, Lars
Format:	Text
Language:	unknown
Published:	ScholarWorks@UARK 2015
Subjects:	Ecohydrological zones snowmelt period heterogeneous forest-mire boreal Russia Atmospheric Sciences Fresh Water Studies Hydrology Terrestrial and Aquatic Ecology Northwest Russia
Online Access:	https://scholarworks.uark.edu/baegpub/12 https://doi.org/10.1002/hyp.10710

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spelling	ftunivarkansas:oai:scholarworks.uark.edu:baegpub-1011 2023-11-12T04:23:29+01:00 Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia Avagyan, Armine Runkle, Benjamin R. K. Hennings, Nina Haupt, Hannes Virtanen, Tarmo Kutzbach, Lars 2015-10-12T07:00:00Z https://scholarworks.uark.edu/baegpub/12 https://doi.org/10.1002/hyp.10710 unknown ScholarWorks@UARK https://scholarworks.uark.edu/baegpub/12 doi:10.1002/hyp.10710 Biological and Agricultural Engineering Faculty Publications and Presentations Ecohydrological zones snowmelt period heterogeneous forest-mire boreal Russia Atmospheric Sciences Fresh Water Studies Hydrology Terrestrial and Aquatic Ecology text 2015 ftunivarkansas https://doi.org/10.1002/hyp.10710 2023-10-30T09:47:16Z Boreal mire landscapes are rich in soil carbon and significantly contribute to the carbon input of aquatic ecosystems. They are composed of different mesoscale ecohydrological subunits, whose individual contributions to the water and carbon export of mire catchments are not well understood. The spring snowmelt period is the major hydrological event in the annual water cycle of the boreal regions and strongly influences the carbon flux between the terrestrial and aquatic systems. The aim of this study was (1) to provide a conceptual understanding of the spatial and temporal dynamics of the surface water chemistry along a swamp forest‐fen‐bog gradient during the snowmelt period, (2) to quantify the exported dissolved organic carbon (DOC) content in the runoff and (3) to identify the ecohydrological landscape unit that contributes most to DOC export during the snowmelt period in a heterogeneous mire complex in Northwest Russia. The highest DOC concentrations were detected in the swamp forest, and the lowest concentrations were observed at the treeless bog by the end of the snowmelt period (swamp forest: 37–43 mg l−1, bog: 13–17 mg l−1). During the spring snowmelt period, a significant amount (~1.7 g C m−2) of DOC was transferred by the ~74 mm of runoff from the catchment into the river. Variability in the thawing periods led to differences in the relative contributions of each ecohydrological zone to the carbon export measured at a stream channel draining the studied part of the mire complex. An increased understanding of the variation in DOC concentrations and contributions from the mesoscale ecohydrological subunits to carbon export can help to predict the potential regional loss of DOC based on land cover type under climate change. Text Northwest Russia University of Arkansas: ScholarWorks@UARK Hydrological Processes 30 11 1727 1741
institution	Open Polar
collection	University of Arkansas: ScholarWorks@UARK
op_collection_id	ftunivarkansas
language	unknown
topic	Ecohydrological zones snowmelt period heterogeneous forest-mire boreal Russia Atmospheric Sciences Fresh Water Studies Hydrology Terrestrial and Aquatic Ecology
spellingShingle	Ecohydrological zones snowmelt period heterogeneous forest-mire boreal Russia Atmospheric Sciences Fresh Water Studies Hydrology Terrestrial and Aquatic Ecology Avagyan, Armine Runkle, Benjamin R. K. Hennings, Nina Haupt, Hannes Virtanen, Tarmo Kutzbach, Lars Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
topic_facet	Ecohydrological zones snowmelt period heterogeneous forest-mire boreal Russia Atmospheric Sciences Fresh Water Studies Hydrology Terrestrial and Aquatic Ecology
description	Boreal mire landscapes are rich in soil carbon and significantly contribute to the carbon input of aquatic ecosystems. They are composed of different mesoscale ecohydrological subunits, whose individual contributions to the water and carbon export of mire catchments are not well understood. The spring snowmelt period is the major hydrological event in the annual water cycle of the boreal regions and strongly influences the carbon flux between the terrestrial and aquatic systems. The aim of this study was (1) to provide a conceptual understanding of the spatial and temporal dynamics of the surface water chemistry along a swamp forest‐fen‐bog gradient during the snowmelt period, (2) to quantify the exported dissolved organic carbon (DOC) content in the runoff and (3) to identify the ecohydrological landscape unit that contributes most to DOC export during the snowmelt period in a heterogeneous mire complex in Northwest Russia. The highest DOC concentrations were detected in the swamp forest, and the lowest concentrations were observed at the treeless bog by the end of the snowmelt period (swamp forest: 37–43 mg l−1, bog: 13–17 mg l−1). During the spring snowmelt period, a significant amount (~1.7 g C m−2) of DOC was transferred by the ~74 mm of runoff from the catchment into the river. Variability in the thawing periods led to differences in the relative contributions of each ecohydrological zone to the carbon export measured at a stream channel draining the studied part of the mire complex. An increased understanding of the variation in DOC concentrations and contributions from the mesoscale ecohydrological subunits to carbon export can help to predict the potential regional loss of DOC based on land cover type under climate change.
format	Text
author	Avagyan, Armine Runkle, Benjamin R. K. Hennings, Nina Haupt, Hannes Virtanen, Tarmo Kutzbach, Lars
author_facet	Avagyan, Armine Runkle, Benjamin R. K. Hennings, Nina Haupt, Hannes Virtanen, Tarmo Kutzbach, Lars
author_sort	Avagyan, Armine
title	Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
title_short	Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
title_full	Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
title_fullStr	Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
title_full_unstemmed	Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia
title_sort	dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in northwest russia
publisher	ScholarWorks@UARK
publishDate	2015
url	https://scholarworks.uark.edu/baegpub/12 https://doi.org/10.1002/hyp.10710
genre	Northwest Russia
genre_facet	Northwest Russia
op_source	Biological and Agricultural Engineering Faculty Publications and Presentations
op_relation	https://scholarworks.uark.edu/baegpub/12 doi:10.1002/hyp.10710
op_doi	https://doi.org/10.1002/hyp.10710
container_title	Hydrological Processes
container_volume	30
container_issue	11
container_start_page	1727
op_container_end_page	1741
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Dissolved organic matter dynamics during the spring snowmelt at a boreal river valley mire complex in Northwest Russia

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