Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change

Intensifying permafrost thaw alters carbon cycling by mobilizing large amounts of terrestrial substrate into aquatic ecosystems. Yet, few studies have measured aquatic carbon fluxes and constrained drivers of ecosystem carbon balance across heterogeneous Arctic landscapes. Here, we characterized hyd...

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Main Authors: Zolkos, Scott, Tank, Suzanne E., Kokelj, Steven V., Striegl, Robert G., Shakil, Sarah, Voigt, Carolina, Sonnentag, Oliver, Quinton, William L., Schuur, Edward A. G., Zona, Donatella, Lafleur, Peter M., Sullivan, Ryan C., Ueyama, Masahito, Billesbach, David P., Cook, David, Humphreys, Elyn R., Marsh, Philip
Format: Text
Language:unknown
Published: DigitalCommons@University of Nebraska - Lincoln 2022
Subjects:
Bioresource and Agricultural Engineering
Civil and Environmental Engineering
Engineering
Environmental Engineering
Other Civil and Environmental Engineering
Arctic
Ice
permafrost
Thermokarst
Online Access:https://digitalcommons.unl.edu/biosysengfacpub/813
https://digitalcommons.unl.edu/context/biosysengfacpub/article/1822/viewcontent/Zolkos_GBC_2022_Permafrost_Landscape_History.pdf
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spelling ftunivnebraskali:oai:digitalcommons.unl.edu:biosysengfacpub-1822 2023-11-12T04:12:47+01:00 Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change Zolkos, Scott Tank, Suzanne E. Kokelj, Steven V. Striegl, Robert G. Shakil, Sarah Voigt, Carolina Sonnentag, Oliver Quinton, William L. Schuur, Edward A. G. Zona, Donatella Lafleur, Peter M. Sullivan, Ryan C. Ueyama, Masahito Billesbach, David P. Cook, David Humphreys, Elyn R. Marsh, Philip 2022-08-16T07:00:00Z application/pdf https://digitalcommons.unl.edu/biosysengfacpub/813 https://digitalcommons.unl.edu/context/biosysengfacpub/article/1822/viewcontent/Zolkos_GBC_2022_Permafrost_Landscape_History.pdf unknown DigitalCommons@University of Nebraska - Lincoln https://digitalcommons.unl.edu/biosysengfacpub/813 https://digitalcommons.unl.edu/context/biosysengfacpub/article/1822/viewcontent/Zolkos_GBC_2022_Permafrost_Landscape_History.pdf Biological Systems Engineering: Papers and Publications Bioresource and Agricultural Engineering Civil and Environmental Engineering Engineering Environmental Engineering Other Civil and Environmental Engineering text 2022 ftunivnebraskali 2023-10-30T12:10:20Z Intensifying permafrost thaw alters carbon cycling by mobilizing large amounts of terrestrial substrate into aquatic ecosystems. Yet, few studies have measured aquatic carbon fluxes and constrained drivers of ecosystem carbon balance across heterogeneous Arctic landscapes. Here, we characterized hydrochemical and landscape controls on fluvial carbon cycling, quantified fluvial carbon fluxes, and estimated fluvial contributions to ecosystem carbon balance across 33 watersheds in four ecoregions in the continuous permafrost zone of the western Canadian Arctic: unglaciated uplands, ice-rich moraine, and organic-rich lowlands and till plains. Major ions, stable isotopes, and carbon speciation and fluxes revealed patterns in carbon cycling across ecoregions defined by terrain relief and accumulation of organics. In previously unglaciated mountainous watersheds, bicarbonate dominated carbon export (70% of total) due to chemical weathering of bedrock. In lowland watersheds, where soil organic carbon stores were largest, lateral transport of dissolved organic carbon (50%) and efflux of biotic CO2 (25%) dominated. In watersheds affected by thaw-induced mass wasting, erosion of ice-rich tills enhanced chemical weathering and increased particulate carbon fluxes by two orders of magnitude. From an ecosystem carbon balance perspective, fluvial carbon export in watersheds not affected by thaw-induced wasting was, on average, equivalent to 6%–16% of estimated net ecosystem exchange (NEE). In watersheds affected by thaw-induced wasting, fluvial carbon export approached 60% of NEE. Because future intensification of thermokarst activity will amplify fluvial carbon export, determining the fate of carbon across diverse northern landscapes is a priority for constraining trajectories of permafrost region ecosystem carbon balance. Text Arctic Ice permafrost Thermokarst University of Nebraska-Lincoln: DigitalCommons@UNL Arctic
institution Open Polar
collection University of Nebraska-Lincoln: DigitalCommons@UNL
op_collection_id ftunivnebraskali
language unknown
topic Bioresource and Agricultural Engineering
Civil and Environmental Engineering
Engineering
Environmental Engineering
Other Civil and Environmental Engineering
spellingShingle Bioresource and Agricultural Engineering
Civil and Environmental Engineering
Engineering
Environmental Engineering
Other Civil and Environmental Engineering
Zolkos, Scott
Tank, Suzanne E.
Kokelj, Steven V.
Striegl, Robert G.
Shakil, Sarah
Voigt, Carolina
Sonnentag, Oliver
Quinton, William L.
Schuur, Edward A. G.
Zona, Donatella
Lafleur, Peter M.
Sullivan, Ryan C.
Ueyama, Masahito
Billesbach, David P.
Cook, David
Humphreys, Elyn R.
Marsh, Philip
Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
topic_facet Bioresource and Agricultural Engineering
Civil and Environmental Engineering
Engineering
Environmental Engineering
Other Civil and Environmental Engineering
description Intensifying permafrost thaw alters carbon cycling by mobilizing large amounts of terrestrial substrate into aquatic ecosystems. Yet, few studies have measured aquatic carbon fluxes and constrained drivers of ecosystem carbon balance across heterogeneous Arctic landscapes. Here, we characterized hydrochemical and landscape controls on fluvial carbon cycling, quantified fluvial carbon fluxes, and estimated fluvial contributions to ecosystem carbon balance across 33 watersheds in four ecoregions in the continuous permafrost zone of the western Canadian Arctic: unglaciated uplands, ice-rich moraine, and organic-rich lowlands and till plains. Major ions, stable isotopes, and carbon speciation and fluxes revealed patterns in carbon cycling across ecoregions defined by terrain relief and accumulation of organics. In previously unglaciated mountainous watersheds, bicarbonate dominated carbon export (70% of total) due to chemical weathering of bedrock. In lowland watersheds, where soil organic carbon stores were largest, lateral transport of dissolved organic carbon (50%) and efflux of biotic CO2 (25%) dominated. In watersheds affected by thaw-induced mass wasting, erosion of ice-rich tills enhanced chemical weathering and increased particulate carbon fluxes by two orders of magnitude. From an ecosystem carbon balance perspective, fluvial carbon export in watersheds not affected by thaw-induced wasting was, on average, equivalent to 6%–16% of estimated net ecosystem exchange (NEE). In watersheds affected by thaw-induced wasting, fluvial carbon export approached 60% of NEE. Because future intensification of thermokarst activity will amplify fluvial carbon export, determining the fate of carbon across diverse northern landscapes is a priority for constraining trajectories of permafrost region ecosystem carbon balance.
format Text
author Zolkos, Scott
Tank, Suzanne E.
Kokelj, Steven V.
Striegl, Robert G.
Shakil, Sarah
Voigt, Carolina
Sonnentag, Oliver
Quinton, William L.
Schuur, Edward A. G.
Zona, Donatella
Lafleur, Peter M.
Sullivan, Ryan C.
Ueyama, Masahito
Billesbach, David P.
Cook, David
Humphreys, Elyn R.
Marsh, Philip
author_facet Zolkos, Scott
Tank, Suzanne E.
Kokelj, Steven V.
Striegl, Robert G.
Shakil, Sarah
Voigt, Carolina
Sonnentag, Oliver
Quinton, William L.
Schuur, Edward A. G.
Zona, Donatella
Lafleur, Peter M.
Sullivan, Ryan C.
Ueyama, Masahito
Billesbach, David P.
Cook, David
Humphreys, Elyn R.
Marsh, Philip
author_sort Zolkos, Scott
title Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
title_short Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
title_full Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
title_fullStr Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
title_full_unstemmed Permafrost Landscape History Shapes Fluvial Chemistry, Ecosystem Carbon Balance, and Potential Trajectories of Future Change
title_sort permafrost landscape history shapes fluvial chemistry, ecosystem carbon balance, and potential trajectories of future change
publisher DigitalCommons@University of Nebraska - Lincoln
publishDate 2022
url https://digitalcommons.unl.edu/biosysengfacpub/813
https://digitalcommons.unl.edu/context/biosysengfacpub/article/1822/viewcontent/Zolkos_GBC_2022_Permafrost_Landscape_History.pdf
geographic Arctic
geographic_facet Arctic
genre Arctic
Ice
permafrost
Thermokarst
genre_facet Arctic
Ice
permafrost
Thermokarst
op_source Biological Systems Engineering: Papers and Publications
op_relation https://digitalcommons.unl.edu/biosysengfacpub/813
https://digitalcommons.unl.edu/context/biosysengfacpub/article/1822/viewcontent/Zolkos_GBC_2022_Permafrost_Landscape_History.pdf
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