Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon

This poster was presented at the 2018 ArcticNet Scientific Meeting, in Ottawa, ON, held from Dec 10th to 14th, 2018.http://www.arcticnetmeetings.ca/asm2018/index.php Reference: Roy-Levillee P, Burn CR. (2018) Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, n...

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Main Authors: Roy-Léveillée, Pascale, Burn, Chris
Format: Still Image
Language:unknown
Published: figshare 2018
Subjects:
59999 Environmental Sciences not elsewhere classified
FOS Earth and related environmental sciences
Environmental Science
40699 Physical Geography and Environmental Geoscience not elsewhere classified
49999 Earth Sciences not elsewhere classified
40601 Geomorphology and Regolith and Landscape Evolution
50101 Ecological Impacts of Climate Change
50304 Soil Chemistry excl. Carbon Sequestration Science
FOS Agriculture, forestry and fisheries
Arctic
Yukon
Talik
Old Crow Flats
ArcticNet
Climate change
Old Crow
permafrost
Thermokarst
Tundra
Online Access:https://dx.doi.org/10.6084/m9.figshare.7476098.v1
https://figshare.com/articles/Thermokarst_lake_expansion_and_carbon_mobilization_in_polygonal_tundra_of_Old_Crow_Flats_northern_Yukon/7476098/1
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record_format openpolar
institution Open Polar
collection DataCite Metadata Store (German National Library of Science and Technology)
op_collection_id ftdatacite
language unknown
topic 59999 Environmental Sciences not elsewhere classified
FOS Earth and related environmental sciences
Environmental Science
40699 Physical Geography and Environmental Geoscience not elsewhere classified
49999 Earth Sciences not elsewhere classified
40601 Geomorphology and Regolith and Landscape Evolution
50101 Ecological Impacts of Climate Change
50304 Soil Chemistry excl. Carbon Sequestration Science
FOS Agriculture, forestry and fisheries
spellingShingle 59999 Environmental Sciences not elsewhere classified
FOS Earth and related environmental sciences
Environmental Science
40699 Physical Geography and Environmental Geoscience not elsewhere classified
49999 Earth Sciences not elsewhere classified
40601 Geomorphology and Regolith and Landscape Evolution
50101 Ecological Impacts of Climate Change
50304 Soil Chemistry excl. Carbon Sequestration Science
FOS Agriculture, forestry and fisheries
Roy-Léveillée, Pascale
Burn, Chris
Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
topic_facet 59999 Environmental Sciences not elsewhere classified
FOS Earth and related environmental sciences
Environmental Science
40699 Physical Geography and Environmental Geoscience not elsewhere classified
49999 Earth Sciences not elsewhere classified
40601 Geomorphology and Regolith and Landscape Evolution
50101 Ecological Impacts of Climate Change
50304 Soil Chemistry excl. Carbon Sequestration Science
FOS Agriculture, forestry and fisheries
description This poster was presented at the 2018 ArcticNet Scientific Meeting, in Ottawa, ON, held from Dec 10th to 14th, 2018.http://www.arcticnetmeetings.ca/asm2018/index.php Reference: Roy-Levillee P, Burn CR. (2018) Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon. In ArcticNet Scientific Meeting 2018, Ottawa, ON, December 10th to 14th 2018 . doi: 10.6084/m9.figshare.7476098 Abstract: The expansion and drainage of thermokarst lakes respond to climatic trends and are an important part of the permafrost carbon feedback. The effects of climate on total lake area in thermokarst lowlands vary from region to region and may be monitored via remote-sensing, but it is difficult to interpret changes in lake area in terms of volumes of permafrost thawed and organic carbon released from permafrost. This is because the rates of subaerial and sublacustrine permafrost degradation associated with lake expansion, as well as the distribution of organics in the sediment profile, vary across Arctic lowlands due differences in environmental conditions. This research links changes in lake area with tridimensional estimates of permafrost degradation, and assesses associated changes in permafrost carbon storage at the landscape scale. The study area was a zone of polygonal tundra within Old Crow Flats (OCF), YT, a 5600 km 2 Arctic peatland located in an inland basin separated from the Arctic Coast by mountains. The research objectives are: 1) to use remotely sensed imagery to assess rates of lake expansion and characterize the relation between lake size and shore erosion rates in the study area; 2) to use modelling in combination with ground temperature measurements and observations of talik geometry to estimate volumetric rates of permafrost degradation beneath expanding lakes; 3) to use field measurements of shore bank height and samples of permafrost to estimate organic carbon content where permafrost degradation is imminent. Results indicate that, between 1951 and 2011, lake expansion encroached on the surrounding tundra at an average rate of 0.27 km 2 a -1 . The total lake expansion during this period is approximately equal to the total lake area lost to catastrophic drainages in the 1060 km 2 study area. Permafrost thaw occurred beneath the areas that became part of the lakes, and this loss of permafrost was compensated by the aggradation of permafrost in drained basins. However, lake expansion occurred via the erosion of organic-rich permafrost banks varying in height between 0.5 and 4 m, representing an additional loss of permafrost. Due to bank erosion alone, approximately 430 000 m 3 a -1 of sediment fell in the lakes of the study area annually. This represents an input of organic carbon into the lakes of 0.22 Tg C a -1 , of which 0.15 Tg C a -1 was stored in permafrost prior to being thawed during bank erosion. Comparatively, a doubling of active layer depth over the entire study area in the next 20 years would lead to the thawing of 0.01 Tg C a -1 of organic carbon previously stored in permafrost, less than one tenth of what would be released via bank erosion if current erosion rates are sustained. While current climate models with carbon budgets focus on active layer deepening as the main mechanism of permafrost degradation associated with carbon mobilisation, these research results highlight the importance of considering thermokarst lake expansion as a tridimensional process when quantifying the permafrost carbon feedback in Arctic lowlands.
format Still Image
author Roy-Léveillée, Pascale
Burn, Chris
author_facet Roy-Léveillée, Pascale
Burn, Chris
author_sort Roy-Léveillée, Pascale
title Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
title_short Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
title_full Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
title_fullStr Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
title_full_unstemmed Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon
title_sort thermokarst lake expansion and carbon mobilization in polygonal tundra of old crow flats, northern yukon
publisher figshare
publishDate 2018
url https://dx.doi.org/10.6084/m9.figshare.7476098.v1
https://figshare.com/articles/Thermokarst_lake_expansion_and_carbon_mobilization_in_polygonal_tundra_of_Old_Crow_Flats_northern_Yukon/7476098/1
long_lat ENVELOPE(146.601,146.601,59.667,59.667)
ENVELOPE(-139.755,-139.755,68.083,68.083)
geographic Arctic
Yukon
Talik
Old Crow Flats
geographic_facet Arctic
Yukon
Talik
Old Crow Flats
genre Arctic
ArcticNet
Climate change
Old Crow
permafrost
Talik
Thermokarst
Tundra
Yukon
genre_facet Arctic
ArcticNet
Climate change
Old Crow
permafrost
Talik
Thermokarst
Tundra
Yukon
op_relation https://dx.doi.org/10.6084/m9.figshare.7476098
op_rights Creative Commons Attribution 4.0 International
https://creativecommons.org/licenses/by/4.0/legalcode
cc-by-4.0
op_rightsnorm CC-BY
op_doi https://doi.org/10.6084/m9.figshare.7476098.v1
https://doi.org/10.6084/m9.figshare.7476098
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spelling ftdatacite:10.6084/m9.figshare.7476098.v1 2023-05-15T15:01:02+02:00 Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon Roy-Léveillée, Pascale Burn, Chris 2018 https://dx.doi.org/10.6084/m9.figshare.7476098.v1 https://figshare.com/articles/Thermokarst_lake_expansion_and_carbon_mobilization_in_polygonal_tundra_of_Old_Crow_Flats_northern_Yukon/7476098/1 unknown figshare https://dx.doi.org/10.6084/m9.figshare.7476098 Creative Commons Attribution 4.0 International https://creativecommons.org/licenses/by/4.0/legalcode cc-by-4.0 CC-BY 59999 Environmental Sciences not elsewhere classified FOS Earth and related environmental sciences Environmental Science 40699 Physical Geography and Environmental Geoscience not elsewhere classified 49999 Earth Sciences not elsewhere classified 40601 Geomorphology and Regolith and Landscape Evolution 50101 Ecological Impacts of Climate Change 50304 Soil Chemistry excl. Carbon Sequestration Science FOS Agriculture, forestry and fisheries Image graphic Poster ImageObject 2018 ftdatacite https://doi.org/10.6084/m9.figshare.7476098.v1 https://doi.org/10.6084/m9.figshare.7476098 2021-11-05T12:55:41Z This poster was presented at the 2018 ArcticNet Scientific Meeting, in Ottawa, ON, held from Dec 10th to 14th, 2018.http://www.arcticnetmeetings.ca/asm2018/index.php Reference: Roy-Levillee P, Burn CR. (2018) Thermokarst lake expansion and carbon mobilization in polygonal tundra of Old Crow Flats, northern Yukon. In ArcticNet Scientific Meeting 2018, Ottawa, ON, December 10th to 14th 2018 . doi: 10.6084/m9.figshare.7476098 Abstract: The expansion and drainage of thermokarst lakes respond to climatic trends and are an important part of the permafrost carbon feedback. The effects of climate on total lake area in thermokarst lowlands vary from region to region and may be monitored via remote-sensing, but it is difficult to interpret changes in lake area in terms of volumes of permafrost thawed and organic carbon released from permafrost. This is because the rates of subaerial and sublacustrine permafrost degradation associated with lake expansion, as well as the distribution of organics in the sediment profile, vary across Arctic lowlands due differences in environmental conditions. This research links changes in lake area with tridimensional estimates of permafrost degradation, and assesses associated changes in permafrost carbon storage at the landscape scale. The study area was a zone of polygonal tundra within Old Crow Flats (OCF), YT, a 5600 km 2 Arctic peatland located in an inland basin separated from the Arctic Coast by mountains. The research objectives are: 1) to use remotely sensed imagery to assess rates of lake expansion and characterize the relation between lake size and shore erosion rates in the study area; 2) to use modelling in combination with ground temperature measurements and observations of talik geometry to estimate volumetric rates of permafrost degradation beneath expanding lakes; 3) to use field measurements of shore bank height and samples of permafrost to estimate organic carbon content where permafrost degradation is imminent. Results indicate that, between 1951 and 2011, lake expansion encroached on the surrounding tundra at an average rate of 0.27 km 2 a -1 . The total lake expansion during this period is approximately equal to the total lake area lost to catastrophic drainages in the 1060 km 2 study area. Permafrost thaw occurred beneath the areas that became part of the lakes, and this loss of permafrost was compensated by the aggradation of permafrost in drained basins. However, lake expansion occurred via the erosion of organic-rich permafrost banks varying in height between 0.5 and 4 m, representing an additional loss of permafrost. Due to bank erosion alone, approximately 430 000 m 3 a -1 of sediment fell in the lakes of the study area annually. This represents an input of organic carbon into the lakes of 0.22 Tg C a -1 , of which 0.15 Tg C a -1 was stored in permafrost prior to being thawed during bank erosion. Comparatively, a doubling of active layer depth over the entire study area in the next 20 years would lead to the thawing of 0.01 Tg C a -1 of organic carbon previously stored in permafrost, less than one tenth of what would be released via bank erosion if current erosion rates are sustained. While current climate models with carbon budgets focus on active layer deepening as the main mechanism of permafrost degradation associated with carbon mobilisation, these research results highlight the importance of considering thermokarst lake expansion as a tridimensional process when quantifying the permafrost carbon feedback in Arctic lowlands. Still Image Arctic ArcticNet Climate change Old Crow permafrost Talik Thermokarst Tundra Yukon DataCite Metadata Store (German National Library of Science and Technology) Arctic Yukon Talik ENVELOPE(146.601,146.601,59.667,59.667) Old Crow Flats ENVELOPE(-139.755,-139.755,68.083,68.083)

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