Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017

The investigators propose to measure methane concentrations in frozen lakes continuously throughout the Arctic winter using autonomous sampling devices, to more thoroughly address the variability in the methane flux from Arctic lakes to the atmosphere. Methane is a potent greenhouse gas, the release...

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Bibliographic Details
Main Author: Beth Orcutt
Format: Dataset
Language:unknown
Published: Arctic Data Center 2017
Subjects:
Ice
Online Access:https://doi.org/10.18739/A2MK6589W
id dataone:doi:10.18739/A2MK6589W
record_format openpolar
spelling dataone:doi:10.18739/A2MK6589W 2024-11-03T19:44:53+00:00 Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017 Beth Orcutt Seasonally ice-covered permafrost lakes in the Mackenzie River delta in Northwest Territories, Canada: Lake 129 ENVELOPE(-133.8514,-133.8514,68.3042,68.3042) BEGINDATE: 2015-08-01T00:00:00Z ENDDATE: 2016-08-01T00:00:00Z 2017-09-28T00:00:00Z https://doi.org/10.18739/A2MK6589W unknown Arctic Data Center methane observatory permafrost Mackenzie River osmosampler Dataset 2017 dataone:urn:node:ARCTIC https://doi.org/10.18739/A2MK6589W 2024-11-03T19:16:02Z The investigators propose to measure methane concentrations in frozen lakes continuously throughout the Arctic winter using autonomous sampling devices, to more thoroughly address the variability in the methane flux from Arctic lakes to the atmosphere. Methane is a potent greenhouse gas, the release of which from Arctic sources is poised to increase with climate warming. This project will expand upon a successful pilot study that included the initial testing of autonomous continuous fluid sampler and sensor systems. The proposed expansion will involve additional capabilities and the deployment of a sampling unit in each of six small lakes along a north-south gradient in the Mackenzie River delta in the Canadian Arctic for a nine-month period, spanning the winter season. With these data the investigators aim to characterize the physical, chemical, and microbial conditions in the water column to elucidate hydrologic, microbial, and weathering processes during the winter season, when methane builds in lake water under the ice cover. The investigators hypothesize that sudden (week, days, or even hours) releases of methane, following spring flooding and ice cover breakup, produce a distinct atmospheric flux from Arctic lakes that would otherwise be missed, since most logistically reasonable sampling occurs in the summer months when methane concentrations in these lakes are low or below detection. The majority of methane flux to the Arctic atmosphere is estimated to come from soils and small lakes, although these estimates are based on few direct observations with large uncertainties. This proposed study, using in situ samplers and sensors, will allow an extensive microbial, gas and ion analytical program coupled with a network of physical and chemical sensor data to assess temporal conditions during winter months; to confirm fundamental processes and rates; to determine the interplay among microbial, geochemical and physical processes; and to develop a plan for a more inclusive study that takes advantage of low cost proxies for significant processes that best characterize temporal aspects of lake conditions. The project will enhance infrastructure for future research in the Arctic through the development of novel in situ sampling. The project will support several undergraduate and graduate students, providing valuable lab-based experience for students from non-research-intensive institutions. The investigators also will conduct two informal outreach activities to communicate the importance of Arctic climate change to primary school students while also teaching them about design and engineering. They also intend to work closely with Aurora College and Aurora Research Institute based in Inuvik, Canada, to engage First Nations youth. Dataset Arctic Aurora Research Institute Climate change Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes First Nations Ice Inuvik Mackenzie river Northwest Territories permafrost Arctic Data Center (via DataONE) Arctic Northwest Territories Mackenzie River Canada Inuvik ENVELOPE(-133.610,-133.610,68.341,68.341) ENVELOPE(-133.8514,-133.8514,68.3042,68.3042)
institution Open Polar
collection Arctic Data Center (via DataONE)
op_collection_id dataone:urn:node:ARCTIC
language unknown
topic methane
observatory
permafrost
Mackenzie River
osmosampler
spellingShingle methane
observatory
permafrost
Mackenzie River
osmosampler
Beth Orcutt
Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
topic_facet methane
observatory
permafrost
Mackenzie River
osmosampler
description The investigators propose to measure methane concentrations in frozen lakes continuously throughout the Arctic winter using autonomous sampling devices, to more thoroughly address the variability in the methane flux from Arctic lakes to the atmosphere. Methane is a potent greenhouse gas, the release of which from Arctic sources is poised to increase with climate warming. This project will expand upon a successful pilot study that included the initial testing of autonomous continuous fluid sampler and sensor systems. The proposed expansion will involve additional capabilities and the deployment of a sampling unit in each of six small lakes along a north-south gradient in the Mackenzie River delta in the Canadian Arctic for a nine-month period, spanning the winter season. With these data the investigators aim to characterize the physical, chemical, and microbial conditions in the water column to elucidate hydrologic, microbial, and weathering processes during the winter season, when methane builds in lake water under the ice cover. The investigators hypothesize that sudden (week, days, or even hours) releases of methane, following spring flooding and ice cover breakup, produce a distinct atmospheric flux from Arctic lakes that would otherwise be missed, since most logistically reasonable sampling occurs in the summer months when methane concentrations in these lakes are low or below detection. The majority of methane flux to the Arctic atmosphere is estimated to come from soils and small lakes, although these estimates are based on few direct observations with large uncertainties. This proposed study, using in situ samplers and sensors, will allow an extensive microbial, gas and ion analytical program coupled with a network of physical and chemical sensor data to assess temporal conditions during winter months; to confirm fundamental processes and rates; to determine the interplay among microbial, geochemical and physical processes; and to develop a plan for a more inclusive study that takes advantage of low cost proxies for significant processes that best characterize temporal aspects of lake conditions. The project will enhance infrastructure for future research in the Arctic through the development of novel in situ sampling. The project will support several undergraduate and graduate students, providing valuable lab-based experience for students from non-research-intensive institutions. The investigators also will conduct two informal outreach activities to communicate the importance of Arctic climate change to primary school students while also teaching them about design and engineering. They also intend to work closely with Aurora College and Aurora Research Institute based in Inuvik, Canada, to engage First Nations youth.
format Dataset
author Beth Orcutt
author_facet Beth Orcutt
author_sort Beth Orcutt
title Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
title_short Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
title_full Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
title_fullStr Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
title_full_unstemmed Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes, Northwest Territories, Canada, 2011-2017
title_sort collaborative research: year-round autonomous sampling of methane in arctic lakes, northwest territories, canada, 2011-2017
publisher Arctic Data Center
publishDate 2017
url https://doi.org/10.18739/A2MK6589W
op_coverage Seasonally ice-covered permafrost lakes in the Mackenzie River delta in Northwest Territories, Canada: Lake 129
ENVELOPE(-133.8514,-133.8514,68.3042,68.3042)
BEGINDATE: 2015-08-01T00:00:00Z ENDDATE: 2016-08-01T00:00:00Z
long_lat ENVELOPE(-133.610,-133.610,68.341,68.341)
ENVELOPE(-133.8514,-133.8514,68.3042,68.3042)
geographic Arctic
Northwest Territories
Mackenzie River
Canada
Inuvik
geographic_facet Arctic
Northwest Territories
Mackenzie River
Canada
Inuvik
genre Arctic
Aurora Research Institute
Climate change
Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes
First Nations
Ice
Inuvik
Mackenzie river
Northwest Territories
permafrost
genre_facet Arctic
Aurora Research Institute
Climate change
Collaborative Research: Year-round autonomous sampling of methane in Arctic lakes
First Nations
Ice
Inuvik
Mackenzie river
Northwest Territories
permafrost
op_doi https://doi.org/10.18739/A2MK6589W
_version_ 1814731898887340032