Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada

Recognizing that permafrost distributions are largely controlled by topography and climate, our IPY study documents local C cycling processes and GHG emissions as associated with vegetation, soil and permafrost environments along a climatic gradient from the Isolated Patches Permafrost Zone, in nort...

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Bibliographic Details
Main Authors: Jagtar Bhatti, Charles Tarnocai, Michael Brady, Michael Whiticar, Mingliang Wang, Natalia Starstev, Rick Hurdle, Ruth Errington, Thierry Varem-Sanders
Format: Dataset
Language:unknown
Published: 2012
Subjects:
Forests
Permafrost
Carbon fluxes
Greenhouse gas
Soils
Plants
Thawing
Vegetation
Peatland
Mackenzie River
Canada
Inuvik
Mackenzie Valley
IPY
Mackenzie river
Peat
Peat plateau
permafrost
Online Access:https://search.dataone.org/view/sha256:b19b73be41742eecd868de7051ebd5ef58007eb39e0bc3443e866b129f4e052a
id dataone:sha256:b19b73be41742eecd868de7051ebd5ef58007eb39e0bc3443e866b129f4e052a
record_format openpolar
spelling dataone:sha256:b19b73be41742eecd868de7051ebd5ef58007eb39e0bc3443e866b129f4e052a 2024-06-03T18:46:57+00:00 Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada Jagtar Bhatti Charles Tarnocai Michael Brady Michael Whiticar Mingliang Wang Natalia Starstev Rick Hurdle Ruth Errington Thierry Varem-Sanders BEGINDATE: 2007-04-01T00:00:00Z ENDDATE: 2012-03-04T00:00:00Z 2012-10-17T00:00:00Z https://search.dataone.org/view/sha256:b19b73be41742eecd868de7051ebd5ef58007eb39e0bc3443e866b129f4e052a unknown Forests Permafrost Carbon fluxes Greenhouse gas Soils Plants Thawing Vegetation Peatland Mackenzie River Dataset 2012 dataone:urn:node:BOREALIS 2024-06-03T18:08:43Z Recognizing that permafrost distributions are largely controlled by topography and climate, our IPY study documents local C cycling processes and GHG emissions as associated with vegetation, soil and permafrost environments along a climatic gradient from the Isolated Patches Permafrost Zone, in northern Alberta, to the Continuous Permafrost Zone at Inuvik, NWT. In order to understand variation in vegetation, soils, and permafrost, an extensive network of 26 sites has been established over the summers of 2007 and 2008, with four of these sites intensively monitored, from 2007 to the present, for C cycling and GHG exchange. Each NWT site encompasses a gradient from upland to peatland, including areas of permafrost-affected peatlands (peat plateaux), areas of permafrost thaw within the peat plateau matrix (collapse scars), and nearby forests occurring on mineral soils (upland forests). The northern Alberta site is entirely permafrost free, containing peatland plots in a bog, an internal lawn (area of permafrost thaw within an unfrozen bog matrix), and an adjacent upland forest. Preliminary data indicate that vegetation primarily varies from upland forest to peat plateau to collapse scar, with collapse scars having the most distinct plant communities. Permafrost zonation is a strong sec ondary gradient, with greatest differences between plant communities of the Continuous Permafrost Zone and those of either the Sporadic or Extensive Discontinuous Permafrost Zones. The CH4 release/consumption within the study area is intricate and highly variable, fluctuating with the local soil water and corresponding vegetation. Significant surface CH4 production, essentially by microbial methyl-type fermentation, occurs only in submerged parts, and hence most reducing parts of the soil profile. Contrary to initial expectations, CH4 production is greatest during the warmest months and is insignificant during the spring thaw. Carbon dioxide emissions and net ecosystem CO2 exchange (NEE) measurements at the ground surface decreases from south to north and are mainly affected by soil temperature and the presence of permafrost. Topographic position affects soil respiration rate, which is significantly greater in uplands than peatlands, while plant uptake of CO2 by photosynthesis also varies with landscape position, accounting for over half of NEE in peatlands but less than a quarter in uplands. Dataset Inuvik IPY Mackenzie river Mackenzie Valley Peat Peat plateau permafrost Unknown Canada Inuvik ENVELOPE(-133.610,-133.610,68.341,68.341) Mackenzie River Mackenzie Valley ENVELOPE(-126.070,-126.070,52.666,52.666)
institution Open Polar
collection Unknown
op_collection_id dataone:urn:node:BOREALIS
language unknown
topic Forests
Permafrost
Carbon fluxes
Greenhouse gas
Soils
Plants
Thawing
Vegetation
Peatland
Mackenzie River
spellingShingle Forests
Permafrost
Carbon fluxes
Greenhouse gas
Soils
Plants
Thawing
Vegetation
Peatland
Mackenzie River
Jagtar Bhatti
Charles Tarnocai
Michael Brady
Michael Whiticar
Mingliang Wang
Natalia Starstev
Rick Hurdle
Ruth Errington
Thierry Varem-Sanders
Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
topic_facet Forests
Permafrost
Carbon fluxes
Greenhouse gas
Soils
Plants
Thawing
Vegetation
Peatland
Mackenzie River
description Recognizing that permafrost distributions are largely controlled by topography and climate, our IPY study documents local C cycling processes and GHG emissions as associated with vegetation, soil and permafrost environments along a climatic gradient from the Isolated Patches Permafrost Zone, in northern Alberta, to the Continuous Permafrost Zone at Inuvik, NWT. In order to understand variation in vegetation, soils, and permafrost, an extensive network of 26 sites has been established over the summers of 2007 and 2008, with four of these sites intensively monitored, from 2007 to the present, for C cycling and GHG exchange. Each NWT site encompasses a gradient from upland to peatland, including areas of permafrost-affected peatlands (peat plateaux), areas of permafrost thaw within the peat plateau matrix (collapse scars), and nearby forests occurring on mineral soils (upland forests). The northern Alberta site is entirely permafrost free, containing peatland plots in a bog, an internal lawn (area of permafrost thaw within an unfrozen bog matrix), and an adjacent upland forest. Preliminary data indicate that vegetation primarily varies from upland forest to peat plateau to collapse scar, with collapse scars having the most distinct plant communities. Permafrost zonation is a strong sec ondary gradient, with greatest differences between plant communities of the Continuous Permafrost Zone and those of either the Sporadic or Extensive Discontinuous Permafrost Zones. The CH4 release/consumption within the study area is intricate and highly variable, fluctuating with the local soil water and corresponding vegetation. Significant surface CH4 production, essentially by microbial methyl-type fermentation, occurs only in submerged parts, and hence most reducing parts of the soil profile. Contrary to initial expectations, CH4 production is greatest during the warmest months and is insignificant during the spring thaw. Carbon dioxide emissions and net ecosystem CO2 exchange (NEE) measurements at the ground surface decreases from south to north and are mainly affected by soil temperature and the presence of permafrost. Topographic position affects soil respiration rate, which is significantly greater in uplands than peatlands, while plant uptake of CO2 by photosynthesis also varies with landscape position, accounting for over half of NEE in peatlands but less than a quarter in uplands.
format Dataset
author Jagtar Bhatti
Charles Tarnocai
Michael Brady
Michael Whiticar
Mingliang Wang
Natalia Starstev
Rick Hurdle
Ruth Errington
Thierry Varem-Sanders
author_facet Jagtar Bhatti
Charles Tarnocai
Michael Brady
Michael Whiticar
Mingliang Wang
Natalia Starstev
Rick Hurdle
Ruth Errington
Thierry Varem-Sanders
author_sort Jagtar Bhatti
title Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
title_short Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
title_full Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
title_fullStr Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
title_full_unstemmed Recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the Mackenzie Valley region of Canada
title_sort recent changes in carbon source-sink relationships and greenhouse gas emissions in forest and peatland ecosystems along the mackenzie valley region of canada
publishDate 2012
url https://search.dataone.org/view/sha256:b19b73be41742eecd868de7051ebd5ef58007eb39e0bc3443e866b129f4e052a
op_coverage BEGINDATE: 2007-04-01T00:00:00Z ENDDATE: 2012-03-04T00:00:00Z
long_lat ENVELOPE(-133.610,-133.610,68.341,68.341)
ENVELOPE(-126.070,-126.070,52.666,52.666)
geographic Canada
Inuvik
Mackenzie River
Mackenzie Valley
geographic_facet Canada
Inuvik
Mackenzie River
Mackenzie Valley
genre Inuvik
IPY
Mackenzie river
Mackenzie Valley
Peat
Peat plateau
permafrost
genre_facet Inuvik
IPY
Mackenzie river
Mackenzie Valley
Peat
Peat plateau
permafrost
_version_ 1800873692570320896

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