Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies

Northern boreal peatlands are major terrestrial sinks of organic carbon and these ecosystems, which are highly sensitive to human activities and climate change, act as sensitive archives of past environmental change at various timescales. This study aims at understanding how the climate changes of t...

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Published in:Quaternary Science Reviews
Main Authors: Magnan, Gabriel, van Bellen, Simon, Davies, Lauren, Froese, Duane, Garneau, Michelle, Mullan-Boudreau, Gillian, Zaccone, Claudio, Shotyk, William
Format: Text
Language:English
Published: 2018
Subjects:
bogs
boreal
North America
vegetation dynamics
Holocene
plant macrofossils
permafrost
peat humification
Sphagnum
climate warming
Fort McMurray
Canada
Ice
Online Access:http://archipel.uqam.ca/13659/1/manuscript_magnan_accepted.docx
id ftunivquebec:oai:archipel.uqam.ca:13659
record_format openpolar
spelling ftunivquebec:oai:archipel.uqam.ca:13659 2023-07-16T03:58:29+02:00 Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies Magnan, Gabriel van Bellen, Simon Davies, Lauren Froese, Duane Garneau, Michelle Mullan-Boudreau, Gillian Zaccone, Claudio Shotyk, William 2018-04-01 application/msword http://archipel.uqam.ca/13659/1/manuscript_magnan_accepted.docx en eng http://archipel.uqam.ca/13659/ http://dx.doi.org/10.1016/j.quascirev.2018.01.015 doi:10.1016/j.quascirev.2018.01.015 http://archipel.uqam.ca/13659/1/manuscript_magnan_accepted.docx Magnan, Gabriel; van Bellen, Simon; Davies, Lauren; Froese, Duane; Garneau, Michelle; Mullan-Boudreau, Gillian; Zaccone, Claudio et Shotyk, William (2018). « Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies ». Quaternary Science Reviews, 185, pp. 230-243. bogs boreal North America vegetation dynamics Holocene plant macrofossils permafrost peat humification Sphagnum climate warming Article de revue scientifique PeerReviewed 2018 ftunivquebec https://doi.org/10.1016/j.quascirev.2018.01.015 2023-06-24T23:22:54Z Northern boreal peatlands are major terrestrial sinks of organic carbon and these ecosystems, which are highly sensitive to human activities and climate change, act as sensitive archives of past environmental change at various timescales. This study aims at understanding how the climate changes of the last 1000 years have affected peatland vegetation dynamics in the boreal region of Alberta in western Canada. Peat cores were collected from five bogs in the Fort McMurray region (56–57° N), at the southern limit of sporadic permafrost, and two in central Alberta (53° N and 55° N) outside the present-day limit of permafrost peatlands. The past changes in vegetation communities were reconstructed using detailed plant macrofossil analyses combined with high-resolution peat chronologies (14C, atmospheric bomb-pulse 14C, 210Pb and cryptotephras). Peat humification proxies (C/N, H/C, bulk density) and records of pH and ash content were also used to improve the interpretation of climate-related vegetation changes. Our study shows important changes in peatland vegetation and physical and chemical peat properties during the Little Ice Age (LIA) cooling period mainly from around 1700 CE and the subsequent climate warming of the 20th century. In some bogs, the plant macrofossils have recorded periods of permafrost aggradation during the LIA with drier surface conditions, increased peat humification and high abundance of ericaceous shrubs and black spruce (Picea mariana). The subsequent permafrost thaw was characterized by a short-term shift towards wetter conditions (Sphagnum sect. Cuspidata) and a decline in Picea mariana. Finally, a shift to a dominance of Sphagnum sect. Acutifolia (mainly Sphagnum fuscum) occurred in all the bogs during the second half of the 20th century, indicating the establishment of dry ombrotrophic conditions under the recent warmer and drier climate conditions. Text Fort McMurray Ice permafrost UQAM - Université du Québec à Montréal: archipel Fort McMurray Canada Quaternary Science Reviews 185 230 243
institution Open Polar
collection UQAM - Université du Québec à Montréal: archipel
op_collection_id ftunivquebec
language English
topic bogs
boreal
North America
vegetation dynamics
Holocene
plant macrofossils
permafrost
peat humification
Sphagnum
climate warming
spellingShingle bogs
boreal
North America
vegetation dynamics
Holocene
plant macrofossils
permafrost
peat humification
Sphagnum
climate warming
Magnan, Gabriel
van Bellen, Simon
Davies, Lauren
Froese, Duane
Garneau, Michelle
Mullan-Boudreau, Gillian
Zaccone, Claudio
Shotyk, William
Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
topic_facet bogs
boreal
North America
vegetation dynamics
Holocene
plant macrofossils
permafrost
peat humification
Sphagnum
climate warming
description Northern boreal peatlands are major terrestrial sinks of organic carbon and these ecosystems, which are highly sensitive to human activities and climate change, act as sensitive archives of past environmental change at various timescales. This study aims at understanding how the climate changes of the last 1000 years have affected peatland vegetation dynamics in the boreal region of Alberta in western Canada. Peat cores were collected from five bogs in the Fort McMurray region (56–57° N), at the southern limit of sporadic permafrost, and two in central Alberta (53° N and 55° N) outside the present-day limit of permafrost peatlands. The past changes in vegetation communities were reconstructed using detailed plant macrofossil analyses combined with high-resolution peat chronologies (14C, atmospheric bomb-pulse 14C, 210Pb and cryptotephras). Peat humification proxies (C/N, H/C, bulk density) and records of pH and ash content were also used to improve the interpretation of climate-related vegetation changes. Our study shows important changes in peatland vegetation and physical and chemical peat properties during the Little Ice Age (LIA) cooling period mainly from around 1700 CE and the subsequent climate warming of the 20th century. In some bogs, the plant macrofossils have recorded periods of permafrost aggradation during the LIA with drier surface conditions, increased peat humification and high abundance of ericaceous shrubs and black spruce (Picea mariana). The subsequent permafrost thaw was characterized by a short-term shift towards wetter conditions (Sphagnum sect. Cuspidata) and a decline in Picea mariana. Finally, a shift to a dominance of Sphagnum sect. Acutifolia (mainly Sphagnum fuscum) occurred in all the bogs during the second half of the 20th century, indicating the establishment of dry ombrotrophic conditions under the recent warmer and drier climate conditions.
format Text
author Magnan, Gabriel
van Bellen, Simon
Davies, Lauren
Froese, Duane
Garneau, Michelle
Mullan-Boudreau, Gillian
Zaccone, Claudio
Shotyk, William
author_facet Magnan, Gabriel
van Bellen, Simon
Davies, Lauren
Froese, Duane
Garneau, Michelle
Mullan-Boudreau, Gillian
Zaccone, Claudio
Shotyk, William
author_sort Magnan, Gabriel
title Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
title_short Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
title_full Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
title_fullStr Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
title_full_unstemmed Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies
title_sort impact of the little ice age cooling and 20th century climate change on peatland vegetation dynamics in central and northern alberta using a multi-proxy approach and high-resolution peat chronologies
publishDate 2018
url http://archipel.uqam.ca/13659/1/manuscript_magnan_accepted.docx
geographic Fort McMurray
Canada
geographic_facet Fort McMurray
Canada
genre Fort McMurray
Ice
permafrost
genre_facet Fort McMurray
Ice
permafrost
op_relation http://archipel.uqam.ca/13659/
http://dx.doi.org/10.1016/j.quascirev.2018.01.015
doi:10.1016/j.quascirev.2018.01.015
http://archipel.uqam.ca/13659/1/manuscript_magnan_accepted.docx
Magnan, Gabriel; van Bellen, Simon; Davies, Lauren; Froese, Duane; Garneau, Michelle; Mullan-Boudreau, Gillian; Zaccone, Claudio et Shotyk, William (2018). « Impact of the Little Ice Age cooling and 20th century climate change on peatland vegetation dynamics in central and northern Alberta using a multi-proxy approach and high-resolution peat chronologies ». Quaternary Science Reviews, 185, pp. 230-243.
op_doi https://doi.org/10.1016/j.quascirev.2018.01.015
container_title Quaternary Science Reviews
container_volume 185
container_start_page 230
op_container_end_page 243
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