Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard

Arctic permafrost soils store substantial reserves of organic matter (OM) from which microbial transformation contributes significantly to greenhouse gas emissions of CH4 and CO2. However, many younger sediments exposed by glacier retreat and sea level change in fjord landscapes lack significant org...

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Published in:Arctic, Antarctic, and Alpine Research
Main Authors: Ivaylo Kolchev, Ian P.G. Marshall, Eleanor Jones, Jacob C. Yde, Per Nørnberg, Alejandro Mateos-Rivera, Andy J. Hodson, Ebbe N. Bak, Kai Finster
Format: Article in Journal/Newspaper
Language:English
Published: Taylor & Francis Group 2022
Subjects:
Greenhouse gas emission
competition
organic matter quality
biogeochemistry
iron reduction
envir
geo
Adventdalen
Arctic
Bolterdalen
Svalbard
Antarctic and Alpine Research
glacier
permafrost
Online Access:https://doi.org/10.1080/15230430.2022.2097757
https://doaj.org/article/54b88442c34a471b9a851d623a49ccc3
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spelling fttriple:oai:gotriple.eu:oai:doaj.org/article:54b88442c34a471b9a851d623a49ccc3 2023-05-15T13:05:46+02:00 Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard Ivaylo Kolchev Ian P.G. Marshall Eleanor Jones Jacob C. Yde Per Nørnberg Alejandro Mateos-Rivera Andy J. Hodson Ebbe N. Bak Kai Finster 2022-12-01 https://doi.org/10.1080/15230430.2022.2097757 https://doaj.org/article/54b88442c34a471b9a851d623a49ccc3 en eng Taylor & Francis Group doi:10.1080/15230430.2022.2097757 1938-4246 1523-0430 https://doaj.org/article/54b88442c34a471b9a851d623a49ccc3 undefined Arctic, Antarctic, and Alpine Research, Vol 54, Iss 1, Pp 314-334 (2022) Greenhouse gas emission competition organic matter quality biogeochemistry iron reduction envir geo Journal Article https://vocabularies.coar-repositories.org/resource_types/c_6501/ 2022 fttriple https://doi.org/10.1080/15230430.2022.2097757 2023-01-22T18:58:22Z Arctic permafrost soils store substantial reserves of organic matter (OM) from which microbial transformation contributes significantly to greenhouse gas emissions of CH4 and CO2. However, many younger sediments exposed by glacier retreat and sea level change in fjord landscapes lack significant organic carbon resources, so their capacity to promote greenhouse gas emissions is unclear. We therefore studied the effects of increased temperatures (4°C and 21°C) and OM on rates of Fe(III) reduction, CO2 production, and methanogenesis in three different Holocene sedimentary units from a single site within the former marine limit of Adventdalen, Svalbard. Higher temperature and OM addition generally stimulated CH4 production and CO2 production and an increase in Bacteria and Archaea abundance in all units, whereas an equal stimulation of Fe(II) production by OM amendment and an increase in temperature to 21°C was only observed in a diamicton. We observed an accumulation of Fe(II) in beach and delta deposits as well but saw no stimulating effect of additional OM or increased temperature. Interestingly, we observed a small but significant production of CH4 in all units despite the presence of large reservoirs of Fe(III), sulfate, and nitrate, indicating either the availability of substrates that are primarily used by methanogens or a tight physical coupling between fermentation and methanogenesis by direct electron transfer. Our study clearly illustrates a significant challenge that comes with the large heterogeneity on a narrow spatial scale that one encounters when studying soils that have complex histories. Article in Journal/Newspaper Adventdalen Antarctic and Alpine Research Arctic Arctic glacier permafrost Svalbard Unknown Adventdalen ENVELOPE(16.264,16.264,78.181,78.181) Arctic Bolterdalen ENVELOPE(15.945,15.945,78.146,78.146) Svalbard Arctic, Antarctic, and Alpine Research 54 1 314 334
institution Open Polar
collection Unknown
op_collection_id fttriple
language English
topic Greenhouse gas emission
competition
organic matter quality
biogeochemistry
iron reduction
envir
geo
spellingShingle Greenhouse gas emission
competition
organic matter quality
biogeochemistry
iron reduction
envir
geo
Ivaylo Kolchev
Ian P.G. Marshall
Eleanor Jones
Jacob C. Yde
Per Nørnberg
Alejandro Mateos-Rivera
Andy J. Hodson
Ebbe N. Bak
Kai Finster
Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
topic_facet Greenhouse gas emission
competition
organic matter quality
biogeochemistry
iron reduction
envir
geo
description Arctic permafrost soils store substantial reserves of organic matter (OM) from which microbial transformation contributes significantly to greenhouse gas emissions of CH4 and CO2. However, many younger sediments exposed by glacier retreat and sea level change in fjord landscapes lack significant organic carbon resources, so their capacity to promote greenhouse gas emissions is unclear. We therefore studied the effects of increased temperatures (4°C and 21°C) and OM on rates of Fe(III) reduction, CO2 production, and methanogenesis in three different Holocene sedimentary units from a single site within the former marine limit of Adventdalen, Svalbard. Higher temperature and OM addition generally stimulated CH4 production and CO2 production and an increase in Bacteria and Archaea abundance in all units, whereas an equal stimulation of Fe(II) production by OM amendment and an increase in temperature to 21°C was only observed in a diamicton. We observed an accumulation of Fe(II) in beach and delta deposits as well but saw no stimulating effect of additional OM or increased temperature. Interestingly, we observed a small but significant production of CH4 in all units despite the presence of large reservoirs of Fe(III), sulfate, and nitrate, indicating either the availability of substrates that are primarily used by methanogens or a tight physical coupling between fermentation and methanogenesis by direct electron transfer. Our study clearly illustrates a significant challenge that comes with the large heterogeneity on a narrow spatial scale that one encounters when studying soils that have complex histories.
format Article in Journal/Newspaper
author Ivaylo Kolchev
Ian P.G. Marshall
Eleanor Jones
Jacob C. Yde
Per Nørnberg
Alejandro Mateos-Rivera
Andy J. Hodson
Ebbe N. Bak
Kai Finster
author_facet Ivaylo Kolchev
Ian P.G. Marshall
Eleanor Jones
Jacob C. Yde
Per Nørnberg
Alejandro Mateos-Rivera
Andy J. Hodson
Ebbe N. Bak
Kai Finster
author_sort Ivaylo Kolchev
title Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
title_short Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
title_full Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
title_fullStr Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
title_full_unstemmed Microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, Bolterdalen, Svalbard
title_sort microbial iron reduction and greenhouse gas production in response to organic matter amendment and temperature increase of periglacial sediments, bolterdalen, svalbard
publisher Taylor & Francis Group
publishDate 2022
url https://doi.org/10.1080/15230430.2022.2097757
https://doaj.org/article/54b88442c34a471b9a851d623a49ccc3
long_lat ENVELOPE(16.264,16.264,78.181,78.181)
ENVELOPE(15.945,15.945,78.146,78.146)
geographic Adventdalen
Arctic
Bolterdalen
Svalbard
geographic_facet Adventdalen
Arctic
Bolterdalen
Svalbard
genre Adventdalen
Antarctic and Alpine Research
Arctic
Arctic
glacier
permafrost
Svalbard
genre_facet Adventdalen
Antarctic and Alpine Research
Arctic
Arctic
glacier
permafrost
Svalbard
op_source Arctic, Antarctic, and Alpine Research, Vol 54, Iss 1, Pp 314-334 (2022)
op_relation doi:10.1080/15230430.2022.2097757
1938-4246
1523-0430
https://doaj.org/article/54b88442c34a471b9a851d623a49ccc3
op_rights undefined
op_doi https://doi.org/10.1080/15230430.2022.2097757
container_title Arctic, Antarctic, and Alpine Research
container_volume 54
container_issue 1
container_start_page 314
op_container_end_page 334
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