Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic
Arctic warming may influence the global climate system by altering of ecological processes that preserve vast quantities of carbon stored in permafrost. Thirty-two percent of global forest carbon stock is stored in boreal forests, and a majority of this carbon is found in Russian forests. Boreal for...
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ftdaytonuniv:oai:ecommons.udayton.edu:graduate_theses-7781 2023-12-17T10:24:51+01:00 Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic Frankenberg, Sarah J. 2020-01-01T08:00:00Z https://ecommons.udayton.edu/graduate_theses/6782 http://rave.ohiolink.edu/etdc/view?acc_num=dayton1596147602477988 unknown eCommons https://ecommons.udayton.edu/graduate_theses/6782 http://rave.ohiolink.edu/etdc/view?acc_num=dayton1596147602477988 Copyright © 2020, author Graduate Theses and Dissertations Biology Climate Change Forestry Arctic Ectomycorrhizal fungi Forest Regeneration text 2020 ftdaytonuniv 2023-11-19T17:52:25Z Arctic warming may influence the global climate system by altering of ecological processes that preserve vast quantities of carbon stored in permafrost. Thirty-two percent of global forest carbon stock is stored in boreal forests, and a majority of this carbon is found in Russian forests. Boreal forests of the Siberian Arctic are dominated by monospecific stands of Larix cajanderii that grow on permafrost and may sequester up to 35% of the carbon stored in Russian boreal forests. Due to the spatial extent of its range, the single-species nature of this forest, and permafrost underlying these forests, Larix cajanderii is a crucial component of the Siberian Arctic carbon sink and may be a key regulator of global climate. This boreal tree species is symbiotic with ectomycorrhizal fungi, which are critical to their growth. Post fire recruitment density of L. cajanderii varies widely, and may be impacted by surrounding vegetation and fungal communities. In this study, I investigate factors affecting ectomycorrhizal fungal (EMF) colonization of roots of L. cajanderii in plots representing a gradient of seedling density after fire in northeast Siberia. In nine burn scars among upland or lowland landscape positions, I measured soil characteristics, seedling metrics, and surrounding EMF inoculum sources to examine the influence these factors have on EMF colonization of tree seedling roots. To determine the effect of EMF colonization on larch seedlings, I quantified percentage of fine root length colonized by EMF for 110 harvested recruits across density treatments. Seedling density treatments of none, moderate and high were observed and a control treatment located in the adjacent unburned stand. EMF were present on nearly all samples collected for analysis. I found that there is a positive relationship between EMF colonization and fresh seasonal growth of recruited seedlings. Together these results demonstrate that EMF may be essential to seedling success. Site topography influenced EMF colonization rates, and an inverse ... Text Arctic Climate change Ice permafrost Siberia University of Dayton: eCommons Arctic |
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Open Polar |
collection |
University of Dayton: eCommons |
op_collection_id |
ftdaytonuniv |
language |
unknown |
topic |
Biology Climate Change Forestry Arctic Ectomycorrhizal fungi Forest Regeneration |
spellingShingle |
Biology Climate Change Forestry Arctic Ectomycorrhizal fungi Forest Regeneration Frankenberg, Sarah J. Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
topic_facet |
Biology Climate Change Forestry Arctic Ectomycorrhizal fungi Forest Regeneration |
description |
Arctic warming may influence the global climate system by altering of ecological processes that preserve vast quantities of carbon stored in permafrost. Thirty-two percent of global forest carbon stock is stored in boreal forests, and a majority of this carbon is found in Russian forests. Boreal forests of the Siberian Arctic are dominated by monospecific stands of Larix cajanderii that grow on permafrost and may sequester up to 35% of the carbon stored in Russian boreal forests. Due to the spatial extent of its range, the single-species nature of this forest, and permafrost underlying these forests, Larix cajanderii is a crucial component of the Siberian Arctic carbon sink and may be a key regulator of global climate. This boreal tree species is symbiotic with ectomycorrhizal fungi, which are critical to their growth. Post fire recruitment density of L. cajanderii varies widely, and may be impacted by surrounding vegetation and fungal communities. In this study, I investigate factors affecting ectomycorrhizal fungal (EMF) colonization of roots of L. cajanderii in plots representing a gradient of seedling density after fire in northeast Siberia. In nine burn scars among upland or lowland landscape positions, I measured soil characteristics, seedling metrics, and surrounding EMF inoculum sources to examine the influence these factors have on EMF colonization of tree seedling roots. To determine the effect of EMF colonization on larch seedlings, I quantified percentage of fine root length colonized by EMF for 110 harvested recruits across density treatments. Seedling density treatments of none, moderate and high were observed and a control treatment located in the adjacent unburned stand. EMF were present on nearly all samples collected for analysis. I found that there is a positive relationship between EMF colonization and fresh seasonal growth of recruited seedlings. Together these results demonstrate that EMF may be essential to seedling success. Site topography influenced EMF colonization rates, and an inverse ... |
format |
Text |
author |
Frankenberg, Sarah J. |
author_facet |
Frankenberg, Sarah J. |
author_sort |
Frankenberg, Sarah J. |
title |
Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
title_short |
Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
title_full |
Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
title_fullStr |
Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
title_full_unstemmed |
Fire, Forest, Ice, and Fungi: Exploring The Mesh Of Relationships Driving Seedling Regeneration In The Siberian Arctic |
title_sort |
fire, forest, ice, and fungi: exploring the mesh of relationships driving seedling regeneration in the siberian arctic |
publisher |
eCommons |
publishDate |
2020 |
url |
https://ecommons.udayton.edu/graduate_theses/6782 http://rave.ohiolink.edu/etdc/view?acc_num=dayton1596147602477988 |
geographic |
Arctic |
geographic_facet |
Arctic |
genre |
Arctic Climate change Ice permafrost Siberia |
genre_facet |
Arctic Climate change Ice permafrost Siberia |
op_source |
Graduate Theses and Dissertations |
op_relation |
https://ecommons.udayton.edu/graduate_theses/6782 http://rave.ohiolink.edu/etdc/view?acc_num=dayton1596147602477988 |
op_rights |
Copyright © 2020, author |
_version_ |
1785570823589855232 |