Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska

Current climate warming strongly affects the Arctic region by increasing thaw depths and modifying water table depths in soils. Exposing newly thawed permafrost at depth unlocks mineral nutrients that can boost plant growth, thereby contributing to modify the balance between carbon input and output...

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Main Authors:	Mauclet, Elisabeth, Opfergelt, Sophie, Hirst, Catherine, Monhonval, Arthur, Debruxelles Laurentine, Ledman Justin, Taylor Meghan, Schuiur A.G., AGU FALL MEETING
Other Authors:	UCL - SST/ELI/ELIE - Environmental Sciences
Format:	Conference Object
Language:	English
Published:	2020
Subjects:	soil plant mineral element Alaska Permafrost Thawing permafrost Arctic permafrost
Online Access:	http://hdl.handle.net/2078.1/239963

id	ftunivlouvain:oai:dial.uclouvain.be:boreal:239963
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spelling	ftunivlouvain:oai:dial.uclouvain.be:boreal:239963 2024-05-12T07:59:52+00:00 Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska Mauclet, Elisabeth Opfergelt, Sophie Hirst, Catherine Monhonval, Arthur Debruxelles Laurentine Ledman Justin Taylor Meghan Schuiur A.G. AGU FALL MEETING UCL - SST/ELI/ELIE - Environmental Sciences 2020 http://hdl.handle.net/2078.1/239963 eng eng boreal:239963 http://hdl.handle.net/2078.1/239963 info:eu-repo/semantics/openAccess soil plant mineral element Alaska Permafrost Thawing permafrost info:eu-repo/semantics/conferenceObject 2020 ftunivlouvain 2024-04-17T16:42:12Z Current climate warming strongly affects the Arctic region by increasing thaw depths and modifying water table depths in soils. Exposing newly thawed permafrost at depth unlocks mineral nutrients that can boost plant growth, thereby contributing to modify the balance between carbon input and output from permafrost regions. In this changing Arctic environment, how will active layer deepening affect plant mineral nutrient availability, plant mineral nutrient uptake and soil-plant nutrient cycling via litter degradation? Studies have highlighted that upon thawing, deep-rooted plants benefit from a newly exposed pool of essential nutrients (e.g., N). It is hypothesized that during plant growth, additional mineral elements (e.g., Ca, K, Mg) are also bio-lifted and recycled in surface soil horizons through litter production, providing a potential source of nutrients for shallower rooted plants. To address this hypothesis and investigate mineral element distribution in plants and soils upon permafrost thaw, we determine the mineral element content (Ca, K, Mg, Na, P, Si, Mn) (i) in plant species from three different plant functional types (sedges, deciduous and evergreen shrubs) and (ii) in the corresponding soil profiles. The plant selection includes species with shallower (e.g., Vaccinium spp.) and deeper (e.g., Carex spp.) rooting depth, across a permafrost thaw gradient at Eight Mile Lake, Central Alaska. In soils, we also determine the availability of Ca, Mg, K, Na for plants from the soil exchange complex. Plant leaves and soil samples were collected in August â€“ September 2019, corresponding to the maximal thaw depth. The sampling transect (vegetation and related soil profiles) encompasses a wide range of thaw depth (from -48 cm to â€“96 cm) and water table depth (from 0 cm to â€“40 cm). Results are discussed considering mineral element distribution in soils, plant rooting depth, and active layer depth to evaluate whether vegetation may access mineral elements from deeper soil horizons, related to the active ... Conference Object Arctic permafrost Alaska DIAL@UCLouvain (Université catholique de Louvain) Arctic
institution	Open Polar
collection	DIAL@UCLouvain (Université catholique de Louvain)
op_collection_id	ftunivlouvain
language	English
topic	soil plant mineral element Alaska Permafrost Thawing permafrost
spellingShingle	soil plant mineral element Alaska Permafrost Thawing permafrost Mauclet, Elisabeth Opfergelt, Sophie Hirst, Catherine Monhonval, Arthur Debruxelles Laurentine Ledman Justin Taylor Meghan Schuiur A.G. AGU FALL MEETING Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
topic_facet	soil plant mineral element Alaska Permafrost Thawing permafrost
description	Current climate warming strongly affects the Arctic region by increasing thaw depths and modifying water table depths in soils. Exposing newly thawed permafrost at depth unlocks mineral nutrients that can boost plant growth, thereby contributing to modify the balance between carbon input and output from permafrost regions. In this changing Arctic environment, how will active layer deepening affect plant mineral nutrient availability, plant mineral nutrient uptake and soil-plant nutrient cycling via litter degradation? Studies have highlighted that upon thawing, deep-rooted plants benefit from a newly exposed pool of essential nutrients (e.g., N). It is hypothesized that during plant growth, additional mineral elements (e.g., Ca, K, Mg) are also bio-lifted and recycled in surface soil horizons through litter production, providing a potential source of nutrients for shallower rooted plants. To address this hypothesis and investigate mineral element distribution in plants and soils upon permafrost thaw, we determine the mineral element content (Ca, K, Mg, Na, P, Si, Mn) (i) in plant species from three different plant functional types (sedges, deciduous and evergreen shrubs) and (ii) in the corresponding soil profiles. The plant selection includes species with shallower (e.g., Vaccinium spp.) and deeper (e.g., Carex spp.) rooting depth, across a permafrost thaw gradient at Eight Mile Lake, Central Alaska. In soils, we also determine the availability of Ca, Mg, K, Na for plants from the soil exchange complex. Plant leaves and soil samples were collected in August â€“ September 2019, corresponding to the maximal thaw depth. The sampling transect (vegetation and related soil profiles) encompasses a wide range of thaw depth (from -48 cm to â€“96 cm) and water table depth (from 0 cm to â€“40 cm). Results are discussed considering mineral element distribution in soils, plant rooting depth, and active layer depth to evaluate whether vegetation may access mineral elements from deeper soil horizons, related to the active ...
author2	UCL - SST/ELI/ELIE - Environmental Sciences
format	Conference Object
author	Mauclet, Elisabeth Opfergelt, Sophie Hirst, Catherine Monhonval, Arthur Debruxelles Laurentine Ledman Justin Taylor Meghan Schuiur A.G. AGU FALL MEETING
author_facet	Mauclet, Elisabeth Opfergelt, Sophie Hirst, Catherine Monhonval, Arthur Debruxelles Laurentine Ledman Justin Taylor Meghan Schuiur A.G. AGU FALL MEETING
author_sort	Mauclet, Elisabeth
title	Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
title_short	Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
title_full	Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
title_fullStr	Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
title_full_unstemmed	Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska
title_sort	influence of thawing permafrost on soil-plant mineral element transfer: case study in interior alaska
publishDate	2020
url	http://hdl.handle.net/2078.1/239963
geographic	Arctic
geographic_facet	Arctic
genre	Arctic permafrost Alaska
genre_facet	Arctic permafrost Alaska
op_relation	boreal:239963 http://hdl.handle.net/2078.1/239963
op_rights	info:eu-repo/semantics/openAccess
_version_	1798841493422604288

Influence of thawing permafrost on soil-plant mineral element transfer: Case study in Interior Alaska

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