Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data

Arctic tundra ecosystems will play a key role in future climate change due to intensifying permafrost thawing, plant growth and ecosystem carbon exchange, but monitoring these changes may be challenging due to the heterogeneity of Arctic landscapes. We examined spatial variation and linkages of soil...

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Main Authors: Mikola, Juha, Virtanen, Tarmo, Linkosalmi, Maiju, Vähä, Emmi, Nyman, Johanna, Postanogova, Olga, Räsänen, Aleksi, Kotze, D. Johan, Laurila, Tuomas, Juutinen, Sari, Kondratyev, Vladimir, Aurela, Mika
Format: Article in Journal/Newspaper
Language:unknown
Published: 2018
Subjects:
Soil
Vegetation
Remote sensing
Permafrost
Ecosystem carbon exchange
Land cover type
NDVI
Satellite image
Topography
LAI
Moss
Vascular plant
Soil temperature
Spatial variation
Reflectance
Spatial extrapolation
Arctic
Tiksi
Climate change
permafrost
Tundra
Siberia
Online Access:http://hdl.handle.net/10255/dryad.178986
https://doi.org/10.5061/dryad.8382j4r
id ftdryad:oai:v1.datadryad.org:10255/dryad.178986
record_format openpolar
institution Open Polar
collection Dryad Digital Repository (Duke University)
op_collection_id ftdryad
language unknown
topic Soil
Vegetation
Remote sensing
Permafrost
Ecosystem carbon exchange
Land cover type
NDVI
Satellite image
Topography
LAI
Moss
Vascular plant
Soil temperature
Spatial variation
Reflectance
Spatial extrapolation
spellingShingle Soil
Vegetation
Remote sensing
Permafrost
Ecosystem carbon exchange
Land cover type
NDVI
Satellite image
Topography
LAI
Moss
Vascular plant
Soil temperature
Spatial variation
Reflectance
Spatial extrapolation
Mikola, Juha
Virtanen, Tarmo
Linkosalmi, Maiju
Vähä, Emmi
Nyman, Johanna
Postanogova, Olga
Räsänen, Aleksi
Kotze, D. Johan
Laurila, Tuomas
Juutinen, Sari
Kondratyev, Vladimir
Aurela, Mika
Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
topic_facet Soil
Vegetation
Remote sensing
Permafrost
Ecosystem carbon exchange
Land cover type
NDVI
Satellite image
Topography
LAI
Moss
Vascular plant
Soil temperature
Spatial variation
Reflectance
Spatial extrapolation
description Arctic tundra ecosystems will play a key role in future climate change due to intensifying permafrost thawing, plant growth and ecosystem carbon exchange, but monitoring these changes may be challenging due to the heterogeneity of Arctic landscapes. We examined spatial variation and linkages of soil and plant attributes in a site of Siberian Arctic tundra in Tiksi, northeast Russia, and evaluated possibilities to capture this variation by remote sensing for the benefit of carbon exchange measurements and landscape extrapolation. We distinguished nine land cover types (LCTs) and to characterize them, sampled 92 study plots for plant and soil attributes in 2014. Moreover, to test if variation in plant and soil attributes can be detected using remote sensing, we produced a normalized difference vegetation index (NDVI) and topographical parameters for each study plot using three very high spatial resolution multispectral satellite images. We found that soils ranged from mineral soils in bare soil and lichen tundra LCTs to soils of high percentage of organic matter (OM) in graminoid tundra, bog, dry fen and wet fen. OM content of the top soil was on average 14 g dm−3 in bare soil and lichen tundra and 89 g dm−3 in other LCTs. Total moss biomass varied from 0 to 820 g m−2, total vascular shoot mass from 7 to 112 g m−2 and vascular leaf area index (LAI) from 0.04 to 0.95 among LCTs. In late summer, soil temperatures at 15 cm depth were on average 25 ◦C in bare soil and lichen tundra, and varied from 5 to 9 ◦C in other LCTs. On average, depth of the biologically active, unfrozen soil layer doubled from early July to mid-August. When contrasted across study plots, moss biomass was positively associated with soil OM % and OM content and negatively associated with soil temperature, explaining 14–34 % of variation. Vascular shoot mass and LAI were also positively associated with soil OM content, and LAI with active layer depth, but only explained 6–15 % of variation. NDVI captured variation in vascular LAI better than in moss biomass, but while this difference was significant with late season NDVI, it was minimal with early season NDVI. For this reason, soil attributes associated with moss mass were better captured by early season NDVI. Topographic attributes were related to LAI and many soil attributes, but not to moss biomass and could not increase the amount of spatial variation explained in plant and soil attributes above that achieved by NDVI. The LCT map we produced had low to moderate uncertainty in predictions for plant and soil properties except for moss biomass and bare soil and lichen tundra LCTs. Our results illustrate a typical tundra ecosystem with great fine-scale spatial variation in both plant and soil attributes. Mosses dominate plant biomass and control many soil attributes, including OM % and temperature, but variation in moss biomass is difficult to capture by remote sensing reflectance, topography or a LCT map. Despite the general accuracy of landscape level predictions in our LCT approach, this indicates challenges in the spatial extrapolation of some of those vegetation and soil attributes that are relevant for the regional ecosystem and global climate models.
format Article in Journal/Newspaper
author Mikola, Juha
Virtanen, Tarmo
Linkosalmi, Maiju
Vähä, Emmi
Nyman, Johanna
Postanogova, Olga
Räsänen, Aleksi
Kotze, D. Johan
Laurila, Tuomas
Juutinen, Sari
Kondratyev, Vladimir
Aurela, Mika
author_facet Mikola, Juha
Virtanen, Tarmo
Linkosalmi, Maiju
Vähä, Emmi
Nyman, Johanna
Postanogova, Olga
Räsänen, Aleksi
Kotze, D. Johan
Laurila, Tuomas
Juutinen, Sari
Kondratyev, Vladimir
Aurela, Mika
author_sort Mikola, Juha
title Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
title_short Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
title_full Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
title_fullStr Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
title_full_unstemmed Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data
title_sort data from: spatial variation and linkages of soil and vegetation in the siberian arctic tundra – coupling field observations with remote sensing data
publishDate 2018
url http://hdl.handle.net/10255/dryad.178986
https://doi.org/10.5061/dryad.8382j4r
op_coverage Arctic
Siberia
Tiksi
long_lat ENVELOPE(128.867,128.867,71.633,71.633)
geographic Arctic
Tiksi
geographic_facet Arctic
Tiksi
genre Arctic
Arctic
Climate change
permafrost
Tiksi
Tundra
Siberia
genre_facet Arctic
Arctic
Climate change
permafrost
Tiksi
Tundra
Siberia
op_relation 15;;2018
doi:10.5061/dryad.8382j4r/1
doi:10.5194/bg-2017-569
doi:10.5061/dryad.8382j4r
Mikola J, Virtanen T, Linkosalmi M, Vähä E, Nyman J, Postanogova O, Räsänen A, Kotze DJ, Laurila T, Juutinen S, Kondratyev V, Aurela M (2018) Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data. Biogeosciences 15: 2781-2801.
http://hdl.handle.net/10255/dryad.178986
op_doi https://doi.org/10.5061/dryad.8382j4r
https://doi.org/10.5061/dryad.8382j4r/1
https://doi.org/10.5194/bg-2017-569
_version_ 1766300699531935744
spelling ftdryad:oai:v1.datadryad.org:10255/dryad.178986 2023-05-15T14:27:07+02:00 Data from: Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data Mikola, Juha Virtanen, Tarmo Linkosalmi, Maiju Vähä, Emmi Nyman, Johanna Postanogova, Olga Räsänen, Aleksi Kotze, D. Johan Laurila, Tuomas Juutinen, Sari Kondratyev, Vladimir Aurela, Mika Arctic Siberia Tiksi 2018-05-04T16:25:54Z http://hdl.handle.net/10255/dryad.178986 https://doi.org/10.5061/dryad.8382j4r unknown 15;;2018 doi:10.5061/dryad.8382j4r/1 doi:10.5194/bg-2017-569 doi:10.5061/dryad.8382j4r Mikola J, Virtanen T, Linkosalmi M, Vähä E, Nyman J, Postanogova O, Räsänen A, Kotze DJ, Laurila T, Juutinen S, Kondratyev V, Aurela M (2018) Spatial variation and linkages of soil and vegetation in the Siberian Arctic tundra – coupling field observations with remote sensing data. Biogeosciences 15: 2781-2801. http://hdl.handle.net/10255/dryad.178986 Soil Vegetation Remote sensing Permafrost Ecosystem carbon exchange Land cover type NDVI Satellite image Topography LAI Moss Vascular plant Soil temperature Spatial variation Reflectance Spatial extrapolation Article 2018 ftdryad https://doi.org/10.5061/dryad.8382j4r https://doi.org/10.5061/dryad.8382j4r/1 https://doi.org/10.5194/bg-2017-569 2020-01-01T16:08:40Z Arctic tundra ecosystems will play a key role in future climate change due to intensifying permafrost thawing, plant growth and ecosystem carbon exchange, but monitoring these changes may be challenging due to the heterogeneity of Arctic landscapes. We examined spatial variation and linkages of soil and plant attributes in a site of Siberian Arctic tundra in Tiksi, northeast Russia, and evaluated possibilities to capture this variation by remote sensing for the benefit of carbon exchange measurements and landscape extrapolation. We distinguished nine land cover types (LCTs) and to characterize them, sampled 92 study plots for plant and soil attributes in 2014. Moreover, to test if variation in plant and soil attributes can be detected using remote sensing, we produced a normalized difference vegetation index (NDVI) and topographical parameters for each study plot using three very high spatial resolution multispectral satellite images. We found that soils ranged from mineral soils in bare soil and lichen tundra LCTs to soils of high percentage of organic matter (OM) in graminoid tundra, bog, dry fen and wet fen. OM content of the top soil was on average 14 g dm−3 in bare soil and lichen tundra and 89 g dm−3 in other LCTs. Total moss biomass varied from 0 to 820 g m−2, total vascular shoot mass from 7 to 112 g m−2 and vascular leaf area index (LAI) from 0.04 to 0.95 among LCTs. In late summer, soil temperatures at 15 cm depth were on average 25 ◦C in bare soil and lichen tundra, and varied from 5 to 9 ◦C in other LCTs. On average, depth of the biologically active, unfrozen soil layer doubled from early July to mid-August. When contrasted across study plots, moss biomass was positively associated with soil OM % and OM content and negatively associated with soil temperature, explaining 14–34 % of variation. Vascular shoot mass and LAI were also positively associated with soil OM content, and LAI with active layer depth, but only explained 6–15 % of variation. NDVI captured variation in vascular LAI better than in moss biomass, but while this difference was significant with late season NDVI, it was minimal with early season NDVI. For this reason, soil attributes associated with moss mass were better captured by early season NDVI. Topographic attributes were related to LAI and many soil attributes, but not to moss biomass and could not increase the amount of spatial variation explained in plant and soil attributes above that achieved by NDVI. The LCT map we produced had low to moderate uncertainty in predictions for plant and soil properties except for moss biomass and bare soil and lichen tundra LCTs. Our results illustrate a typical tundra ecosystem with great fine-scale spatial variation in both plant and soil attributes. Mosses dominate plant biomass and control many soil attributes, including OM % and temperature, but variation in moss biomass is difficult to capture by remote sensing reflectance, topography or a LCT map. Despite the general accuracy of landscape level predictions in our LCT approach, this indicates challenges in the spatial extrapolation of some of those vegetation and soil attributes that are relevant for the regional ecosystem and global climate models. Article in Journal/Newspaper Arctic Arctic Climate change permafrost Tiksi Tundra Siberia Dryad Digital Repository (Duke University) Arctic Tiksi ENVELOPE(128.867,128.867,71.633,71.633)

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