Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming

1.Tall-shrub expansion into low-statured communities, a hallmark of recent vegetative change across tundra ecosystems, involves three major genera: Alnus, Betula, and Salix. Which genus expands most into tundra landscapes will determine ecosystem properties. 2.We show that Alnus and Salix shrubs seg...

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Main Authors: Rinas, Christina L., Dial, Roman J., Sullivan, Patrick F., Smeltz, T. Scott, Tobin, S. Carl, Loso, Michael, Geck, Jason E.
Format: Article in Journal/Newspaper
Language:unknown
Published: 2017
Subjects:
alpine
climate change
forecast modeling
thermal niche modeling
plant-climate interactions
range expansion
shrubs
tundra
Arctic
Climate change
Tundra
Alaska
Online Access:http://hdl.handle.net/10255/dryad.134803
https://doi.org/10.5061/dryad.dc863
id ftdryad:oai:v1.datadryad.org:10255/dryad.134803
record_format openpolar
spelling ftdryad:oai:v1.datadryad.org:10255/dryad.134803 2023-05-15T15:18:46+02:00 Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming Rinas, Christina L. Dial, Roman J. Sullivan, Patrick F. Smeltz, T. Scott Tobin, S. Carl Loso, Michael Geck, Jason E. Chugach Mountains Alaska North America 2017-01-13T14:50:15Z http://hdl.handle.net/10255/dryad.134803 https://doi.org/10.5061/dryad.dc863 unknown doi:10.5061/dryad.dc863/1 doi:10.5061/dryad.dc863/2 doi:10.5061/dryad.dc863/3 doi:10.5061/dryad.dc863/4 doi:10.5061/dryad.dc863/5 doi:10.5061/dryad.dc863/6 doi:10.1111/1365-2745.12737 doi:10.5061/dryad.dc863 Rinas CL, Dial RJ, Sullivan PF, Smeltz TS, Tobin SC, Loso M, Geck JE (2017) Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming. Journal of Ecology 105(4): 935-946. 0022-0477 http://hdl.handle.net/10255/dryad.134803 alpine climate change forecast modeling thermal niche modeling plant-climate interactions range expansion shrubs tundra Article 2017 ftdryad https://doi.org/10.5061/dryad.dc863 https://doi.org/10.5061/dryad.dc863/1 https://doi.org/10.5061/dryad.dc863/2 https://doi.org/10.5061/dryad.dc863/3 https://doi.org/10.5061/dryad.dc863/4 https://doi.org/10.5061/dryad.dc863/5 https://doi.org/1 2020-01-01T15:45:02Z 1.Tall-shrub expansion into low-statured communities, a hallmark of recent vegetative change across tundra ecosystems, involves three major genera: Alnus, Betula, and Salix. Which genus expands most into tundra landscapes will determine ecosystem properties. 2.We show that Alnus and Salix shrubs segregate thermal space (elevation x insolation) and colonize tundra landscapes differently in response to climate warming, thereby replacing different tundra types. 3.Vegetative change estimated from repeat photography should account for hill-slope. Methodologically, slope determines surface area estimated from orthophotos as projected pixel area times secant of pixel slope. Ecologically, the change in thermally-responsive vegetative area is sensitive to terrain steepness, scaling as the cosecant of hill-slope, so that studies should expect more shrub expansion in areas of shallow slopes than steep slopes. 4.Repeat aerial photography in Alaska's Chugach Mountains from 1972-2012 orthorectified on high-resolution lidar DEM indicated tall Salix was rare in 1972 and colonized warmer slopes by 2012. Tall Alnus colonized steeper, cooler slopes both by 2012 and by 1972. Salix and forest colonized similar thermal space. Colonization probability for both shrub genera was maximized at intermediate elevations. 5.Alnus colonization adjacent to dwarf-shrub tundra was twenty-times as likely as Salix colonization. Salix colonization adjacent to low-shrub/herbaceous tundra was three-times as likely as Alnus colonization. Replacement of dwarf-shrub tundra by Alnus and of low-shrub/herbaceous communities by Salix will affect herbivores and soil properties. 6.Good agreement between observations of plant functional type and multinomial predictions in a thermal space defined by elevation and insolation suggested that these two variables were sufficient for forecast modeling. Spatially explicit, climate-driven GLM multinomial and random forest classification models in available thermal space forecast surface areas of forest, Alnus, Salix, and tundra over a range of warming, modeled as upward shifted isotherms, including expected IPCC scenarios. Both modeling approaches indicated that shrubs may respond non-linearly to warming. 7.Synthesis The provision of taxon-specific coefficients for climate-driven, spatially-explicit models using high resolution digital elevation models is necessary for accurately forecasting vegetative change due to climate warming in montane and arctic regions. Article in Journal/Newspaper Arctic Climate change Tundra Alaska Dryad Digital Repository (Duke University) Arctic
institution Open Polar
collection Dryad Digital Repository (Duke University)
op_collection_id ftdryad
language unknown
topic alpine
climate change
forecast modeling
thermal niche modeling
plant-climate interactions
range expansion
shrubs
tundra
spellingShingle alpine
climate change
forecast modeling
thermal niche modeling
plant-climate interactions
range expansion
shrubs
tundra
Rinas, Christina L.
Dial, Roman J.
Sullivan, Patrick F.
Smeltz, T. Scott
Tobin, S. Carl
Loso, Michael
Geck, Jason E.
Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
topic_facet alpine
climate change
forecast modeling
thermal niche modeling
plant-climate interactions
range expansion
shrubs
tundra
description 1.Tall-shrub expansion into low-statured communities, a hallmark of recent vegetative change across tundra ecosystems, involves three major genera: Alnus, Betula, and Salix. Which genus expands most into tundra landscapes will determine ecosystem properties. 2.We show that Alnus and Salix shrubs segregate thermal space (elevation x insolation) and colonize tundra landscapes differently in response to climate warming, thereby replacing different tundra types. 3.Vegetative change estimated from repeat photography should account for hill-slope. Methodologically, slope determines surface area estimated from orthophotos as projected pixel area times secant of pixel slope. Ecologically, the change in thermally-responsive vegetative area is sensitive to terrain steepness, scaling as the cosecant of hill-slope, so that studies should expect more shrub expansion in areas of shallow slopes than steep slopes. 4.Repeat aerial photography in Alaska's Chugach Mountains from 1972-2012 orthorectified on high-resolution lidar DEM indicated tall Salix was rare in 1972 and colonized warmer slopes by 2012. Tall Alnus colonized steeper, cooler slopes both by 2012 and by 1972. Salix and forest colonized similar thermal space. Colonization probability for both shrub genera was maximized at intermediate elevations. 5.Alnus colonization adjacent to dwarf-shrub tundra was twenty-times as likely as Salix colonization. Salix colonization adjacent to low-shrub/herbaceous tundra was three-times as likely as Alnus colonization. Replacement of dwarf-shrub tundra by Alnus and of low-shrub/herbaceous communities by Salix will affect herbivores and soil properties. 6.Good agreement between observations of plant functional type and multinomial predictions in a thermal space defined by elevation and insolation suggested that these two variables were sufficient for forecast modeling. Spatially explicit, climate-driven GLM multinomial and random forest classification models in available thermal space forecast surface areas of forest, Alnus, Salix, and tundra over a range of warming, modeled as upward shifted isotherms, including expected IPCC scenarios. Both modeling approaches indicated that shrubs may respond non-linearly to warming. 7.Synthesis The provision of taxon-specific coefficients for climate-driven, spatially-explicit models using high resolution digital elevation models is necessary for accurately forecasting vegetative change due to climate warming in montane and arctic regions.
format Article in Journal/Newspaper
author Rinas, Christina L.
Dial, Roman J.
Sullivan, Patrick F.
Smeltz, T. Scott
Tobin, S. Carl
Loso, Michael
Geck, Jason E.
author_facet Rinas, Christina L.
Dial, Roman J.
Sullivan, Patrick F.
Smeltz, T. Scott
Tobin, S. Carl
Loso, Michael
Geck, Jason E.
author_sort Rinas, Christina L.
title Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
title_short Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
title_full Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
title_fullStr Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
title_full_unstemmed Data from: Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
title_sort data from: thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming
publishDate 2017
url http://hdl.handle.net/10255/dryad.134803
https://doi.org/10.5061/dryad.dc863
op_coverage Chugach Mountains
Alaska
North America
geographic Arctic
geographic_facet Arctic
genre Arctic
Climate change
Tundra
Alaska
genre_facet Arctic
Climate change
Tundra
Alaska
op_relation doi:10.5061/dryad.dc863/1
doi:10.5061/dryad.dc863/2
doi:10.5061/dryad.dc863/3
doi:10.5061/dryad.dc863/4
doi:10.5061/dryad.dc863/5
doi:10.5061/dryad.dc863/6
doi:10.1111/1365-2745.12737
doi:10.5061/dryad.dc863
Rinas CL, Dial RJ, Sullivan PF, Smeltz TS, Tobin SC, Loso M, Geck JE (2017) Thermal segregation drives patterns of alder and willow expansion in a montane ecosystem subject to climate warming. Journal of Ecology 105(4): 935-946.
0022-0477
http://hdl.handle.net/10255/dryad.134803
op_doi https://doi.org/10.5061/dryad.dc863
https://doi.org/10.5061/dryad.dc863/1
https://doi.org/10.5061/dryad.dc863/2
https://doi.org/10.5061/dryad.dc863/3
https://doi.org/10.5061/dryad.dc863/4
https://doi.org/10.5061/dryad.dc863/5
https://doi.org/1
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