Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography
Abstract We used repeat oblique photography to quantify and determine the drivers of vegetation change, particularly forest closure and encroachment, in the Rocky Mountains of southern Alberta, Canada, from the beginning of the twentieth century to the present. We classified the landscape into seven...
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Online Access: | https://doi.org/10.1002/ecs2.2774 |
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doaj-4e80720fe727459fa5b69b8f4ba8d97e2020-11-25T01:15:33ZengWileyEcosphere2150-89252019-06-01106n/an/a10.1002/ecs2.2774Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photographyChristopher A. Stockdale0S. Ellen Macdonald1Eric Higgs2Department of Renewable Resources Faculty of Agricultural, Life and Environmental Sciences University of Alberta Edmonton Alberta CanadaDepartment of Renewable Resources Faculty of Agricultural, Life and Environmental Sciences University of Alberta Edmonton Alberta CanadaSchool of Environmental Studies University of Victoria Victoria British Columbia CanadaAbstract We used repeat oblique photography to quantify and determine the drivers of vegetation change, particularly forest closure and encroachment, in the Rocky Mountains of southern Alberta, Canada, from the beginning of the twentieth century to the present. We classified the landscape into seven distinct vegetation types (closed‐canopy conifer forest, broadleaf deciduous forest, mixedwood forest, open‐canopy woodlands, shrublands, grasslands and meadows, non‐vegetated) and assessed vegetation change between the two time periods. We found that closed‐canopy coniferous forest, broadleaf deciduous forest, and mixedwood forest increased on an area basis by 35%, 45%, and 80%, respectively, over this time period; concomitantly, grasslands and open‐canopy woodlands declined by 25% and 39%, respectively. Overall, 28% of the landscape was in a more advanced successional state in 2008 as compared to the early twentieth century. The Montane and Subalpine Natural Subregions (NSR) experienced the most change (42% and 26%, respectively, in a more advanced successional state). The loss of open‐canopy woodlands was observed across the entire landscape, while grassland and meadow losses were most acute in the Subalpine and Alpine NSRs. The probability of vegetation change to a more advanced successional condition was greater at higher elevations and in areas receiving lower amounts of solar insolation. The changes observed are consistent with what we would expect to see due to lengthening of fire return intervals. Understanding the magnitude of change in vegetation types and the drivers of this change is important for the development of effective contemporary ecosystem management and restoration practices.https://doi.org/10.1002/ecs2.2774change detectionecosystem changeforest encroachmenthistorical ecologyrepeat photographyvegetation change |
collection |
DOAJ |
language |
English |
format |
Article |
sources |
DOAJ |
author |
Christopher A. Stockdale S. Ellen Macdonald Eric Higgs |
spellingShingle |
Christopher A. Stockdale S. Ellen Macdonald Eric Higgs Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography Ecosphere change detection ecosystem change forest encroachment historical ecology repeat photography vegetation change |
author_facet |
Christopher A. Stockdale S. Ellen Macdonald Eric Higgs |
author_sort |
Christopher A. Stockdale |
title |
Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
title_short |
Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
title_full |
Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
title_fullStr |
Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
title_full_unstemmed |
Forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
title_sort |
forest closure and encroachment at the grassland interface: a century‐scale analysis using oblique repeat photography |
publisher |
Wiley |
series |
Ecosphere |
issn |
2150-8925 |
publishDate |
2019-06-01 |
description |
Abstract We used repeat oblique photography to quantify and determine the drivers of vegetation change, particularly forest closure and encroachment, in the Rocky Mountains of southern Alberta, Canada, from the beginning of the twentieth century to the present. We classified the landscape into seven distinct vegetation types (closed‐canopy conifer forest, broadleaf deciduous forest, mixedwood forest, open‐canopy woodlands, shrublands, grasslands and meadows, non‐vegetated) and assessed vegetation change between the two time periods. We found that closed‐canopy coniferous forest, broadleaf deciduous forest, and mixedwood forest increased on an area basis by 35%, 45%, and 80%, respectively, over this time period; concomitantly, grasslands and open‐canopy woodlands declined by 25% and 39%, respectively. Overall, 28% of the landscape was in a more advanced successional state in 2008 as compared to the early twentieth century. The Montane and Subalpine Natural Subregions (NSR) experienced the most change (42% and 26%, respectively, in a more advanced successional state). The loss of open‐canopy woodlands was observed across the entire landscape, while grassland and meadow losses were most acute in the Subalpine and Alpine NSRs. The probability of vegetation change to a more advanced successional condition was greater at higher elevations and in areas receiving lower amounts of solar insolation. The changes observed are consistent with what we would expect to see due to lengthening of fire return intervals. Understanding the magnitude of change in vegetation types and the drivers of this change is important for the development of effective contemporary ecosystem management and restoration practices. |
topic |
change detection ecosystem change forest encroachment historical ecology repeat photography vegetation change |
url |
https://doi.org/10.1002/ecs2.2774 |
work_keys_str_mv |
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