Your search keyword '"Macdonald, S. Ellen"' showing total 11 results

1. Directional Change in Upland Tundra Plant Communities 20-30 Years after Seismic Exploration in the Canadian Low-Arctic

Author

Kemper, J. Todd and MacDonald, S. Ellen

Published

2009

2. Effects of Contemporary Winter Seismic Exploration on Low Arctic Plant Communities and Permafrost

Author

Kemper, J. Todd and Macdonald, S. Ellen

Published

2009

3. Above‐ and belowground drivers of intraspecific trait variability across subcontinental gradients for five ubiquitous forest plants in North America.

Author

Cardou, Françoise, Munson, Alison D., Boisvert‐Marsh, Laura, Anand, Madhur, Arsenault, André, Bell, F. Wayne, Bergeron, Yves, Boulangeat, Isabelle, Delagrange, Sylvain, Fenton, Nicole J., Gravel, Dominique, Hamel, Benoît, Hébert, François, Johnstone, Jill F., Kumordzi, Bright B., Macdonald, S. Ellen, Mallik, Azim, McIntosh, Anne C. S., McLaren, Jennie R., and Messier, Christian

Subjects

FOREST plants, PLANT species, ECOLOGICAL niche, LEAF area, VASCULAR plants, LEAVES

Abstract

Copyright of Journal of Ecology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2022

4. Data on vegetation across forest edges from the FERN (Forest Edge Research Network).

Author

Harper, Karen A., Gray, Logan, Macdonald, S. Ellen, Lesieur, Daniel, DeFields, Danielle, Dodonov, Pavel, Franklin, Caroline Mary Adrianne, Haughian, Sean R., Mascarúa López, Liliana, Heathcote, Alexandra, Jager, Krista, Yang, Renee, Angelidis, Christine, Braga, Andreza Lanza, Butler, Wendy, Coley, Sarah, Kornelsen, Jonathan M. E., Murphy, Liam, Pelton, Julia, and Recco, Everton Viotto

Subjects

DEAD trees, FOREST plants, RIPARIAN areas, META-analysis, DATABASES, VEGETATION patterns, PLANT species

Abstract

Many studies have focused on vegetation across forest edges to study impacts of edges created by human activities on forest structure and composition, or patterns of vegetation at inherent natural edges. Our objective was to create a database of plant‐related variables across different types of edges from various studies (mainly from across Canada, but also in Brazil and Belize) to facilitate edge research. We compiled data on vegetation along more than 300 transects perpendicular to forest edges adjacent to clear‐cuts, burned areas, bogs, lakes, barrens, insect disturbances, and riparian areas from 24 studies conducted over the past three decades. Data were compiled for more than 400 plant species and forest structure variables (e.g., trees, logs, canopy cover). All data were collected with a similar sampling design of quadrats along transects perpendicular to forest edges, but with varying numbers of transects and quadrats, and distances from the edge. The purpose for most of the studies was either to determine the distance of edge influence (edge width) or to explore the pattern of vegetation along the edge to interior gradient. We provide data tables for the cover of plant species and functional groups, the species and size of live and dead trees, the density of saplings, maximum height of functional groups and shrub species, and the cover of functional groups at different heights (vertical distribution of vegetation). The Forest Edge Research Network (FERN) database provides extensive data on many variables that can be used for further study including meta‐analyses and can assist in answering questions important to conservation efforts (e.g., how is distance of edge influence from created edges affected by different factors?). We plan to expand this database with subsequent studies from the authors and we invite others to contribute to make this a more global database. The data are released under a CC0 license. When using these data, we ask that you cite this data paper and any relevant publications listed in our metadata file. We also encourage you to contact the first author if you are planning to use or contribute to this database. [ABSTRACT FROM AUTHOR]

Published

2023

5. Utilizing a topographic moisture index to characterize understory vegetation patterns in the boreal forest.

Author

Echiverri, Laureen and Macdonald, S. Ellen

Subjects

TAIGAS, PINACEAE, VASCULAR plants, VEGETATION patterns, LIDAR, PLANT diversity, UNDERSTORY plants

Abstract

• Depth-to-water index can be used to identify understory distribution. • Conifer stands had higher understory diversity and abundance on drier sites. • Mixedwood and broadleaf stands had higher understory abundance on drier sites. • Depth-to-water index can be useful for guiding conservation. For the purpose of informing biodiversity conservation efforts in managed landscapes, we explored whether and how understory plant communities (abundance, diversity, composition) were related to a topographic moisture index, called depth-to-water, in the boreal mixedwood forests of northwestern Alberta. Depth-to-water is an index of relative site moisture derived from the Wet Areas Mapping tool using a fine-scale digital elevation model based upon remotely-sensed lidar (light detection and ranging) data. Sample plots were placed along the depth-to-water moisture gradient in three forest types: conifer-dominated, mixedwood, and broadleaf -(deciduous) dominated. Understory vascular plant diversity, abundance, and composition were measured for each plot. We found understory attributes were related to the depth-to-water index with the relationships varying among forest types. In coniferous stands, diversity and abundance (cover) were higher on drier sites. In broadleaf and mixedwood stands, understory abundance was higher on drier sites, but diversity was not related to the depth-to-water index. Lastly, composition was significantly, but weakly, related to the depth-to-water index in all three forest types. Our study shows that this moisture index, based on remotely-sensed data, can be used to characterize patterns in understory vascular plant communities; hence it can be useful for identifying areas of particular interest for conservation or management. [ABSTRACT FROM AUTHOR]

Published

2019

6. Understory vascular plant responses to retention harvesting with and without prescribed fire.

Author

Franklin, Caroline M.A., Nielsen, Scott E., and Macdonald, S. Ellen

Subjects

PRESCRIBED burning, UNDERSTORY plants, WILDFIRES, FOREST management, FUEL reduction (Wildfire prevention), PLANT diversity, TAIGAS, VASCULAR plants

Abstract

Copyright of Canadian Journal of Forest Research is the property of Canadian Science Publishing and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published

2019

7. Combining aggregated and dispersed tree retention harvesting for conservation of vascular plant communities.

Author

Franklin, Caroline M. A., Macdonald, S. Ellen, and Nielsen, Scott E.

Subjects

BIODIVERSITY, VASCULAR plants, FORESTS & forestry, PLANT communities, PLANT species

Abstract

Abstract: Retention harvesting (also called tree retention or structural retention), in which live mature trees are selectively retained within harvested stands at different retention levels and in different patterns (aggregated to dispersed), is increasingly being used to mitigate the negative impacts of forest harvesting on biodiversity. However, the effectiveness of combining different patterns of retention harvesting for conservation and recovery of understory vascular plants in the long term is largely unknown. To address this gap, we compared understory vascular plant diversity, abundance, and composition between aggregated retention and five levels of surrounding dispersed retention (0% [clearcut], 10%, 20%, 50%, 75%) 15 yr postharvest. We also investigated the influence of dispersed retention on the ability of embedded retention patches to support plant communities characteristic of unharvested forests, and whether it varies by patch size of aggregated retention (0.20 ha or 0.46 ha) and position within patches (edge or interior). Species richness, diversity, and cover were higher in the dispersed retention than in the patch retention as the harvested areas favored early‐seral plant species. Graminoid cover was greater at the edges than in the interior of large patches. Retention patches as small as 0.2 ha more effectively supported shade‐tolerant (forest interior) plant communities when they were surrounded by higher levels of dispersed retention (as compared to patches retained within clearcuts). Overall, the combined use of both aggregated and dispersed retention within a given cutblock benefits both late‐ and early‐seral plant species and thus could effectively conserve understory plant assemblages in harvested landscapes. Sustainable forest management should therefore consider using a range of retention patch sizes combined with varying levels of surrounding dispersed retention in harvest designs to achieve objectives for plant conservation. [ABSTRACT FROM AUTHOR]

Published

2018

8. Seasonal and annual dynamics of western Canadian boreal forest plant communities: A legacy data set spanning four decades.

Author

Hesketh, Amelia V., Loesberg, Jenna A., Bledsoe, Ellen K., Karst, Justine, and Macdonald, S. Ellen

Subjects

TAIGAS, FOREST measurement, FOREST plants, EFFECT of human beings on climate change, COMMUNITY forests, FOREST soils, SNOW accumulation

Abstract

As boreal forests rapidly warm due to anthropogenic climate change, long‐term baseline community data are needed to effectively characterize the corresponding ecological changes that are occurring in these forests. The combined seasonal dynamics (SEADYN) and annual dynamics (ANNDYN) data set, which documents the vegetative changes in boreal forests during the snow‐free period, is one such source of baseline community data. These data were collected by George H. La Roi and colleagues in Alberta, Canada from 1980 to 2015 within permanent sampling plots established in the Hondo‐Slave Lake area (eight stands; 1980–2015) in central Alberta and the Athabasca Oil Sands (AOS) region (17 stands; 1981–1984) near Fort McMurray in northeastern Alberta. Various data were collected, with temporal and spatial coverage differing by data set. These data sets include, but are not limited to, cover of each identified vascular plant and bryoid (moss, liverwort, and lichen) species; forest mensuration; forest litter production; and soil temperature and moisture. Notably, permanent sampling plots were set up as a grid, which will facilitate analyses of spatial relations. These data can be used to analyze long‐term changes in seasonal dynamics and succession within boreal forest communities and serve as a baseline for comparison with future forest conditions in unmanaged, managed, and reclaimed forests. Data are released under a CC‐BY license; please cite this data paper when using the data for analyses. [ABSTRACT FROM AUTHOR]

Published

2022

9. Partitioning vascular understory diversity in mixedwood boreal forests: The importance of mixed canopies for diversity conservation.

Author

Chávez, Virginia and Macdonald, S. Ellen

Subjects

PLANT diversity, PLANT canopies, FORESTS & forestry, FOREST conservation, PLANT communities, VASCULAR plants, FOREST management

Abstract

Abstract: Progress in understanding the patterns of plant diversity requires a conceptualization and quantification of the hierarchy of patch configuration that exists in plant communities across levels of observation. In order to identify the scales at which vascular plant diversity is maximized, we investigated the hierarchical organization of understory vascular plant diversity in relation to canopy patch types in mature boreal mixedwood forests in western Canada. In each of two study areas within a 30km2 landscape (55° N, 112° E) we sampled four canopy patch types: conifer, mixed conifer-broadleaf, broadleaf and canopy gaps. Understory diversity (richness and Shannon’s (H′) index) was additively partitioned in relation to these four canopy patch types across a hierarchy of four scales; α-individual patch +β1-among patches within canopy patch type +β2-among canopy patch types within area +β3-between areas. We also examined understory species abundance patterns by means of rank-abundance plots fitted to relative abundance models. The largest partition of species richness was among patches within canopy patch type (β1). For Shannon diversity index, the largest partition was at the within-individual patch level (α1) indicating that evenness was high at the patch level but that dominance increased at higher levels in the hierarchy. The assessment of relative abundance by means of rank abundance plots suggested that the canopy patch types differed in terms of the ecological mechanisms influencing diversity patterns. Considering plant diversity within a hierarchical framework is critical for the understanding and management of biodiversity as maximum levels of plant richness and evenness do not necessarily occur at the same observational scales. Management practices which retain the natural hierarchies of vegetation patches will help conserve plant community richness and diversity. [Copyright &y& Elsevier]

Published

2012

10. Understory plant communities of boreal mixedwood forests in western Canada: Natural patterns and response to variable-retention harvesting.

Author

Macdonald, S. Ellen and Fenniak, Treena E.

Subjects

FORESTS & forestry, TAIGAS, HARVESTING

Abstract

Abstract: We examined patterns of variation in richness, diversity, and composition of understory vascular plant communities in mixedwood boreal forests of varying composition (broadleaf, mixedwood, conifer) in Alberta, Canada, before and for 2 years following variable-retention harvesting (clearcut, 20 and 75% dispersed green tree retention, control). Broadleaf-dominated forests differed from mixedwood or conifer-dominated forests in that they had greater canopy cover, litter depth, soil nitrogen, warmer soils, as well as greater shrub cover, herb and shrub richness and diversity (plot scale). In contrast, conifer, and to a lesser extent mixedwood, forest had greater β diversity than broadleaf forest. Overall, mixedwood and conifer forests were similar to one another, both differed from broadleaf forest. Several species were found to be significant indicators of broadleaf forest but most of these also occurred in the other forest types. Understory composition was related to canopy composition and edaphic conditions. Variable-retention harvesting had little effect on understory cover, richness, or diversity but resulted in reduced richness and β diversity at a larger scale. The clearcut and 20% treatments affected composition in all forest types. Early successional species and those common in disturbed sites were indicators of harvesting while evergreen, shade-tolerant understory herbs were indicators of the control forest and 75% retention harvest. We conclude that it is important to maintain a range of variation in canopy composition of mixedwood forests in order to conserve the associated understory communities. The presence of conifers in these forests has a particularly important influence on understory communities. The threshold for a lifeboat effect of variable-retention harvesting is between 20 and 75% retention. Examination of richness and β diversity at a variety of scales can provide interesting information on effects of harvesting on spatial reorganization and homogenization of understory plant communities. [Copyright &y& Elsevier]

Published

2007

11. Effects of partial post-fire salvage harvesting on vegetation communities in the boreal mixedwood forest region of northeastern Alberta, Canada.

Author

Macdonald, S. Ellen

Subjects

PLANT communities, TAIGAS, FOREST fires

Abstract

Abstract: We examined forest structure and understory vascular plant communities of aspen (Populus tremuloides)-dominated mixedwood boreal forest in Alberta, Canada that had been burned by wildfire and then subjected to one of three treatments (salvage harvested with single-tree retention, salvage harvested with patch-retention, unsalvaged control). Both salvage harvesting treatments resulted in greater cover of regenerating aspen saplings, as compared to unsalvaged controls, but there were no significant effects on vascular plant richness per plot or β diversity. The salvage harvesting treatments differed from the unsalvaged control, but not from one another, in terms of vascular plant community composition. The significant indicators of the unsalvaged treatment were total moss cover and Geranium bicknellii, a fire specialist species. Another fire specialist, Corydalis sempervirens, was an indicator of the patch-retention treatment. Several environmental factors found to be significantly related to vascular plant composition reflected variation in burn severity, rather than the salvage-harvesting treatment. Burned-unsalvaged mixedwood forest was compared to three burned forest types that were unsalvaged because they are not considered merchantable [jack pine (Pinus banksiana), jack pine–black spruce (Picea mariana), black spruce]. The four types of forest were quite different in terms of their structure and vascular plant communities. Burned, non-merchantable forest will not serve as reserves of the post-fire plant communities typical of commercially desirable mixedwood forest, but they may harbor small populations of fire specialist species. Burn severity and pre-fire forest composition have an important influence on the post-fire community, perhaps even more than the salvage-harvesting treatments we examined. Partial salvage harvesting may be an effective way to mitigate some of the potentially negative impacts of post-fire salvaging. [Copyright &y& Elsevier]

Published

2007