A New Approach for Tracking Vegetation Change after Restoration: A Case Study with Peatlands

Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response curves (PRC) and species classification according to their preferential habitats to monitor changes in community composition. Following large‐...

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Veröffentlicht in:Restoration ecology Jg. 21; H. 3; S. 363 - 371
Hauptverfasser: Poulin, Monique, Andersen, Roxane, Rochefort, Line
Format: Journal Article
Sprache:Englisch
Veröffentlicht: Oxford, UK Blackwell Publishing Ltd 01.05.2013
Wiley
Schlagworte:
Animal and plant ecology
Animal, plant and microbial ecology
Applied ecology
Biological and medical sciences
Calamagrostis canadensis
Case studies
Community composition
Community ecology
community structure
Conservation, protection and management of environment and wildlife
cut-over bog
Demecology
ecosystems
Environmental degradation: ecosystems survey and restoration
Environmental restoration
felling
forests
Fundamental and applied biological sciences. Psychology
General aspects
Habitats
indicator species
Kalmia angustifolia
multivariate analyses
Mylia anomala
Peatlands
Plant communities
plant diversity
Plant species
plant succession
Plants (botany)
Plants and fungi
Pohlia nutans
principal response curves
reference ecosystem
Restoration
restoration ecology
Species
Species classification
Sphagnum rubellum
Synecology
temporal variation
Tracking
trajectory analysis
Typha latifolia
Vegetation
Wetlands
cut-over bog
reference ecosystem
trajectory analysis
multivariate analyses
plant diversity
Tracking
restoration ecology
principal response curves
Bogs
indicator species
Biological indicator
plant succession
Vegetation dynamics
Multivariate analysis
Biodiversity
Vegetation succession
Peat bog
Case study
Plant
Ecosystem
Plant marsh community
Ecological recovery
Trajectory
ISSN:1061-2971, 1526-100X
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Abstract Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response curves (PRC) and species classification according to their preferential habitats to monitor changes in community composition. Following large‐scale restoration of a cut‐over peatland, vegetation was surveyed biannually over 8 years. We evaluated whether the establishing plant communities fell within the range of natural variation. We used both general diversity curves and PRC applied on plant species grouped by preferred habitat to compare restored sites and unrestored sites to a reference ecosystem. After 8 years, diversity and richness differed between the sites, with Forest and Ruderal species more prominent in unrestored sites, and Peatland, Forest, and Wetland species dominant in restored sites. The PRC revealed that the restored site became rapidly dominated by typical peatland plants, the main drivers of temporal changes being Sphagnum rubellum, Pohlia nutans, and Mylia anomala. Some differences remained between the restored and the undisturbed species pools: the former had more herbaceous species associated with wetlands such as Calamagrostis canadensis and Typha latifolia and the latter had more forested species like Kalmia angustifolia throughout the study. PRC revealed to be an efficient tool identifying species driving changes at the community level after restoration. In our case study, examining PRC scores after classifying species according to their preferred habitat allowed to illustrate objectively how restoration promotes target species (associated to peatlands) and how lack of intervention benefits ruderal species.
AbstractList Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response curves (PRC) and species classification according to their preferential habitats to monitor changes in community composition. Following large‐scale restoration of a cut‐over peatland, vegetation was surveyed biannually over 8 years. We evaluated whether the establishing plant communities fell within the range of natural variation. We used both general diversity curves and PRC applied on plant species grouped by preferred habitat to compare restored sites and unrestored sites to a reference ecosystem. After 8 years, diversity and richness differed between the sites, with Forest and Ruderal species more prominent in unrestored sites, and Peatland, Forest, and Wetland species dominant in restored sites. The PRC revealed that the restored site became rapidly dominated by typical peatland plants, the main drivers of temporal changes being Sphagnum rubellum, Pohlia nutans, and Mylia anomala. Some differences remained between the restored and the undisturbed species pools: the former had more herbaceous species associated with wetlands such as Calamagrostis canadensis and Typha latifolia and the latter had more forested species like Kalmia angustifolia throughout the study. PRC revealed to be an efficient tool identifying species driving changes at the community level after restoration. In our case study, examining PRC scores after classifying species according to their preferred habitat allowed to illustrate objectively how restoration promotes target species (associated to peatlands) and how lack of intervention benefits ruderal species.
Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response curves (PRC) and species classification according to their preferential habitats to monitor changes in community composition. Following large‐scale restoration of a cut‐over peatland, vegetation was surveyed biannually over 8 years. We evaluated whether the establishing plant communities fell within the range of natural variation. We used both general diversity curves and PRC applied on plant species grouped by preferred habitat to compare restored sites and unrestored sites to a reference ecosystem. After 8 years, diversity and richness differed between the sites, with Forest and Ruderal species more prominent in unrestored sites, and Peatland , Forest , and Wetland species dominant in restored sites. The PRC revealed that the restored site became rapidly dominated by typical peatland plants, the main drivers of temporal changes being Sphagnum rubellum , Pohlia nutans , and Mylia anomala . Some differences remained between the restored and the undisturbed species pools: the former had more herbaceous species associated with wetlands such as Calamagrostis canadensis and Typha latifolia and the latter had more forested species like Kalmia angustifolia throughout the study. PRC revealed to be an efficient tool identifying species driving changes at the community level after restoration. In our case study, examining PRC scores after classifying species according to their preferred habitat allowed to illustrate objectively how restoration promotes target species (associated to peatlands) and how lack of intervention benefits ruderal species.
Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response curves (PRC) and species classification according to their preferential habitats to monitor changes in community composition. Following large-scale restoration of a cut-over peatland, vegetation was surveyed biannually over 8 years. We evaluated whether the establishing plant communities fell within the range of natural variation. We used both general diversity curves and PRC applied on plant species grouped by preferred habitat to compare restored sites and unrestored sites to a reference ecosystem. After 8 years, diversity and richness differed between the sites, with Forest and Ruderal species more prominent in unrestored sites, and Peatland, Forest, and Wetland species dominant in restored sites. The PRC revealed that the restored site became rapidly dominated by typical peatland plants, the main drivers of temporal changes being Sphagnum rubellum, Pohlia nutans, and Mylia anomala. Some differences remained between the restored and the undisturbed species pools: the former had more herbaceous species associated with wetlands such as Calamagrostis canadensis and Typha latifolia and the latter had more forested species like Kalmia angustifolia throughout the study. PRC revealed to be an efficient tool identifying species driving changes at the community level after restoration. In our case study, examining PRC scores after classifying species according to their preferred habitat allowed to illustrate objectively how restoration promotes target species (associated to peatlands) and how lack of intervention benefits ruderal species. [PUBLICATION ABSTRACT]
Author Poulin, Monique
Andersen, Roxane
Rochefort, Line
Author_xml – sequence: 1
  givenname: Monique
  surname: Poulin
  fullname: Poulin, Monique
  email: monique.poulin@fsaa.ulaval.ca
  organization: Peatland Ecology Research Group and Département de phytologie, 2425, rue de l'Agriculture, Université Laval Québec, Québec, Canada G1V 0A6
– sequence: 2
  givenname: Roxane
  surname: Andersen
  fullname: Andersen, Roxane
  organization: Peatland Ecology Research Group and Département de phytologie, 2425, rue de l'Agriculture, Université Laval Québec, Québec, Canada G1V 0A6
– sequence: 3
  givenname: Line
  surname: Rochefort
  fullname: Rochefort, Line
  organization: Peatland Ecology Research Group and Département de phytologie, 2425, rue de l'Agriculture, Université Laval Québec, Québec, Canada G1V 0A6
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Issue 3
Keywords cut-over bog
reference ecosystem
trajectory analysis
multivariate analyses
plant diversity
Tracking
restoration ecology
principal response curves
Bogs
indicator species
Biological indicator
plant succession
Vegetation dynamics
Multivariate analysis
Biodiversity
Vegetation succession
Peat bog
Case study
Plant
Ecosystem
Plant marsh community
Ecological recovery
Trajectory
Language English
License CC BY 4.0
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Notes Appendix S1. List of the 233 species found with the LPI method for the restored and unrestored sites and in quadrats sampled in seven natural peatlands composing the reference ecosystem. Each species was attributed to one of the six habitat preference categories. For Peatland species, both bryophytes and vascular plants were identified according to Payette and Rochefort (2001). For Wetland and Facultative wetland species, vascular plants were identified according to the Ministère du Développement durable, de l'Environnement et des Parcs du Québec (2008). For the rest of the vascular plants, we referred to Boivin (1992; for Cyperaceae) and to Marie-Victorin (1995). For nonvascular plants other than those found preferentially in peatlands, we referred to Sims and Baldwin (1996) for Sphagnum, to Ireland et al. (1987) and J. Faubert (2010, Société québécoise de bryologie, Québec, Canada, personal communication) for mosses, to Jean Faubert for liverworts, and to Brodo et al. (2001) for lichens. The species classification into the six habitat preference categories was based on habitat species preferences in regions South of the 48° parallel. Although some species can be found in more than one category, we used exclusive classification so that each species was attributed to only one category. We chose not to associate Picea mariana to Facultative wetland category and classified it as a Forest species. Some species were too generalists to be attributed to a particular category and were classified as Other species.Appendix S2. Frequencies of occurrence of species identified as indicator species by the principal response curve (see Figs. 5 & 6) from the year prior to restoration (0) and the years after (2, 4, 6, and 8). Values for the restored and unrestored sites are from the LPI method (presence-absence) and those for the reference ecosystem are from percent cover in 1-m2 quadrats (see Methods). The grey line is the average value (and standard error) of the reference ecosystem.
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1987; 13
1993; 23
2010; 36
1996; 19
2002; 53
2000; 3
1993; 66
2006; 14
1995; 10
2009
2003; 14
2008
1996
2005; 42
1995
2011b
2006
2010; 260
2004
1964; 67
2003
1992
1992; 15
2005; 83
2001; 129
2011; 19
2011a; 14
2006; 331
1992; 95
1990; 89
2004; 92
2003; 91
2001
1999; 18
2001; 9
1992; 25
2010; 30
1989
2003; 23
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SSID ssj0015883
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Snippet Developing objective tools for tracking progress of restored sites is of general concern. Here, we present an innovative approach based on principal response...
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Index Database
Enrichment Source
Publisher
StartPage 363
SubjectTerms Animal and plant ecology
Animal, plant and microbial ecology
Applied ecology
Biological and medical sciences
Calamagrostis canadensis
Case studies
Community composition
Community ecology
community structure
Conservation, protection and management of environment and wildlife
cut-over bog
Demecology
ecosystems
Environmental degradation: ecosystems survey and restoration
Environmental restoration
felling
forests
Fundamental and applied biological sciences. Psychology
General aspects
Habitats
indicator species
Kalmia angustifolia
multivariate analyses
Mylia anomala
Peatlands
Plant communities
plant diversity
Plant species
plant succession
Plants (botany)
Plants and fungi
Pohlia nutans
principal response curves
reference ecosystem
Restoration
restoration ecology
Species
Species classification
Sphagnum rubellum
Synecology
temporal variation
Tracking
trajectory analysis
Typha latifolia
Vegetation
Wetlands
Title A New Approach for Tracking Vegetation Change after Restoration: A Case Study with Peatlands
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https://onlinelibrary.wiley.com/doi/abs/10.1111%2Fj.1526-100X.2012.00889.x
https://www.proquest.com/docview/1337735102
https://www.proquest.com/docview/1352291489
https://www.proquest.com/docview/1490527646
Volume 21
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