Fire and functional traits: Using functional groups of birds and plants to guide management in a fire-prone, heathy woodland ecosystem

Aim Many dry forests and woodlands worldwide are fire‐prone and support bird and plant communities shaped by fire. Changes in fire regimes, including the time between fires, have important implications for population trajectories. We studied the responses of bird and plant communities of heathy wood...

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Bibliographic Details
Published in:Diversity & distributions 2022-03, Vol.28 (3), p.372-385
Main Authors: Rainsford, Frederick W., Kelly, Luke T., Leonard, Steve W. J., Bennett, Andrew F.
Format: Article
Language:English
Subjects:
Age
Animals
Biodiversity
BIODIVERSITY RESEARCH
Biota
Birds
Community composition
Community ecology
Dry forests
Ecosystems
Evaluation
fire interval
fire management
Fires
Flowers & plants
Foraging habitats
Forest & brush fires
Functional groups
functional traits
Government agencies
habitat
Habitats
Intervals
Land management
Life history
National parks
Plant communities
plants
Population decline
Population studies
post‐fire succession
Prescribed fire
Seeds
Shrubs
Spatial data
Species richness
Strategic management
time since fire
Trees
Vegetation
Woodlands
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Summary:Aim Many dry forests and woodlands worldwide are fire‐prone and support bird and plant communities shaped by fire. Changes in fire regimes, including the time between fires, have important implications for population trajectories. We studied the responses of bird and plant communities of heathy woodlands to time since the last fire, a key measure underpinning fire management, to evaluate whether current management strategies will enhance conservation of multiple taxa. Location Otway Ranges, south‐eastern Australia. Methods We surveyed birds and plants at 38 sites, stratified by an 80‐year post‐fire chronosequence, and modelled the responses of individual species, functional groups and community composition to fire history. Model outputs were used to evaluate the impacts of fire management as guided by (a) domains of tolerable fire intervals, a concept based on plant life history traits, and (b) the spatial arrangement of post‐fire age classes, a surrogate for animal habitats. Results Bird and plant communities both responded to time since fire. Notable relationships included the following: a high reporting rate of ground‐foraging birds and high cover and species richness of shrubs immediately after fire; and a gradual increase up to ~50 years and ~20 years post‐fire of birds that forage in the mid‐storey and facultative‐resprouting plants, respectively. Post‐fire age classes had distinct bird and plant assemblages. Tolerable fire intervals currently used by land managers (min 12–max 45 years between fires) encompassed the peak in richness of most plant functional groups but not the preferred habitat of lower‐mid‐storey foraging birds. Main conclusions Fire management based solely on birds or plants risks population declines in other biota. Use of functional groups can help guide strategic planning, such as spatial representation of post‐fire age classes across the landscape. Maintaining late‐successional vegetation will provide habitat for several groups of birds, while fire is needed at sufficient frequency to prevent loss of plants and ground‐foraging birds.
ISSN:1366-9516
1472-4642
DOI:10.1111/ddi.13278