The distribution and role of functional abundance in cross‐scale resilience

Sundstrom, Shana M.; Angeler, David G.; Barichievy, Chris; Eason, Tarsha; Garmestani, Ahjond S.; Gunderson, Lance; Knutson, Melinda G.; Nash, Kirsty L.; Spanbauer, Trisha L.; Stow, Craig A.; Allen, Craig R.

doi:10.1002/ecy.2508

Cited by 20 publications

(22 citation statements)

References 107 publications

(249 reference statements)

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“…Resilience is posited to derive, in part, from the distribution of species diversity within and across scales (and in particular, the diversity of functional traits; Peterson et al, 1998). Ecological systems can often compensate for the loss or population reduction of single species, though resilience may be diminished (Sundstrom and Allen, 2014;Sundstrom et al, 2018).…”

Section: Selecting An Appropriate Spatial Extent and Grainmentioning

confidence: 99%

“…Including different taxa with varying affinities to the ecosystems within the system, spatial requirements, and sensitivities to the predominant disturbances may help identify the causes of change more precisely and limit errors of interpretation. The increasing availability of data, statistical tools, and comprehensive models relating species to resilience supports multi-species approaches (Sundstrom et al, 2018).…”

Section: Understanding Relationships Among General Ecological and Smentioning

confidence: 99%

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Operationalizing Ecological Resilience Concepts for Managing Species and Ecosystems at Risk

2019

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This review provides an overview and integration of the use of resilience concepts to guide natural resources management actions. We emphasize ecosystems and landscapes and provide examples of the use of these concepts from empirical research in applied ecology. We begin with a discussion of definitions and concepts of ecological resilience and related terms that are applicable to management. We suggest that a resilience-based framework for management facilitates regional planning by providing the ability to locate management actions where they will have the greatest benefits and determine effective management strategies. We review the six key components of a resilience-based framework, beginning with managing for adaptive capacity and selecting an appropriate spatial extent and grain. Critical elements include developing an understanding of the factors influencing the general and ecological resilience of ecosystems and landscapes, the landscape context and spatial resilience, pattern and process interactions and their variability, and relationships among ecological and spatial resilience and the capacity to support habitats and species. We suggest that a spatially explicit approach, which couples geospatial information on general and spatial resilience to disturbance with information on resources, habitats, or species, provides the foundation for resilience-based management. We provide a case study from the sagebrush biome that illustrates the use of geospatial information on ecological and spatial resilience for prioritizing management actions and determine effective strategies.

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Section: Selecting An Appropriate Spatial Extent and Grainmentioning

confidence: 99%

Section: Understanding Relationships Among General Ecological and Smentioning

confidence: 99%

Operationalizing Ecological Resilience Concepts for Managing Species and Ecosystems at Risk

2019

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“…The evaluation of cross-scale structure has been originally based on animal body sizes (Holling, 1992). More recently it has been extended to a broader discontinuity framework that accounts for abundances in ecological studies Sundstrom et al, 2018) and that accommodates metrics from non-ecological systems (e.g., city size: Garmestani et al, 2008). There is also evidence that plankton studies based on body mass of single species and biovolume of populations give similar results (Baho et al, 2015).…”

Section: Statistical Analysesmentioning

confidence: 99%

“…Patterns of discrete size structures of organisms in communities are related to a number of abiotic and biotic factors that operate across distinct scales of space and time; that is, they reflect the hierarchical organization of ecosystems (Nash et al, 2014;Sundstrom et al, 2018). This is due to competitive interactions and behavioral, life-history, and morphological adaptations to resources (e.g., food and shelter) that prevail at each scale (Holling, 1992;Segura et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

“…For instance, an elephant and an ant in a savannah interact with and exploit very different scales in the system. The discrete size structure within communities, also referred to as cross-scale structure (Sundstrom et al, 2018), has been suggested to serve as a surrogate of resilience in ecosystems , and other complex systems (Sundstrom et al, 2014). This is due to the ability of one scale (discrete size structure) in the system being able to buffer against disturbances at other scales as a function of their functional trait characteristics and diversity .…”

Section: Introductionmentioning

confidence: 99%

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Discontinuity Analysis Reveals Alternative Community Regimes During Phytoplankton Succession

2019

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It is well-recognized in plankton ecology that phytoplankton development can lead to distinct peaks (i.e., blooms) during spring and summer. We used a 5-year (2007-2011) phytoplankton data set and utilized discontinuity analysis to assess resilience attributes of spring and summer blooms based on the cross-scale resilience model. Using the size structure (i.e., cross-scale structure as an indicator of resilience) in the sampled plankton data, we assessed whether spring and summer blooms differ substantially between but not within blooms; that is, whether they comprise alternative community regimes. Our exploratory study supported this expectation and more broadly resilience theory, which posits that ecological systems can manifest in and change between alternative regimes. The dynamics of regimes receives increased attention because rapid environmental change potentially irreversibly alters ecosystems. Model organisms are needed that allow revealing patterns and processes of various aspects of regime dynamics at tractable time scales. Our preliminary findings suggest that phytoplankton can be suitable models for assessing the intricacies of regimes and regime changes.

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Estimating density of forest bats and their long‐term trends in a climate refuge

Law

Brassil

Proud³

et al. 2023

Ecology and Evolution

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For many species, estimating density is challenging, but it is important for conservation planning and understanding the functional role of species. Bats play key ecological roles, yet little is known about their free-ranging density. We used a long-term banding study of four species caught in an extensively forested climate refuge and spatial capture-recapture models (SCR) to estimate density and its change over time.Between 1999 and 2020, there were 3671 captures of four bat species, which were all edge-space foragers. Recaptures represented 16% (n = 587) of all captures, of which 89 were between-trap-cluster movements. Closed spatial mark-recapture models es-

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The distribution and role of functional abundance in cross‐scale resilience

Cited by 20 publications

References 107 publications

Operationalizing Ecological Resilience Concepts for Managing Species and Ecosystems at Risk

Operationalizing Ecological Resilience Concepts for Managing Species and Ecosystems at Risk

Discontinuity Analysis Reveals Alternative Community Regimes During Phytoplankton Succession

Estimating density of forest bats and their long‐term trends in a climate refuge

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