The function‐dominance correlation drives the direction and strength of biodiversity–ecosystem functioning relationships

Crawford, Michael; Barry, Kathryn E.; Clark, Adam Thomas; Farrior, Caroline E.; Hines, Jes; Ladouceur, Emma; Lichstein, Jeremy W.; Maréchaux, Isabelle; Mori, Akira; Reineking, Björn; Turnbull, Lindsay A.; Wirth, Christian; Rüger, Nadja

doi:10.1111/ele.13776

Cited by 13 publications

(6 citation statements)

References 57 publications

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“…However, we found a negative or negligible relationship between species richness and multifunctionality for most trophic groups at neighborhood scales, a result that is inconsistent with previous studies (Wang et al, 2019). One plausible reason for this surprising finding is that competitive, though low-functioning, species are more likely to be incorporated into diverse mixtures, and this will lead to a tendency of species-rich communities to provide little functionality (Crawford et al, 2021). Thus, species' identities in a local species pool may more strongly affect ecosystem multifunctionality than changes in species richness at a small scale (Crawford et al, 2021;Hagan et al, 2021).…”

Section: Multitrophic Groups Influence Multifunctionalitycontrasting

confidence: 99%

“…One plausible reason for this surprising finding is that competitive, though low-functioning, species are more likely to be incorporated into diverse mixtures, and this will lead to a tendency of species-rich communities to provide little functionality (Crawford et al, 2021). Thus, species' identities in a local species pool may more strongly affect ecosystem multifunctionality than changes in species richness at a small scale (Crawford et al, 2021;Hagan et al, 2021). A second reason for this scale effect could be that resource and abiotic variables are sufficiently homogeneous at small scales, so there are insufficient opportunities for niche partitioning and complementarity, and, thus, the best performing species that are well matched to local conditions determine ecosystem function (Cardinale, 2011), but the strong environmental gradient means that spillover of less fit species might dilute functional efficiency.…”

Section: Multitrophic Groups Influence Multifunctionalitymentioning

confidence: 99%

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Multitrophic diversity and biotic associations influence subalpine forest ecosystem multifunctionality

Luo

Cadotte

Liu

et al. 2022

Ecology

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Biodiversity across multiple trophic levels is required to maintain multiple ecosystem functions. Yet it remains unclear how multitrophic diversity and species interactions regulate ecosystem multifunctionality. Here, combining data from 9 different trophic groups (including trees, shrubs, herbs, leaf mites, small mammals, bacteria, pathogenic fungi, saprophytic fungi, and symbiotic fungi) and 13 ecosystem functions related to supporting, provisioning, and regulating services, we used a multitrophic perspective to evaluate the effects of elevation, diversity, and network complexity on scale‐dependent subalpine forest multifunctionality. Our results demonstrated that elevation and soil pH significantly modified species composition and richness across multitrophic groups and influenced multiple functions simultaneously. We present evidence that species richness across multiple trophic groups had stronger effects on multifunctionality than species richness at any single trophic level. Moreover, biotic associations, indicating the complexity of trophic networks, were positively associated with multifunctionality. The relative effects of diversity on multifunctionality increased at the scale of the larger community compared to a scale accounting for neighboring interactions. Our results highlight the paramount importance of scale‐ and context‐dependent multitrophic diversity and interactions for a better understanding of mountain ecosystem multifunctionality in a changing world.

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Section: Multitrophic Groups Influence Multifunctionalitycontrasting

confidence: 99%

Section: Multitrophic Groups Influence Multifunctionalitymentioning

confidence: 99%

Multitrophic diversity and biotic associations influence subalpine forest ecosystem multifunctionality

Luo

Cadotte

Liu

et al. 2022

Ecology

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“…The latter case is often referred to as dominance. In cases of extreme competitive asymmetry, dominant individuals may monopolize access to key resources such as light or water, severely reducing the growth of subordinate neighbors and eventually killing them, reducing the positive relationship between biodiversity and ecosystem functioning when dominant species are present (Crawford et al, 2021).…”

Section: Dominancementioning

confidence: 99%

Forest and Biodiversity 2: a tree diversity experiment to understand the consequences of multiple dimensions of diversity and composition for long-term ecosystem function and resilience

Cavender-Bares,

Grossman,

Guzmán Q.

et al. 2024

Preprint

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We introduce a new low-density tree diversity experiment at the Cedar Creek Ecosystem Science Reserve in central Minnesota, USA aimed at testing long-term ecosystem consequences of tree diversity and composition. The experiment was designed to provide guidance on forest restoration efforts that will simultaneously advance carbon sequestration goals and contribute to biodiversity conservation and sustainability. The new Forest and Biodiversity (FAB2) experiment uses native tree species in varying levels of species richness, phylogenetic diversity, and functional diversity to test the mechanisms and processes that contribute to forest stability and ecosystem productivity in the face of global change. FAB2 was designed and established in conjunction with a prior experiment (FAB1) in which the same set of twelve species was planted in 16 m2 plots at high density (0.5 m spacing). In addition to lower density plantings (1 m spacing), FAB2 also has larger plots (100 m2 and 400 m2) appropriate for testing long-term ecosystem consequences of species composition and diversity. Within the first six years, mortality in the 400 m2 monoculture plots was significantly higher than in the 100 m2 plots. The highest mortality among any treatments occurred in Tilia americana and Acer negundo monocultures, but mortality for both species decreased with increasing plot diversity. These results highlight the importance of forest diversity in reducing mortality in some species and point to potential mechanisms, including light and drought stress, that cause tree mortality in vulnerable monocultures. The experiment highlights challenges to maintaining monoculture and low-diversity treatments in tree mixture experiments of large extent. The FAB2 experiment provides a long-term platform for discerning the importance of species and lineage effects and of multiple dimensions of diversity in restoring ecosystem functions and services provided by forests. It also provides a platform for improving remote sensing approaches, including Uncrewed Aerial Vehicles (UAVs) equipped with LiDAR, multispectral, and hyperspectral sensors, to complement ground-based monitoring of forest function and diversity. We aim for the experiment to contribute to international efforts to monitor and manage forests in the face of global change.

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“…Model intercomparison efforts in the biodiversity and ecosystem function literature (e.g., Crawford et al. 2021 ) can help explore differences across systems and improve the generalizability of biodiversity and ecosystem function relationships.…”

Section: Model Integration Strategiesmentioning

confidence: 99%

A Conceptual Framework to Integrate Biodiversity, Ecosystem Function, and Ecosystem Service Models

et al. 2022

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Global biodiversity and ecosystem service models typically operate independently. Ecosystem service projections may therefore be overly optimistic because they do not always account for the role of biodiversity in maintaining ecological functions. We review models used in recent global model intercomparison projects and develop a novel model integration framework to more fully account for the role of biodiversity in ecosystem function, a key gap for linking biodiversity changes to ecosystem services. We propose two integration pathways. The first uses empirical data on biodiversity–ecosystem function relationships to bridge biodiversity and ecosystem function models and could currently be implemented globally for systems and taxa with sufficient data. We also propose a trait-based approach involving greater incorporation of biodiversity into ecosystem function models. Pursuing both approaches will provide greater insight into biodiversity and ecosystem services projections. Integrating biodiversity, ecosystem function, and ecosystem service modeling will enhance policy development to meet global sustainability goals.

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The function‐dominance correlation drives the direction and strength of biodiversity–ecosystem functioning relationships

Cited by 13 publications

References 57 publications

Multitrophic diversity and biotic associations influence subalpine forest ecosystem multifunctionality

Multitrophic diversity and biotic associations influence subalpine forest ecosystem multifunctionality

Forest and Biodiversity 2: a tree diversity experiment to understand the consequences of multiple dimensions of diversity and composition for long-term ecosystem function and resilience

A Conceptual Framework to Integrate Biodiversity, Ecosystem Function, and Ecosystem Service Models

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