Identifying the tree species compositions that maximize ecosystem functioning in European forests

Baeten, Lander; Bruelheide, Helge; Plas, Fons van der; Kambach, Stephan; Ratcliffe, Sophia; Jucker, Tommaso; Allan, Eric; Ampoorter, Evy; Barbaro, Luc; Bastías, Cristina C.; Bauhus, Jürgen; Benavides, Raquel; Bonal, Damien; Bouriaud, Olivier; Bussotti, Filippo; Carnol, Monique; Castagneyrol, Bastien; Charbonnier, Yohan; Chećko, Ewa; Coomes, David A.; Dahlgren, Jonas; Dawud, Seid Muhie; Wandeler, Hans De; Domisch, Timo; Finér, Leena; Fischer, Markus; Fotelli, Mariangela N.; Geßler, Arthur; Grossiord, Charlotte; Guyot, Virginie; Hättenschwiler, Stephan; Jactel, Hervé; Jaroszewicz, Bogdan; Joly, François‐Xavier; Koricheva, Julia; Lehtonen, Aleksi; Müller, Sandra; Muys, Bart; Nguyen, Diem; Pollastrini, Martina; Radoglou, K.; Raulund‐Rasmussen, Karsten; Ruiz‐Benito, Paloma; Selvi, Federico; Stenlid, Jan; Valladares, Fernando; Vesterdal, Lars; Verheyen, Kris; Wirth, Christian; Zavala, M.; Scherer‐Lorenzen, Michael

doi:10.1111/1365-2664.13308

Cited by 81 publications

(67 citation statements)

References 38 publications

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“…An additional benefit of BEF experiments is that they often provide information on a wider range of ecosystem services than many agricultural experiments and agronomic analyses, which tend to focus on yield and its sustainability, e.g., weed control and nutrient cycling (Meyer et al, 2018). Mixtures that promote the supply of multiple ecosystem services simultaneously may therefore be identified from BEF studies (Baeten et al, 2019;Storkey et al, 2015). Further evidence of existing BEF transfer comes from grassland studies, which indicate that there are multiple benefits of diversifying agroecosystems in terms of grass yield and reduced weed abundance (Finn et al, 2013).…”

Section: Small-grain and Highly-controlled Experiments (Cluster A)mentioning

confidence: 99%

Transferring biodiversity-ecosystem function research to the management of ‘real-world’ ecosystems

Manning

Loos

Barnes

et al. 2019

Advances in Ecological Research

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Section: Small-grain and Highly-controlled Experiments (Cluster A)mentioning

confidence: 99%

Transferring biodiversity-ecosystem function research to the management of ‘real-world’ ecosystems

Manning

Loos

Barnes

et al. 2019

Advances in Ecological Research

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“…soil macroscopic animals and microbial diversity such as bacteria, fungi and nematodes; Townshend, 1963;Wagg, Bender, Widmer, & Heijden, 2014). Existing studies have mainly focused on biodiversity within a single trophic group (Delgado-Baquerizo et al, 2016;Felipe-Lucia et al, 2018), neglecting the fact that ecosystem functioning depends strongly on complex interactions between trophic levels and between above-and below-ground biodiversity (Baeten et al, 2018;Schuldt et al, 2018;Soliveres et al, 2016). Further studies are needed to explore the relative effects of above-and below-ground biodiversity on forest multifunctionality (FM) while considering the direct and indirect effects of environmental conditions (see Figure 1a).…”

Section: Introductionmentioning

confidence: 99%

“…In addition, ecosystem multifunctionality may be driven by different individual functions that respond strongly to diversity or environmental conditions or by all functions increasing together (Zirbel, Grman, Bassett, & Brudvig, 2019). Thus, identifying how different ecosystem functions respond to biodiversity and environmental conditions, as well as their relative contributions to multifunctionality, is critical to formulating sustainable management and conservation policies (Baeten et al, 2018;Felipe-Lucia et al, 2018; van der Plas, 2019).…”

Section: Introductionmentioning

confidence: 99%

Above‐ and below‐ground biodiversity jointly regulate temperate forest multifunctionality along a local‐scale environmental gradient

et al. 2020

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Tree diversity has been shown to promote a broad range of ecosystem functions in forests. However, how important these effects are in driving ecosystem multifunctionality in natural forests, relative to other drivers, such as below‐ground biodiversity (e.g. soil microbial diversity), community‐level functional traits and environmental conditions, remains poorly understood. Here, we hypothesize that tree species or phylogenetic diversity (PD), stand structure, functional traits and soil microbial diversity jointly regulate temperate forest multifunctionality (FM) along a local‐scale environmental gradient. Using repeated census data from a 25‐ha old‐growth temperate forest, we first quantified eight ecosystem functions and properties related to above‐ and below‐ground nutrient cycling. We then used these to estimate ecosystem multifunctionality using both averaging and multiple threshold (50%, 75% and 95%) approaches. Finally, we used structural equation models to explore how different facets of tree (tree species, functional and PD) and soil (bacteria, fungi and nematode diversity) biodiversity influence ecosystem multifunctionality, as well as how these relationships are modulated by stand structural attributes and environmental conditions (topography and soil nutrients). Forest multifunctionality was positively related to stand structural complexity but negatively related to acquisitive traits (i.e. community‐weighted mean of specific leaf area). Plant PD had no significant direct effect on FM, but it had a significant indirect effect via increased stand structural complexity. The effect of soil microbial diversity on FM increased with increasing threshold levels of FM and outperformed tree diversity and environmental conditions at the highest threshold level (i.e. 95%). Forests on steep slopes had lower levels of ecosystem multifunctionality due to decreased stand structural complexity. Soil nutrients were responsible for regulating FM via plant trait composition and, to a lesser extent, via tree diversity, stand structure and soil microbial diversity. Synthesis. Plant PD, stand structure and soil microbial diversity jointly regulated FM, and these effects were influenced by local‐scale changes in environmental conditions. Soil microbial diversity was a key driver of highly multifunctional forests, whereas conservation of complex stand structure and conservative trait dominance could enhance mean values of multiple functions.

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“…In theory, any positive effect of species diversity could stem from either positive interactions between the co-occurring species (complementarity effects, Loreau & Hector, 2001) or from the admixing of one or few exceptionally productive or dominating species (selection effects, Loreau & Hector, 2001). Depending on the forest ecosystem, species-specific growth responses to increasing tree diversity can be consistently positive (Chamagne et al, 2017;Liang et al, 2016) or variable, depending on the species and context (Baeten et al, 2019;Jucker, Bouriaud, Avacaritei, Dănilă, et al, 2014;Ratcliffe, Holzwarth, Nadrowski, Levick, & Wirth, 2015;del Río et al, 2017;Tobner et al, 2016). It is unclear to what extent these differences in species responses to tree diversity are caused by differences in species-specific characteristics (Fichtner et al, 2017;Williams, Paquette, Cavender-Bares, Messier, & Reich, 2017) or differences in study design.…”

Section: Introductionmentioning

confidence: 99%

How do trees respond to species mixing in experimental compared to observational studies?

Kambach

Allan

Bilodeau‐Gauthier³

et al. 2019

Ecology and Evolution

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For decades, ecologists have investigated the effects of tree species diversity on tree productivity at different scales and with different approaches ranging from observational to experimental study designs. Using data from five European national forest inventories (16,773 plots), six tree species diversity experiments (584 plots), and six networks of comparative plots (169 plots), we tested whether tree species growth responses to species mixing are consistent and therefore transferrable between those different research approaches. Our results confirm the general positive effect of tree species mixing on species growth (16% on average) but we found no consistency in species‐specific responses to mixing between any of the three approaches, even after restricting comparisons to only those plots that shared similar mixtures compositions and forest types. These findings highlight the necessity to consider results from different research approaches when selecting species mixtures that should maximize positive forest biodiversity and functioning relationships.

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Identifying the tree species compositions that maximize ecosystem functioning in European forests

Cited by 81 publications

References 38 publications

Transferring biodiversity-ecosystem function research to the management of ‘real-world’ ecosystems

Transferring biodiversity-ecosystem function research to the management of ‘real-world’ ecosystems

Above‐ and below‐ground biodiversity jointly regulate temperate forest multifunctionality along a local‐scale environmental gradient

How do trees respond to species mixing in experimental compared to observational studies?

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