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2. Enhancing tree performance through species mixing: review of a quarter-century of TreeDivNet experiments reveals research gaps and practical insights

Author

Depauw, L., De Lombaerde, E., Dhiedt, E., Blondeel, H., Abdala-Roberts, L., Auge, Harald, Barsoum, N., Bauhus, J., Chu, C., Damtew, A., Eisenhauer, N., Fagundes, M.V., Ganade, G., Gendreau-Berthiaume, B., Godbold, D., Gravel, D., Guillemot, J., Hajek, P., Hector, A., Hérault, B., Jactel, H., Koricheva, J., Kreft, H., Liu, X., Mereu, S., Messier, C., Muys, B., Nock, C.A., Paquette, A., Parker, J.D., Parker, W.C., Paterno, G.B., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rewald, B., Scherer-Lorenzen, M., Schnabel, F., Sousa-Silva, R., Weih, M., Zemp, D.C., Verheyen, K., Baeten, L., Depauw, L., De Lombaerde, E., Dhiedt, E., Blondeel, H., Abdala-Roberts, L., Auge, Harald, Barsoum, N., Bauhus, J., Chu, C., Damtew, A., Eisenhauer, N., Fagundes, M.V., Ganade, G., Gendreau-Berthiaume, B., Godbold, D., Gravel, D., Guillemot, J., Hajek, P., Hector, A., Hérault, B., Jactel, H., Koricheva, J., Kreft, H., Liu, X., Mereu, S., Messier, C., Muys, B., Nock, C.A., Paquette, A., Parker, J.D., Parker, W.C., Paterno, G.B., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rewald, B., Scherer-Lorenzen, M., Schnabel, F., Sousa-Silva, R., Weih, M., Zemp, D.C., Verheyen, K., and Baeten, L.

Abstract

Purpose of Review International ambitions for massive afforestation and restoration are high. To make these investments sustainable and resilient under future climate change, science is calling for a shift from planting monocultures to mixed forests. But what is the scientific basis for promoting diverse plantations, and what is the feasibility of their establishment and management? As the largest global network of tree diversity experiments, TreeDivNet is uniquely positioned to answer these pressing questions. Building on 428 peer-reviewed TreeDivNet studies, combined with the results of a questionnaire completed by managers of 32 TreeDivNet sites, we aimed to answer the following questions: (i) How and where have TreeDivNet experiments enabled the relationship between tree diversity and tree performance (including productivity, survival, and pathogen damage) to be studied, and what has been learned? (ii) What are the remaining key knowledge gaps in our understanding of the relationship between tree diversity and tree performance? and (iii) What practical insights can be gained from the TreeDivNet experiments for operational, real-world forest plantations? Recent Findings We developed a conceptual framework that identifies the variety of pathways through which target tree performance is related to local neighbourhood diversity and mapped the research efforts for each of those pathways. Experimental research on forest mixtures has focused primarily on direct tree diversity effects on productivity, with generally positive effects of species and functional diversity on productivity. Fewer studies focused on indirect effects mediated via biotic growing conditions (e.g. soil microbes and herbivores) and resource availability and uptake. Most studies examining light uptake found positive effects of species diversity. For pests and diseases, the evidence points mostly towards lower levels of infection for target trees when growing in mixed plantations. Tree diversity effe

Published
2024

3. Tree diversity reduces variability in sapling survival under drought

Author

Blondeel, H., Guillemot, J., Martin-StPaul, N., Druel, A., Bilodeau-Gauthier, S., Bauhus, J., Grossiord, C., Hector, A., Jactel, H., Jensen, J., Messier, C., Muys, B., Serrano-León, H., Auge, Harald, Barsoum, N., Birhane, E., Bruelheide, H., Cavender-Bares, J., Chu, C., Cumming, J.R., Damtew, A., Eisenhauer, N., Ferlian, O., Fiedler, S., Ganade, G., Godbold, D.L., Gravel, D., Hall, J.S., Hölscher, D., Hulvey, K.B., Koricheva, J., Kreft, H., Lapadat, C., Liang, J., Liu, X., Meredieu, C., Mereu, S., Montgomery, R., Morillas, L., Nock, C., Paquette, A., Parker, J.D., Parker, W.C., Paterno, G.B., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rentch, J., Rewald, B., Sandén, H., Sinacore, K., Standish, R.J., Stefanski, A., Tobin, P.C., van Breugel, M., Vergara Fagundes, M., Weih, M., Williams, L.J., Zhou, M., Scherer-Lorenzen, M., Verheyen, K., Baeten, L., Blondeel, H., Guillemot, J., Martin-StPaul, N., Druel, A., Bilodeau-Gauthier, S., Bauhus, J., Grossiord, C., Hector, A., Jactel, H., Jensen, J., Messier, C., Muys, B., Serrano-León, H., Auge, Harald, Barsoum, N., Birhane, E., Bruelheide, H., Cavender-Bares, J., Chu, C., Cumming, J.R., Damtew, A., Eisenhauer, N., Ferlian, O., Fiedler, S., Ganade, G., Godbold, D.L., Gravel, D., Hall, J.S., Hölscher, D., Hulvey, K.B., Koricheva, J., Kreft, H., Lapadat, C., Liang, J., Liu, X., Meredieu, C., Mereu, S., Montgomery, R., Morillas, L., Nock, C., Paquette, A., Parker, J.D., Parker, W.C., Paterno, G.B., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rentch, J., Rewald, B., Sandén, H., Sinacore, K., Standish, R.J., Stefanski, A., Tobin, P.C., van Breugel, M., Vergara Fagundes, M., Weih, M., Williams, L.J., Zhou, M., Scherer-Lorenzen, M., Verheyen, K., and Baeten, L.

Abstract

Enhancing tree diversity may be important to fostering resilience to drought-related climate extremes. So far, little attention has been given to whether tree diversity can increase the survival of trees and reduce its variability in young forest plantations.We conducted an analysis of seedling and sapling survival from 34 globally distributed tree diversity experiments (363,167 trees, 168 species, 3744 plots, 7 biomes) to answer two questions: (1) Do drought and tree diversity alter the mean and variability in plot-level tree survival, with higher and less variable survival as diversity increases? and (2) Do species that survive poorly in monocultures survive better in mixtures and do specific functional traits explain monoculture survival?Tree species richness reduced variability in plot-level survival, while functional diversity (Rao's Q entropy) increased survival and also reduced its variability. Importantly, the reduction in survival variability became stronger as drought severity increased. We found that species with low survival in monocultures survived comparatively better in mixtures when under drought. Species survival in monoculture was positively associated with drought resistance (indicated by hydraulic traits such as turgor loss point), plant height and conservative resource-acquisition traits (e.g. low leaf nitrogen concentration and small leaf size).Synthesis. The findings highlight: (1) The effectiveness of tree diversity for decreasing the variability in seedling and sapling survival under drought; and (2) the importance of drought resistance and associated traits to explain altered tree species survival in response to tree diversity and drought. From an ecological perspective, we recommend mixing be considered to stabilize tree survival, particularly when functionally diverse forests with drought-resistant species also promote high survival of drought-sensitive species.

Published
2024

4. Explore before you restore : Incorporating complex systems thinking in ecosystem restoration

Author

Maes, S.L., Perring, M.P., Cohen, R., Akinnifesi, F.K., Bargués-Tobella, A., Bastin, J.F., Bauters, M., Bernardino, P.N., Brancalion, P.H.S., Bullock, J.M., Ellison, D., Fayolle, A., Fremout, T., Gann, G.D., Hishe, H., Holmgren, M., Ilstedt, U., Mahy, G., Messier, C., Parr, C.L., Ryan, C.M., Sacande, M., Sankaran, M., Scheffer, M.S., Suding, K.N., Van Meerbeek, K., Verbeeck, H., Verbist, B.J.P., Verheyen, K., Winowiecki, L.A., Muys, B., Maes, S.L., Perring, M.P., Cohen, R., Akinnifesi, F.K., Bargués-Tobella, A., Bastin, J.F., Bauters, M., Bernardino, P.N., Brancalion, P.H.S., Bullock, J.M., Ellison, D., Fayolle, A., Fremout, T., Gann, G.D., Hishe, H., Holmgren, M., Ilstedt, U., Mahy, G., Messier, C., Parr, C.L., Ryan, C.M., Sacande, M., Sankaran, M., Scheffer, M.S., Suding, K.N., Van Meerbeek, K., Verbeeck, H., Verbist, B.J.P., Verheyen, K., Winowiecki, L.A., and Muys, B.

Abstract

The global movement for ecosystem restoration has gained momentum in response to the Bonn Challenge (2010) and the UN Decade on Ecosystem Restoration (UNDER, 2021–2030). While several science-based guidelines exist to aid in achieving successful restoration outcomes, significant variation remains in the outcomes of restoration projects. Some of this disparity can be attributed to unexpected responses of ecosystem components to planned interventions. Given the complex nature of ecosystems, we propose that concepts from Complex Systems Science (CSS) that are linked to non-linearity, such as regime shifts, ecological resilience and ecological feedbacks, should be employed to help explain this variation in restoration outcomes from an ecological perspective. Our framework, Explore Before You Restore, illustrates how these concepts impact restoration outcomes by influencing degradation and recovery trajectories. Additionally, we propose incorporating CSS concepts into the typical restoration project cycle through a CSS assessment phase and suggest that the need for such assessment is explicitly included in the guidelines to improve restoration outcomes. To facilitate this inclusion and make it workable by practitioners, we describe indicators and methods available for restoration teams to answer key questions that should make up such CSS assessment. In doing so, we identify key outstanding science and policy tasks that are needed to further operationalize CSS assessment in restoration. Synthesis and applications. By illustrating how key Complex Systems Science (CSS) concepts linked to non-linear threshold behaviour can impact restoration outcomes through influencing recovery trajectories, our framework Explore Before You Restore demonstrates the need to incorporate Complex Systems thinking in ecosystem restoration. We argue that inclusion of CSS assessment into restoration project cycles, and more broadly, into international restoration guidelines, may significantly impr

Published
2024

6. Globally, functional traits are weak predictors of juvenile tree growth, and we do not know why

Author

Paine, CET, Amissah, L, Auge, H, Baraloto, C, Baruffol, M, Bourland, N, Bruelheide, H, Daïnou, K, de Gouvenain, RC, Doucet, JL, Doust, S, Fine, PVA, Fortunel, C, Haase, J, Holl, KD, Jactel, H, Li, X, Kitajima, K, Koricheva, J, Martínez-Garza, C, Messier, C, Paquette, A, Philipson, C, Piotto, D, Poorter, L, Posada, JM, Potvin, C, Rainio, K, Russo, SE, Ruiz-Jaen, M, Scherer-Lorenzen, M, Webb, CO, Wright, SJ, Zahawi, RA, and Hector, A

Subjects
functional ecology, FunDivEurope, growth, hierarchical models, plant population and community dynamics, relative growth rate, size-standardized growth rate, TreeDivNet, Ecology, Environmental Sciences, Biological Sciences, Agricultural and Veterinary Sciences
Abstract

Plant functional traits, in particular specific leaf area (SLA), wood density and seed mass, are often good predictors of individual tree growth rates within communities. Individuals and species with high SLA, low wood density and small seeds tend to have faster growth rates. If community-level relationships between traits and growth have general predictive value, then similar relationships should also be observed in analyses that integrate across taxa, biogeographic regions and environments. Such global consistency would imply that traits could serve as valuable proxies for the complex suite of factors that determine growth rate, and, therefore, could underpin a new generation of robust dynamic vegetation models. Alternatively, growth rates may depend more strongly on the local environment or growth-trait relationships may vary along environmental gradients. We tested these alternative hypotheses using data on 27 352 juvenile trees, representing 278 species from 27 sites on all forested continents, and extensive functional trait data, 38% of which were obtained at the same sites at which growth was assessed. Data on potential evapotranspiration (PET), which summarizes the joint ecological effects of temperature and precipitation, were obtained from a global data base. We estimated size-standardized relative height growth rates (SGR) for all species, then related them to functional traits and PET using mixed-effect models for the fastest growing species and for all species together. Both the mean and 95th percentile SGR were more strongly associated with functional traits than with PET. PET was unrelated to SGR at the global scale. SGR increased with increasing SLA and decreased with increasing wood density and seed mass, but these traits explained only 3.1% of the variation in SGR. SGR-trait relationships were consistently weak across families and biogeographic zones, and over a range of tree statures. Thus, the most widely studied functional traits in plant ecology were poor predictors of tree growth over large scales. Synthesis. We conclude that these functional traits alone may be unsuitable for predicting growth of trees over broad scales. Determining the functional traits that predict vital rates under specific environmental conditions may generate more insight than a monolithic global relationship can offer. The most widely studied functional traits in plant ecology, specific leaf area, wood density and seed mass, were only weakly associated with tree growth rates over broad scales. Assessing trait-growth relationships under specific environmental conditions may generate more insight than a global relationship can offer.

Published
2015

7. Explore before you restore: Incorporating complex systems thinking in ecosystem restoration.

Author

Maes, S. L., Perring, M. P., Cohen, R., Akinnifesi, F. K., Bargués‐Tobella, A., Bastin, J.‐F., Bauters, M., Bernardino, P. N., Brancalion, P. H. S., Bullock, J. M., Ellison, D., Fayolle, A., Fremout, T., Gann, G. D., Hishe, H., Holmgren, M., Ilstedt, U., Mahy, G., Messier, C., and Parr, C. L.

Subjects
RESTORATION ecology, SYSTEMS theory, ECOLOGICAL resilience, POLICY sciences, ECOSYSTEMS, ECOLOGICAL regime shifts
Abstract

Copyright of Journal of Applied Ecology is the property of Wiley-Blackwell and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2024
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9. An Urban Forest Diversification Software to Improve Resilience to Global Change.

Author

St-Denis, A., Maure, F., Belbahar, R., Delagrange, S., Handa, T., Kneeshaw, D., Paquette, A., Nicol, M., Meurs, M. J., and Messier, C.

Subjects
DECISION support systems, URBAN trees, ARTIFICIAL intelligence, WEB design, SOFTWARE development tools
Abstract

Copyright of Arboriculture & Urban Forestry is the property of International Society of Arboriculture and its content may not be copied or emailed to multiple sites or posted to a listserv without the copyright holder's express written permission. However, users may print, download, or email articles for individual use. This abstract may be abridged. No warranty is given about the accuracy of the copy. Users should refer to the original published version of the material for the full abstract. (Copyright applies to all Abstracts.)

Published
2024
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12. Soil fungal communities contribute to the positive diversity–productivity relationship of tree communities under contrasting water availability.

Author

Fahey, C., Parker, W. C., Paquette, A., Messier, C., and Antunes, P. M.

Subjects
FOREST productivity, FUNGAL communities, WATER supply, STRUCTURAL equation modeling, PLANT diversity, SOIL productivity, SOIL microbiology
Abstract

Plant diversity has often been linked to increased productivity; however, this apparent diversity–productivity relationship may rely on intertrophic interactions such as those between plants and soil microbes. Soil fungi can create complementarity between plant species via altered plant resource partitioning, facilitation via fungal networks or biotic feedbacks, thereby promoting plant diversity–productivity relationships. Furthermore, these relationships are likely to be context dependent in response to resource availability.We used a biodiversity–ecosystem function experiment with trees exposed to high and low water availability treatments to determine the contribution of soil fungal communities to the diversity–productivity relationship in tree communities. We used amplicon sequencing of soil fungi to assess fungal richness, community composition and richness of functional guilds. We then applied structural equation modelling to determine relationships between tree diversity, fungal communities and tree productivity and the role of water availability in these relationships.Tree species richness and functional diversity both increased above‐ground tree productivity and influenced soil fungal community composition. Fungal community composition had a direct impact on tree productivity and enhanced net diversity effects on productivity. Therefore, fungal communities mediated a positive, indirect effect of tree richness on productivity. While total fungal richness was not associated with tree diversity, pathogen richness decreased and mycorrhizal richness increased with tree richness. Pathogen and mycorrhizal richness had either no impact or a weak negative effect on productivity. Tree species traits strongly affected fungal communities and these changes promoted productivity. Finally, water availability greatly influenced fungal communities but did not interact with tree diversity to affect productivity; indicating possible resilience of tree communities to altered precipitation regimes and associated changes in fungal communities.Synthesis: Our study highlights the crucial role that fungal communities play in shaping the relationship between tree diversity, traits and productivity, and resilience to altered water availability. [ABSTRACT FROM AUTHOR]

Published
2023
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14. Traits to stay, traits to move: a review of functional traits to assess sensitivity and adaptive capacity of temperate and boreal trees to climate change

Author

Aubin, I., Munson, A.D., Cardou, F., Burton, P.J., Isabel, N., Pedlar, J.H., Paquette, A., Taylor, A.R., Delagrange, S., Kebli, H., Messier, C., Shipley, B., Valladares, F., Kattge, J., Boisvert-Marsh, L., and McKenney, D.

Subjects
Multifactorial traits -- Analysis, Climate change -- Analysis, Taiga -- Environmental aspects, Environmental issues
Abstract

The integration of functional traits into vulnerability assessments is a promising approach to quantitatively capture differences in species sensitivity and adaptive capacity to climate change, allowing the refinement of tree species distribution models. In response to a clear need to identify traits that are responsive to climate change and applicable in a management context, we review the state of knowledge of the main mechanisms, and their associated traits, that underpin the ability of boreal and temperate tree species to persist and (or) shift their distribution in a changing climate. We aimed to determine whether current knowledge is sufficiently mature and available to be used effectively in vulnerability assessments. Marshalling recent conceptual advances and assessing data availability, our ultimate objective is to guide modellers and practitioners in finding and selecting sets of traits that can be used to capture differences in species' ability to persist and migrate. While the physiological mechanisms that determine sensitivity to climate change are relatively well understood (e.g., drought-induced cavitation), many associated traits have not been systematically documented for North American trees and differences in methodology preclude their widespread integration into vulnerability assessments (e.g., xylem recovery capacity). In contrast, traits traditionally associated with the ability to migrate and withstand fire are generally well documented, but new key traits are emerging in the context of climate change that have not been as well characterized (e.g., age of optimum seed production). More generally, lack of knowledge surrounding the extent and patterns in intraspecific trait variation, as well as co-variation and interaction among traits, limit our ability to use this approach to assess tree adaptive capacity. We conclude by outlining research needs and potential strategies for the development of trait-based knowledge applicable in large-scale modelling efforts, sketching out important aspects of trait data organization that should be part of a coordinated effort by the forest science community. Key words: vulnerability assessment, drought tolerance, fire tolerance, migration ability, intraspecific variation in trait, species persistence. L'utilisation des traits fonctionnels dans l'evaluation de la vulnerabilite est une approche prometteuse pour integrer de maniere quantifiable les differences de sensibilite des especes et leur capacite d'adaptation aux changements climatiques, ameliorant ainsi les modeles de repartition des arbres. Afin d'identifier dans un contexte d'amenagement les traits cles qui sont affectes par les changements climatiques, nous examinons l'etat des connaissances sur les principaux mecanismes - ainsi que leurs traits associes--qui regissent la capacite des arbres des forets boreales et temperees a persister ou a migrer. Nous avons tente de determiner si les connaissances actuelles sont suffisamment matures et disponibles pour etre utilisees efficacement dans le contexte des evaluations de vulnerabilite. En synthetisant les avancees conceptuelles les plus recentes et en evaluant la disponibilite des donnees, nous avons comme objectif principal de guider les modelisateurs et autres intervenants dans la selection de traits fonctionnels pouvant servir a caracteriser les differences dans la capacite des especes a persister et a migrer face a un climat en changement. Par exemple, malgre que l'on comprenne assez bien les mecanismes physiologiques qui determinent la sensibilite aux changements climatiques (ex., cavitation induite par la secheresse), un grand nombre de traits associes a ces mecanismes n'ont pas ete systematiquement documentes pour les arbres d'Amerique du Nord. Nous constatons egalement des differences dans les methodologies utilisees pour mesurer ces traits (ex., capacite de retablissement des xylemes), ce qui nuit a l'integration des traits dans l'evaluation de la vulnerabilite. Pour leur part, les traits traditionnellement associes a la capacite de migrer et de resister au feu sont generalement bien documentes; cependant, de nouveaux traits cles emergeant dans le contexte des changements climatiques demeurent peu documentes (ex., l'age de la production optimale de graines). De facon generale, le manque de connaissance entourant la variabilite intraspecifique des traits, ainsi que sur la covariation et l'interaction entre traits, est limitant dans nos evaluations de la capacite adaptative des arbres. Nous concluons en soulignant des besoins precis en matiere de recherche et en identifiant certaines avenues possibles pour le developpement des connaissances liees aux traits applicables dans des projets de modelisation a grande echelle. Nous soulignons finalement l'importance de certains aspects de la gestion de donnees de traits qui devraient faire partie de tout effort coordonne de documentation par la communaute scientifique du milieu forestier. Mots-cles : evaluation de la vulnerabilite, tolerance a la secheresse, tolerance au feu, capacite de migration, variabilite intraspecifique des traits, persistance de l'espece., 1. Introduction Recent years have seen a marked increase in efforts to assess potential effects of climate change on the distribution and abundance of forest plant species (Thuiller et al. [...]

Published
2016
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15. Using climate analogues and vulnerability metrics to inform urban tree species selection in a changing climate : The case for Canadian cities

Author

Esperon-Rodriguez, M., Ordoñez, C., van Doorn, N.S., Hirons, A., Messier, C., Esperon-Rodriguez, M., Ordoñez, C., van Doorn, N.S., Hirons, A., and Messier, C.

Abstract

Urban forests provide ecosystem services to more than 4.2 billion people living in cities; however, the provision of these services is threatened by climate change. Cities will experience novel, warmer climates that will impact tree species survival. Here, we present an empirical approach combining the use of climate analogues and vulnerability metrics to guide urban tree species selection. Climate analogues can be used to identify where the current climate in a given location is similar to the projected future climate of another location. Using vulnerability metrics, tree species in both locations can then be compared and species at risk of future climate change can be identified and substituted with species known to be resilient to climatic changes in the other location. Using Canadian cities as a case study, we show how our approach can become a useful tool to inform species selection and facilitate urban forest decision-making in response to climate change.

Published
2022

16. Disentangling drivers of litter decomposition in a multi-continent network of tree diversity experiments

Author

Desie, E., Zuo, J., Verheyen, K., Djukic, I., Van Meerbeek, K., Auge, Harald, Barsoum, N., Baum, C., Bruelheide, H., Eisenhauer, N., Feldhaar, H., Ferlian, O., Gravel, D., Jactel, H., Kappel Schmidt, I., Kepfer-Rojas, S., Meredieu, C., Mereu, S., Messier, C., Morillas, L., Nock, C., Paquette, A., Ponette, Q., Reich, P.B., Roales, J., Scherer-Lorenzen, M., Seitz, S., Schmidt, Anja, Stefanski, A., Trogisch, S., van Halder, I., Weih, M., Williams, L.J., Yang, B., Muys, B., Desie, E., Zuo, J., Verheyen, K., Djukic, I., Van Meerbeek, K., Auge, Harald, Barsoum, N., Baum, C., Bruelheide, H., Eisenhauer, N., Feldhaar, H., Ferlian, O., Gravel, D., Jactel, H., Kappel Schmidt, I., Kepfer-Rojas, S., Meredieu, C., Mereu, S., Messier, C., Morillas, L., Nock, C., Paquette, A., Ponette, Q., Reich, P.B., Roales, J., Scherer-Lorenzen, M., Seitz, S., Schmidt, Anja, Stefanski, A., Trogisch, S., van Halder, I., Weih, M., Williams, L.J., Yang, B., and Muys, B.

Abstract

Litter decomposition is a key ecosystem function in forests and varies in response to a range of climatic, edaphic, and local stand characteristics. Disentangling the relative contribution of these factors is challenging, especially along large environmental gradients. In particular, knowledge of the effect of management options, such as tree planting density and species composition, on litter decomposition would be highly valuable in forestry. In this study, we made use of 15 tree diversity experiments spread over eight countries and three continents within the global TreeDivNet network. We evaluated the effects of overstory composition (tree identity, species/mixture composition and species richness), plantation conditions (density and age), and climate (temperature and precipitation) on mass loss (after 3 months and 1 year) of two standardized litters: high-quality green tea and low-quality rooibos tea. Across continents, we found that early-stage decomposition of the low-quality rooibos tea was influenced locally by overstory tree identity. Mass loss of rooibos litter was higher under young gymnosperm overstories compared to angiosperm overstories, but this trend reversed with age of the experiment. Tree species richness did not influence decomposition and explained almost no variation in our multi-continent dataset. Hence, in the young plantations of our study, overstory composition effects on decomposition were mainly driven by tree species identity on decomposer communities and forest microclimates. After 12 months of incubation, mass loss of the high-quality green tea litter was mainly influenced by temperature whereas the low-quality rooibos tea litter decomposition showed stronger relationships with overstory composition and stand age. Our findings highlight that decomposition dynamics are not only affected by climate but also by management options, via litter quality of the identity of planted trees but also by overstory composition and structure.

Published
2022

17. Tree diversity effects on soil microbial biomass and respiration are context dependent across forest diversity experiments

Author

Cesarz, S., Craven, D., Auge, Harald, Bruelheide, H., Castagneyrol, B., Gutknecht, J., Hector, A., Jactel, H., Koricheva, J., Messier, C., Muys, B., O’Brien, M.J., Paquette, A., Ponette, Q., Potvin, C., Reich, P.B., Scherer-Lorenzen, M., Smith, A.R., Verheyen, K., Eisenhauer, N., Cesarz, S., Craven, D., Auge, Harald, Bruelheide, H., Castagneyrol, B., Gutknecht, J., Hector, A., Jactel, H., Koricheva, J., Messier, C., Muys, B., O’Brien, M.J., Paquette, A., Ponette, Q., Potvin, C., Reich, P.B., Scherer-Lorenzen, M., Smith, A.R., Verheyen, K., and Eisenhauer, N.

Abstract

Aim Soil microorganisms are essential for the functioning of terrestrial ecosystems. Although soil microbial communities and functions are linked to tree species composition and diversity, there has been no comprehensive study of the generality or context dependence of these relationships. Here, we examine tree diversity–soil microbial biomass and respiration relationships across environmental gradients using a global network of tree diversity experiments. Location Boreal, temperate, subtropical and tropical forests. Time period 2013. Major taxa studied Soil microorganisms. Methods Soil samples collected from 11 tree diversity experiments were used to measure microbial respiration, biomass and respiratory quotient using the substrate-induced respiration method. All samples were measured using the same analytical device, method and procedure to reduce measurement bias. We used linear mixed-effects models and principal components analysis (PCA) to examine the effects of tree diversity (taxonomic and phylogenetic), environmental conditions and interactions on soil microbial properties. Results Abiotic drivers, mainly soil water content, but also soil carbon and soil pH, significantly increased soil microbial biomass and respiration. High soil water content reduced the importance of other abiotic drivers. Tree diversity had no effect on the soil microbial properties, but interactions with phylogenetic diversity indicated that the effects of diversity were context dependent and stronger in drier soils. Similar results were found for soil carbon and soil pH. Main conclusions Our results indicate the importance of abiotic variables, especially soil water content, for maintaining high levels of soil microbial functions and modulating the effects of other environmental drivers. Planting tree species with diverse water-use strategies and structurally complex canopies and high leaf area might be crucial for maintaining high soil microbial biomass and respiration. Give

Published
2022

20. For the sake of resilience and multifunctionality, let’s diversify planted forests!

Author

Messier, C, Bauhaus, J, Sousa-Silva, R, Hector, A, and al., Et

Abstract

As of 2020, the world has an estimated 290 million hectares of planted forests and this number is continuously increasing. Plantations composed mainly of one tree species under intensive management contribute 131 million hectares to these planted forests. Although monospecific plantations are important in providing timber, they harbour less biodiversity and are potentially more susceptible to disturbances than natural or diverse planted forests. Here, we point out the increasing scientific evidence for increased resilience and ecosystem service provision of functionally- and species-diverse planted forests (hereafter referred to as diverse planted forests) compared to monospecific plantations. Furthermore, we propose five concrete steps to foster the adoption of diverse planted forests: (1) improve awareness of benefits and practical options of diverse planted forests among land-owners, managers, and investors; (2) incentivize tree species diversity in public funding of afforestation and programs to diversify current maladapted plantations; (3) develop new wood-based products that can be derived from many different tree species; (4) invest in research to assess landscape benefits of diverse planted forests for functional connectivity and resilience to global-change threats; and (5) improve the evidence base on diverse planted forests, in particular in currently underrepresented regions, where new options could be tested.

Published
2021

22. For the sake of resilience and multifunctionality, let's diversify planted forests!

Author

Messier, C., Bauhus, J., Sousa-Silva, R., Auge, Harald, Baeten, L., Barsoum, N., Bruelheide, H., Caldwell, B., Cavender-Bares, J., Dhiedt, E., Eisenhauer, N., Ganade, G., Gravel, D., Guillemot, J., Hall, J.S., Hector, A., Hérault, B., Jactel, H., Koricheva, J., Kreft, H., Mereu, S., Muys, B., Nock, C.A., Paquette, A., Parker, J.D., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Scherer-Lorenzen, M., Schnabel, F., Verheyen, K., Weih, M., Wollni, M., Zemp, D.C., Messier, C., Bauhus, J., Sousa-Silva, R., Auge, Harald, Baeten, L., Barsoum, N., Bruelheide, H., Caldwell, B., Cavender-Bares, J., Dhiedt, E., Eisenhauer, N., Ganade, G., Gravel, D., Guillemot, J., Hall, J.S., Hector, A., Hérault, B., Jactel, H., Koricheva, J., Kreft, H., Mereu, S., Muys, B., Nock, C.A., Paquette, A., Parker, J.D., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Scherer-Lorenzen, M., Schnabel, F., Verheyen, K., Weih, M., Wollni, M., and Zemp, D.C.

Abstract

As of 2020, the world has an estimated 290 million ha of planted forests and this number is continuously increasing. Of these, 131 million ha are monospecific planted forests under intensive management. Although monospecific planted forests are important in providing timber, they harbor less biodiversity and are potentially more susceptible to disturbances than natural or diverse planted forests. Here, we point out the increasing scientific evidence for increased resilience and ecosystem service provision of functionally and species diverse planted forests (hereafter referred to as diverse planted forests) compared to monospecific ones. Furthermore, we propose five concrete steps to foster the adoption of diverse planted forests: (1) improve awareness of benefits and practical options of diverse planted forests among land-owners, managers, and investors; (2) incentivize tree species diversity in public funding of afforestation and programs to diversify current maladapted planted forests of low diversity; (3) develop new wood-based products that can be derived from many different tree species not yet in use; (4) invest in research to assess landscape benefits of diverse planted forests for functional connectivity and resilience to global-change threats; and (5) improve the evidence base on diverse planted forests, in particular in currently under-represented regions, where new options could be tested.   &nbsp

Published
2021

39. Utility of the Hebb–Williams maze paradigm for translational research in Fragile X syndrome: A direct comparison of mice and humans

Author

Boutet, I. (Isabelle), Collin, C.A. (Charles A.), Macleod, L.S. (Lindsey S.), Messier, C. (Claude), Holahan, M.R. (Matthew R.), Berry-Kravis, E. (Elizabeth), Gandhi, R.M. (Reno M.), Kogan, C.S. (Cary S.), Boutet, I. (Isabelle), Collin, C.A. (Charles A.), Macleod, L.S. (Lindsey S.), Messier, C. (Claude), Holahan, M.R. (Matthew R.), Berry-Kravis, E. (Elizabeth), Gandhi, R.M. (Reno M.), and Kogan, C.S. (Cary S.)

Abstract

To generate meaningful information, translational research must employ paradigms that allow extrapolation from animal models to humans. However, few studies have evaluated translational paradigms on the basis of defined validation criteria. We outline three criteria for validating translational paradigms. We then evaluate the Hebb–Williams maze paradigm (Hebb and Williams, 1946; Rabinovitch and Rosvold, 1951) on the basis of these criteria using Fragile X syndrome (FXS) as model disease. We focused

Published
2018
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40. A million and more trees for science

Author

Paquette, A., Hector, A., Vanhellemont, M., Koricheva, J., Scherer-Lorenzen, M., Verheyen, K., Abdala-Roberts, L., Auge, H., Barsoum, N., Bauhus, J., Baum, C., Bruelheide, H., Castagneyrol, B., Cavender-Bares, J., Eisenhauer, N., Ferlian, O., Ganade, G., Godbold, D., Gravel, D., Hall, J., Hobbs, R., Hoelscher, D., Hulvey, K.B., Huxham, M., Jactel, H., Kreft, H., Liang, J., Mereu, S., Messier, C., Montgomery, R., Muys, B., Nock, C., Parker, J., Parker, W., Parra-Tabla, V., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rewald, B., Sanden, H., Smith, A., Standish, R., Weih, M., Wollni, M., Zemp, D.C., Paquette, A., Hector, A., Vanhellemont, M., Koricheva, J., Scherer-Lorenzen, M., Verheyen, K., Abdala-Roberts, L., Auge, H., Barsoum, N., Bauhus, J., Baum, C., Bruelheide, H., Castagneyrol, B., Cavender-Bares, J., Eisenhauer, N., Ferlian, O., Ganade, G., Godbold, D., Gravel, D., Hall, J., Hobbs, R., Hoelscher, D., Hulvey, K.B., Huxham, M., Jactel, H., Kreft, H., Liang, J., Mereu, S., Messier, C., Montgomery, R., Muys, B., Nock, C., Parker, J., Parker, W., Parra-Tabla, V., Perring, M.P., Ponette, Q., Potvin, C., Reich, P.B., Rewald, B., Sanden, H., Smith, A., Standish, R., Weih, M., Wollni, M., and Zemp, D.C.

Abstract

TreeDivNet is the largest network of biodiversity experiments worldwide, but needs to expand. We encourage colleagues to establish new experiments on the relation between tree species diversity and forest ecosystem functioning, and to make use of the platform for collaborative research.

Published
2018

42. Dealing with non-linearity and uncertainty in forest management

Author

Messier, C., Puettmann, K.J., Filotas, E., Coates, K.D., Messier, C., Puettmann, K.J., Filotas, E., and Coates, K.D.

Abstract

Forest managers today are struggling with the great uncertainties and rapid changes in many biophysical and socioeconomic aspects of their work. We argue in this review that viewing forests and forest management as complex adaptive systems and acknowledging non-linearity and uncertainty in forest dynamics and management provide an alternative for both production- and conservation-oriented forests to the traditional command and control approaches that have been advocated so far in forestry.We first discuss the concepts of nonlinearity and uncertainty in forest dynamics and management. We then propose a set of broad principles and approaches that are required for forest managers to better incorporate these new concepts into practices. These span from (1) relaxing and expanding the sustained-yield and single-good paradigm, (2) moving the target for assessing success in silviculture from predetermined strict outcomes for each and every stand to an envelope of possible outcomes that are acceptable for one or multiple stands, and (3) using approaches and modeling tools to assess as large a range of possible outcomes as possible instead of the traditional mainly deterministic and static modeling tools.

Published
2016

43. A methodological framework for quantification and valuation of ecosystem services of tree-based intercropping systems

Author

Olivier, A., Alam, M., Paquette, A., Dupras, J., Revéret, J.-P., and Messier, C.

Subjects
alley cropping, agroforestry
Abstract

Presentation Alley cropping, also known as tree-based intercropping (TBI), holds a great potential in providing, in agricultural landscapes, a number of ecosystem services such as reduction of nutrient leaching, enhancement of soil nutrient status, increase of soil microbial biomass and diversity, biological pest control and global climate regulation. We developed and tested a framework for biophysical quantification and economic valuation of several such ecosystem services through a case study in southern Québec, Canada. We used a range of mathematical models for quantification of the services and valued them in economic terms. In some instances, we used existing models and equations, but in most instances we developed new ones to meet study objectives. We have found that the economic value of ecosystem services ranged from as low as 24 $ ha-1y-1 for pollination to as high as 785 $ ha-1y-1 for agricultural products. Water quality regulation ranked highest among the non-market services, followed by air quality regulation and carbon sequestration. The total potential value of TBI ecosystem services was estimated to be 5 billion dollars a year, if the system was implemented in 20 % of Québec’s 1,93 M ha croplands. The study suggests that incentives are needed to interest farmers in adopting TBI systems that benefit society as a whole.

Published
2014

44. Diversity increases carbon storage and tree productivity in Spanish forests

Author

Ruiz Benito, Paloma, Paquette , A., Gómez-Aparicio, Lorena, Messier , C., Kattge, Jens, Zavala Gironés, Miguel Ángel de, and Universidad de Alcalá. Departamento de Ciencias de la Vida

Subjects
Ecosystem functions and services, Diversity, Maximum likelihood techniques, Competition, Continental Spain, Forest management, Climate, Ecosystem functions and service, National forest inventory, Functional identity, Functional diversity, Community-weighted means of trait value
Abstract

Aim Biodiversity loss could reduce primary productivity and the carbon storage provided by forests; however, the mechanisms underpinning the effects of biodiversity on multiple ecosystem functions are not completely understood. Spanish forests are of particular interest because of the broad variation in environmental conditions and management history. We tested for the existence of a relationship between diversity effects and both carbon storage and tree productivity, and examined the relative importance of complementarity and selection mechanisms in a wide variety of forests, from cold deciduous Atlantic to xeric Mediterranean evergreen forests. Location Continental Spain. Methods We used c. 54,000 plots of the Spanish Forest Inventory and maximum likelihood techniques to quantify how climate, stand structure and diversity shape carbon storage and tree productivity. Diversity effects included both complementarity and selection mechanisms, measured respectively through functional diversity and functional identity measures. Results Diversity had a significant effect on both carbon storage and tree productivity, even when controlling for confounding factors of climate and stand structure. A consistent positive effect of functional diversity on carbon storage and tree productivity was observed in all seven forest types studied. This relationship was not linear, and the largest changes in carbon storage and tree productivity were observed at low levels of functional diversity. However, the importance of complementarity effects was not consistent with the productivity of different forest types. Selection effects were particularly important in deciduous and Mediterranean pine forests, but had very little effect on mountain pines. Main conclusions We found a generally positive effect of diversity on carbon storage and tree productivity, supported by both complementarity and selection mechanisms. Thus, both functionally diverse forests and functionally important species should be maintained to adequately preserve and promote key ecosystem functions such as carbon storage and tree productivity., This research was initially supported by INTERBOS3-CGL2008-04503-C03-03 and SUM2008-00004-C03-01 projects, and by FUNDIV (ENV.2010.2.1.4-1) at a later stage. PRB was supported by a FPU fellowship (AP2008-01325). The study has been supported by the TRY initiative on plant traits (http://www.trydb.org). The TRY initiative and database is hosted, developed and maintained by J. Kattge and G. Bönisch (Max-Planck-Institute for Biogeochemistry, Jena, Germany). TRY is supported by DIVERSITAS, IGBP, the Global Land Project, the UK Natural Environment Research Council (NERC) through its program QUEST (Quantifying and Understanding the Earth System), the French Fondation pour la Recherche sur la Biodiversité (FRB) and GIS "Climat Environnement et Société" France.

Published
2014

45. Maximizing conservation and production with intensive forest management: It’s all about location

Author

Tittler, R., Filotas, E., Kroese, J., Messier, C., Tittler, R., Filotas, E., Kroese, J., and Messier, C.

Abstract

Functional zoning has been suggested as a way to balance the needs of a viable forest industry with those of healthy ecosystems. Under this system, part of the forest is set aside for protected areas, counterbalanced by intensive and extensive management of the rest of the forest. Studies indicate this may provide adequate timber while minimizing road construction and favoring the development of large mature and old stands. However, it is unclear how the spatial arrangement of intensive management areas may affect the success of this zoning. Should these areas be agglomerated or dispersed throughout the forest landscape? Should managers prioritize (a) proximity to existing roads, (b) distance from protected areas, or (c) site specific productivity? We use a spatially explicit landscape simulation model to examine the effects of different spatial scenarios on landscape structure, connectivity for native forest wildlife, stand diversity, harvest volume, and road construction: (1) random placement of intensive management areas, and (2–8) all possible combinations of rules (a)–(c). Results favor the agglomeration of intensive management areas. For most wildlife species, connectivity was the highest when intensive management was far from the protected areas. This scenario also resulted in relatively high harvest volumes. Maximizing distance of intensive management areas from protected areas may therefore be the best way to maximize the benefits of intensive management areas while minimizing their potentially negative effects on forest structure and biodiversity.

Published
2015

46. From management to stewardship: Viewing forests as complex adaptive systems in an uncertain world

Author

Messier, C., Puettmann, K.J., Chazdon, R.L., Andersson, K.P., Angers, V.A., Brotons, L., Filotas, E., Tittler, R., Parrott, L., Levin, S.A., Messier, C., Puettmann, K.J., Chazdon, R.L., Andersson, K.P., Angers, V.A., Brotons, L., Filotas, E., Tittler, R., Parrott, L., and Levin, S.A.

Abstract

The world's forests and forestry sector are facing unprecedented biological, political, social, and climatic challenges. The development of appropriate, novel forest management and restoration approaches that adequately consider uncertainty and adaptability are hampered by a continuing focus on production of a few goods or objectives, strong control of forest structure and composition, and most importantly the absence of a global scientific framework and long-term vision. Ecosystem-based approaches represent a step in the right direction, but are limited in their ability to deal with the rapid pace of social, climatic, and environmental changes. We argue here that viewing forest ecosystems as complex adaptive system provides a better alternative for both production- and conservation-oriented forests and forestry. We propose a set of broad principles and changes to increase the adaptive capacity of forests in the face of future uncertainties. These span from expanding the sustained-yield, single-good paradigm to developing policy incentives and interventions that promote self-organization and integrated social-ecological adaptation.

Published
2015

47. Contributions of a global network of tree diversity experiments to sustainable forest plantations

Author

Verheyen, K., Vanhellemont, M., Auge, Harald, Baeten, L., Baraloto, C., Barsoum, N., Bilodeau-Gauthier, S., Bruelheide, H., Castagneyrol, B., Godbold, D., Haase, J., Hector, A., Jactel, H., Koricheva, J., Loreau, M., Mereu, S., Messier, C., Muys, B., Nolet, P., Paquette, A., Parker, J., Perring, M., Ponette, Q., Potvin, C., Reich, P., Smith, A., Weih, M., Scherer-Lorenzen, M., Verheyen, K., Vanhellemont, M., Auge, Harald, Baeten, L., Baraloto, C., Barsoum, N., Bilodeau-Gauthier, S., Bruelheide, H., Castagneyrol, B., Godbold, D., Haase, J., Hector, A., Jactel, H., Koricheva, J., Loreau, M., Mereu, S., Messier, C., Muys, B., Nolet, P., Paquette, A., Parker, J., Perring, M., Ponette, Q., Potvin, C., Reich, P., Smith, A., Weih, M., and Scherer-Lorenzen, M.

Abstract

The area of forest plantations is increasing worldwide helping to meet timber demand and protect natural forests. However, with global change, monospecific plantations are increasingly vulnerable to abiotic and biotic disturbances. As an adaption measure we need to move to plantations that are more diverse in genotypes, species, and structure, with a design underpinned by science. TreeDivNet, a global network of tree diversity experiments, responds to this need by assessing the advantages and disadvantages of mixed species plantations. The network currently consists of 18 experiments, distributed over 36 sites and five ecoregions. With plantations 1–15 years old, TreeDivNet can already provide relevant data for forest policy and management. In this paper, we highlight some early results on the carbon sequestration and pest resistance potential of more diverse plantations. Finally, suggestions are made for new, innovative experiments in understudied regions to complement the existing network.

Published
2015

48. Globally, functional traits are weak predictors of juvenile tree growth, and we do not know why

Author

Paine, C.E.T., Amissah, L., Auge, Harald, Baraloto, C., Baruffol, M., Bourland, N., Bruelheide, H., Dainou, K., de Gouvenain, R.C., Doucet, J.-L., Doust, S., Fine, P.V.A., Fortunel, C., Haase, J., Holl, K.D., Jactel, H., Li, X., Kitajima, K., Koricheva, J., Martínez-Garza, C., Messier, C., Paquette, A., Philipson, C., Piotto, D., Poorter, L., Posada, J.M., Potvin, C., Rainio, K., Russo, S.E., Ruiz-Jaen, M., Scherer-Lorenzen, M., Webb, C.O., Wright, S.J., Zahawi, R.A., Hector, A., Paine, C.E.T., Amissah, L., Auge, Harald, Baraloto, C., Baruffol, M., Bourland, N., Bruelheide, H., Dainou, K., de Gouvenain, R.C., Doucet, J.-L., Doust, S., Fine, P.V.A., Fortunel, C., Haase, J., Holl, K.D., Jactel, H., Li, X., Kitajima, K., Koricheva, J., Martínez-Garza, C., Messier, C., Paquette, A., Philipson, C., Piotto, D., Poorter, L., Posada, J.M., Potvin, C., Rainio, K., Russo, S.E., Ruiz-Jaen, M., Scherer-Lorenzen, M., Webb, C.O., Wright, S.J., Zahawi, R.A., and Hector, A.

Abstract

Plant functional traits, in particular specific leaf area (SLA), wood density and seed mass, are often good predictors of individual tree growth rates within communities. Individuals and species with high SLA, low wood density and small seeds tend to have faster growth rates.If community-level relationships between traits and growth have general predictive value, then similar relationships should also be observed in analyses that integrate across taxa, biogeographic regions and environments. Such global consistency would imply that traits could serve as valuable proxies for the complex suite of factors that determine growth rate, and, therefore, could underpin a new generation of robust dynamic vegetation models. Alternatively, growth rates may depend more strongly on the local environment or growth–trait relationships may vary along environmental gradients.We tested these alternative hypotheses using data on 27 352 juvenile trees, representing 278 species from 27 sites on all forested continents, and extensive functional trait data, 38% of which were obtained at the same sites at which growth was assessed. Data on potential evapotranspiration (PET), which summarizes the joint ecological effects of temperature and precipitation, were obtained from a global data base.We estimated size-standardized relative height growth rates (SGR) for all species, then related them to functional traits and PET using mixed-effect models for the fastest growing species and for all species together.Both the mean and 95th percentile SGR were more strongly associated with functional traits than with PET. PET was unrelated to SGR at the global scale. SGR increased with increasing SLA and decreased with increasing wood density and seed mass, but these traits explained only 3.1% of the variation in SGR. SGR–trait relationships were consistently weak across families and biogeographic zones, and over a range of tree statures. Thus, the most widely studied functional traits in plant e

Published
2015

49. A major shift to the retention approach for forestry can help resolve some global forest sustainability issues

Author

Lindenmayer, D.B., Franklin, J.F., Lõhmus, A., Baker, S.C., Bauhus, J., Beese, W., Brodie, A., Kiehl, B., Kouki, J., Martínez Pastur, Guillermo José, Messier, C., Neyland, M., Palik, B., Sverdrup Thygeson, A., Volney, J., Wayne, A., and Gustafsson, L.

Subjects
ECOLOGICAL FORESTRY, FOREST BIODIVERSITY CONSERVATION, CIENCIAS AGRÍCOLAS, purl.org/becyt/ford/4.1 [https], ECOLOGICALLY SUSTAINABLE FOREST MANAGEMENT, Silvicultura, ALTERED FOREST POLICY, ALTERED LOGGING PRACTICES, Agricultura, Silvicultura y Pesca, purl.org/becyt/ford/4 [https], FOREST ECOSYSTEM PROCESSES
Abstract

Approximately 85% of the global forest estate is neither formally protected nor in areas dedicated to intensive wood production (e.g., plantations). Given the spatial extent of unprotected forests, finding management approaches that will sustain their multiple environmental, economic, and cultural values and prevent their conversion to other uses is imperative. The major global challenge of native forest management is further demonstrated by ongoing steep declines in forest biodiversity and carbon stocks. Here, we suggest that an essential part of such management—supplementing the protection of large reserves and sensitive areas within forest landscapes (e.g., aquatic features)—is the adoption of the retention approach in forests where logging occurs. This ecological approach to harvesting provides for permanent retention of important selected structures (e.g., trees and decayed logs) to provide for continuity of ecosystem structure, function, and species composition in the postharvest forest. The retention approach supports the integration of environmental, economic, and cultural values and is broadly applicable to tropical, temperate, and boreal forests, adaptable to different management objectives, and appropriate in different societal settings. The widespread adoption of the retention approach would be one of the most significant changes in management practice since the onset of modern high-yield forestry. Fil: Lindenmayer, D.B.. The Australian National University,; Australia Fil: Franklin, J.F.. University of Washington; Estados Unidos Fil: Lõhmus, A.. University of Tartu; Estonia Fil: Baker, S.C.. University of Tasmania; Australia Fil: Bauhus, J.. Albert Ludwigs University of Freiburg; Alemania Fil: Beese, W.. University of Vancouver; Canadá Fil: Brodie, A.. No especifíca; Fil: Kiehl, B.. Swedish University of Agricultural Sciences; Suecia Fil: Kouki, J.. University of Eastern Finland; Finlandia Fil: Martínez Pastur, Guillermo José. Consejo Nacional de Investigaciones Científicas y Técnicas. Centro Austral de Investigaciones Científicas; Argentina Fil: Messier, C.. Université du Québec a Montreal; Canadá Fil: Neyland, M.. University of Tasmania; Australia Fil: Palik, B.. No especifíca; Fil: Sverdrup Thygeson, A.. Norwegian University of Life Sciences; Noruega Fil: Volney, J.. Canadian Forest Service; Canadá Fil: Wayne, A.. No especifíca; Fil: Gustafsson, L.. Swedish University of Agricultural Sciences; Suecia

Published
2012

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