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The Ecological and Societal Consequences of Biodiversity Loss. (2022)

Loreau, Michel.

Newark :John Wiley & Sons, Incorporated,

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Keywords: Biodiversity. ; Electronic books.

Type of Medium: Online Resource

Pages: 1 online resource (382 pages)

Edition: 1st ed.

ISBN: 9781119902904

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=6887268

DDC: 333.95

Language: English

Note: Cover -- Half-Title Page -- Title Page -- Copyright Page -- Contents -- Introduction. The Ecological and Societal Consequences of Biodiversity Loss -- Part 1. Biodiversity and Ecosystems: An Overview -- Chapter 1. Biodiversity Change: Past, Present, and Future -- 1.1. Setting the stage: difficulties of documenting, understanding, and communicating biodiversity change -- 1.2. Biodiversity change in Earth history -- 1.3. Pre-industrial biodiversity change -- 1.4. Biodiversity change in the "Anthropocene" -- 1.5. Future of biodiversity change -- 1.6. Future of biodiversity change research -- 1.7. Acknowledgements -- 1.8. References -- Chapter 2. Biodiversity: Concepts, Dimensions, and Measures -- 2.1. Introduction -- 2.2. Progress in measuring taxonomic diversity -- 2.3. Taxonomic diversity and evenness measures -- 2.3.1. Taxonomic diversity: effective number of species -- 2.3.2. Evenness measures -- 2.4. A unified framework integrating diversities (TD, PD, and FD) -- 2.4.1. Phylogenetic diversity as a special case of attribute diversity -- 2.4.2. Functional diversity as a special case of attribute diversity -- 2.5. Diversity in space and time -- 2.6. Examples -- 2.6.1. Coral data -- 2.6.2. Saproxylic beetle data -- 2.7. Conclusion -- 2.8. Acknowledgements -- 2.9. References -- Chapter 3. Ecosystems: An Overview -- 3.1. An introduction to ecosystems -- 3.1.1. Ecosystem extent: abiotic factors in terrestrial systems -- 3.1.2. Ecosystem extent: biotic factors -- 3.1.3. Major ecosystem types -- 3.1.4. Meta-ecosystems -- 3.1.5. Ecosystem dynamics and change over time and space -- 3.2. Ecosystem functioning -- 3.3. Ecosystem stability -- 3.4. Ecosystem services -- 3.5. Human alterations to ecosystems -- 3.6. References -- Part 2. How Biodiversity Affects Ecosystem Functioning -- Chapter 4. Biodiversity and Ecosystem Functioning: Theoretical Foundations. , 4.1. Introduction -- 4.2. Biodiversity: from causes to consequences -- 4.3. Why does biodiversity promote ecosystem functioning? -- 4.4. Trophic diversity and ecosystem functioning -- 4.5. BEF over time and space -- 4.6. Conclusion -- 4.7. Acknowledgements -- 4.8. References -- Chapter 5. Experimental Evidence for How Biodiversity Affects Ecosystem Functioning -- 5.1. The role of experiments -- 5.1.1. The experiment that launched a thousand experiments -- 5.1.2. How do we gain knowledge from experiments? -- 5.2. BEF experiments as tests of theory -- 5.2.1. Diversity as a driver of change in ecosystem function -- 5.2.2. Evidence for selection and complementarity -- 5.2.3. Experimental evidence for key assumptions of BEF theory -- 5.2.4. Testing for diversity effects under broader abiotic and biotic conditions -- 5.2.5. Diversity effects in space and time -- 5.3. Experiments that extend classic theory -- 5.3.1. Does extinction order matter? -- 5.3.2. Experiments that bridge BEF and modern coexistence theory (MCT) -- 5.3.3. Experimental evidence for effects of biodiversity on ecosystem services -- 5.4. Conclusion -- 5.5. References -- Chapter 6. Biodiversity and Ecosystem Functioning in Observational Analyses -- 6.1. Introduction -- 6.2. A historical perspective: returning to observational data -- 6.3. Benefits of observational data -- 6.4. The challenge of causal inference in observational studies -- 6.5. Observational studies: results and evidence to date -- 6.5.1. Across dimensions of biodiversity -- 6.5.2. Across ecosystem functions -- 6.5.3. Across ecosystem types -- 6.5.4. Summary of current evidence gaps -- 6.6. Reviewing study design to date: how are studies analyzing observational data? -- 6.6.1. Moving forward: improving study designs for observational data and analyses -- 6.7. Future directions -- 6.8. Conclusion -- 6.9. References. , Part 3. How Biodiversity Affects Ecosystem Stability -- Chapter 7. Biodiversity and Ecosystem Stability: New Theoretical Insights -- 7.1. Introduction -- 7.2. What is stability? -- 7.3. Why does local biodiversity promote ecosystem stability? -- 7.4. Scaling up diversity-stability relationships -- 7.5. Conclusion -- 7.6. Acknowledgements -- 7.7. References -- Chapter 8. What Do Biodiversity Experiments Tell Us About Biodiversity and Ecological Stability Relationships? -- 8.1. Introduction -- 8.2. Insight from models -- 8.3. A brief account of earlier diversity-stability experiments -- 8.4. The relationships between biodiversity and temporal stability -- 8.4.1. Grassland biodiversity experiments -- 8.4.2. Forest biodiversity experiments -- 8.4.3. Aquatic biodiversity experiments -- 8.4.4. Microbial biodiversity experiments -- 8.4.5. How general are the effects of species diversity on temporal stability? -- 8.4.6. Other dimensions of biodiversity -- 8.5. The relationships between biodiversity and resistance/resilience -- 8.6. The relevance of biodiversity experiments to real-world ecosystems -- 8.7. Conclusion -- 8.8. Acknowledgements -- 8.9. References -- Chapter 9. Biodiversity and Temporal Stability of Naturally Assembled Ecosystems Across Spatial Scales in a Changing World -- 9.1. Introduction -- 9.2. Biodiversity-stability relationships along natural gradients -- 9.3. Global change drivers and biodiversity-stability relationships -- 9.4. Contribution of dominant and rare species to stability -- 9.5. Future directions -- 9.6. References -- Part 4. How Biodiversity Affects Human Societies -- Chapter 10. Biodiversity and Ecosystem Services in Managed Ecosystems -- 10.1. A brief history of the role of biodiversity in managed ecosystems -- 10.2. Biodiversity as the basis for a new green revolution -- 10.3. Biodiversity in agriculture. , 10.3.1. Crop genetic diversity -- 10.3.2. Species diversity in grasslands and intercropping -- 10.3.3. Farm-scale diversity -- 10.4. Biodiversity in forestry -- 10.4.1. Evidence for positive biodiversity effects on forest ecosystem services -- 10.4.2. Ecosystem services provided by agroforestry -- 10.5. Outlook -- 10.5.1. Potential of biodiversity to support the next green revolution -- 10.5.2. Obstacles -- 10.5.3. Solutions -- 10.6. Acknowledgements -- 10.7. References -- Chapter 11. Biodiversity and Human Health: On the Necessity of Combining Ecology and Public Health -- 11.1. Introduction -- 11.2. Microbial biodiversity is a key component of ecosystems -- 11.3. The linkages between biodiversity and human infectious diseases -- 11.4. The evolution of human society is punctuated by epidemiological phases -- 11.5. The new ecology and evolution of zoonotic and sapronotic establishment in the Anthropocene -- 11.6. The process of globalization of human infectious diseases -- 11.7. A livestock-dominated planet -- 11.8. Conclusion -- 11.9. Acknowledgements -- 11.10. References -- Chapter 12. Economic Valuation of Biodiversity and Ecosystem Services -- 12.1. Introduction -- 12.2. What valuation is and is not -- 12.3. Non-market economic valuation methods -- 12.3.1. Production function methods -- 12.3.2. Revealed preference methods -- 12.3.3. Stated preference methods -- 12.3.4. Benefit transfer methods -- 12.4. Conclusion -- 12.5. References -- Part 5. Zooming Out: Biodiversity in a Changing Planet -- Chapter 13. Feedbacks Between Biodiversity and Climate Change -- 13.1. Introduction -- 13.2. Vulnerability and responses of biodiversity and ecosystem functioning to the changing climate in different biomes -- 13.3. Societal and political challenges to these twin crises and their interlinkages. , 13.4. The potential of biodiversity to cope with the changing climate -- 13.5. Conclusion -- 13.6. Acknowledgements -- 13.7. References -- Chapter 14. Feedbacks Between Biodiversity and Society -- 14.1. Introduction -- 14.2. Society's impact on biodiversity -- 14.2.1. Agriculture -- 14.2.2. Income -- 14.3. How societies view biodiversity -- 14.3.1. Biodiversity and culture -- 14.3.2. Biodiversity and well-being -- 14.3.3. Value of biodiversity -- 14.4. Biodiversity policy and society -- 14.4.1. Awareness and perception -- 14.4.2. Management strategies -- 14.4.3. Conflicts in biodiversity management -- 14.4.4. Successful initiatives -- 14.5. Conclusion -- 14.6. Acknowledgements -- 14.7. References -- Chapter 15. Protecting and Restoring Biodiversity and Ecosystem Services -- 15.1. Introduction -- 15.2. Protecting biodiversity and ecosystems -- 15.2.1. What are protected areas and what are they intended to protect? -- 15.2.2. What global targets have been established for protected areas? -- 15.2.3. Where are protected areas and how effective are they? -- 15.2.4. Does protecting biodiversity also protect ecosystem services? -- 15.2.5. What are the limitations of protected areas? -- 15.3. Restoring biodiversity and ecosystems by reversing degradation -- 15.3.1. What is restoration and why is it needed? -- 15.3.2. What global targets have been established for restoration? -- 15.3.3. How extensive and effective is restoration? -- 15.3.4. Increasing the diversity of restorations can increase their efficacy -- 15.3.5. What are the limitations of restoration? -- 15.4. Looking ahead -- 15.5. Conclusion -- 15.6. Acknowledgements -- 15.7. References -- List of Authors -- Index -- EULA.

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A multitrophic perspective on biodiversity–ecosystem functioning research (2019)

Eisenhauer, Nico ; Schielzeth, Holger ; Barnes, Andrew D. ; [et al.]

ELSEVIER ACADEMIC PRESS INC

In: EPIC3Advances in Ecological Research, ELSEVIER ACADEMIC PRESS INC, 61, pp. 1-54, ISSN: 0065-2504

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Publication Date: 2020-10-07

Description: Concern about the functional consequences of unprecedented loss in biodiversity has prompted biodiversity–ecosystem functioning (BEF) research to become one of the most active fields of ecological research in the past 25 years. Hundreds of experiments have manipulated biodiversity as an independent variable and found compelling support that the functioning of ecosystems increases with the diversity of their ecological communities. This research has also identified some of the mechanisms underlying BEF relationships, some context-dependencies of the strength of relationships, as well as implications for various ecosystem services that humankind depends upon. In this chapter, we argue that a multitrophic perspective of biotic interactions in random and non-random biodiversity change scenarios is key to advance future BEF research and to address some of its most important remaining challenges. We discuss that the study and the quantification of multitrophic interactions in space and time facilitates scaling up from small-scale biodiversity manipulations and ecosystem function assessments to management-relevant spatial scales across ecosystem boundaries. We specifically consider multitrophic conceptual frameworks to understand and predict the context-dependency of BEF relationships. Moreover, we highlight the importance of the eco-evolutionary underpinnings of multitrophic BEF relationships. We outline that FAIR data (meeting the standards of findability, accessibility, interoperability, and reusability) and reproducible processing will be key to advance this field of research by making it more integrative. Finally, we show how these BEF insights may be implemented for ecosystem management, society, and policy. Given that human well-being critically depends on the multiple services provided by diverse, multitrophic communities, integrating the approaches of evolutionary ecology, community ecology, and ecosystem ecology in future BEF research will be key to refine conservation targets and develop sustainable management strategies.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , peerRev

Format: application/pdf

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Integrating community assembly and biodiversity to better understand ecosystem function: the Community Assembly and the Functioning of Ecosystems (CAFE) approach. (2017)

Bannar-Martin, Kathrine H. ; Kremer, Colin T. ; Ernest, Morgan ; [et al.]

WILEY-BLACKWELL PUBLISHING

In: EPIC3Ecology Letters, WILEY-BLACKWELL PUBLISHING, ISSN: 1461-023X

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Publication Date: 2018-01-10

Description: The research of a generation of ecologists was catalysed by the recognition that the number and identity of species in communities influences the functioning of ecosystems. The relationship between biodiversity and ecosystem functioning (BEF) is most often examined by controlling species richness and randomising community composition. In natural systems, biodiversity changes are often part of a bigger community assembly dynamic. Therefore, focusing on community assembly and the functioning of ecosystems (CAFE), by integrating both species richness and composition through species gains, losses and changes in abundance, will better reveal how community changes affect ecosystem function. We synthesise the BEF and CAFE perspectives using an ecological application of the Price equation, which partitions the contributions of richness and composition to function. Using empirical examples, we show how the CAFE approach reveals important contributions of composition to function. These examples show how changes in species richness and composition driven by environmental perturbations can work in concert or antagonistically to influence ecosystem function. Considering how communities change in an integrative fashion, rather than focusing on one axis of community structure at a time, will improve our ability to anticipate and predict changes in ecosystem function.

Repository Name: EPIC Alfred Wegener Institut

Type: Article , isiRev

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A framework for quantifying the magnitude and variability of community responses to global change drivers (2016)

Avolio, Meghan L. ; La Pierre, Kimberly J. ; Houseman, Gregory R. ; [et al.]

John Wiley & Sons

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Publication Date: 2022-05-25

Description: © The Author(s), 2015. This article is distributed under the terms of the Creative Commons Attribution License. The definitive version was published in Ecosphere 6, no. 12 (2015): 1-14, doi:10.1890/ES15-00317.1.

Description: A major challenge in global change ecology is to predict the trajectory and magnitude of community change in response to global change drivers (GCDs). Here, we present a new framework that not only increases the predictive power of individual studies, but also allows for synthesis across GCD studies and ecosystems. First, we suggest that by quantifying community dissimilarity of replicates both among and within treatments, we can infer both the magnitude and predictability of community change, respectively. Second, we demonstrate the utility of integrating rank abundance curves with measures of community dissimilarity to understand the species-level dynamics driving community changes and propose a series of testable hypotheses linking changes in rank abundance curves with shifts in community dissimilarity. Finally, we review six case studies that demonstrate how our new conceptual framework can be applied. Overall, we present a new framework for holistically predicting community responses to GCDs that has broad applicability in this era of unprecedented global change and novel environmental conditions.

Description: We thank LTER Network Office for funding our working group and the National Socio-Environmental Synthesis Center for additional funding.

Keywords: Beta diversity ; Community dissimilarity ; Convergence ; Divergence ; Multivariate analysis ; Non-metric multidimensional scaling ; Rank abundance curve ; Species composition

Repository Name: Woods Hole Open Access Server

Type: Article

Format: application/pdf

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