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A Theory of Global Biodiversity (MPB-60). (2018)

Worm, Boris.

Princeton :Princeton University Press,

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Keywords: Electronic books.

Description / Table of Contents: No detailed description available for "A Theory of Global Biodiversity (MPB-60)".

Type of Medium: Online Resource

Pages: 1 online resource (230 pages)

Edition: 1st ed.

ISBN: 9781400890231

Series Statement: Monographs in Population Biology Series ; v.60

URL: https://ebookcentral.proquest.com/lib/geomar/detail.action?docID=5378479

DDC: 333.95

Language: English

Note: Cover -- Title -- Copyright -- Dedication -- Contents -- Acknowledgments -- 1. Introduction -- 1.1. Integrating Land and Sea -- 1.2. A Brief History of Biodiversity Research -- 1.3. Goals and Structure of This Book -- 2. Observed Patterns of Global Biodiversity -- 2.1. Marine Coastal Biodiversity -- 2.2. Marine Pelagic Biodiversity -- 2.3. Deep-Sea Biodiversity -- 2.4. Terrestrial Biodiversity -- 2.5. Changes in Biodiversity Patterns through Time -- 2.6. Robustness of Documented Biodiversity Patterns -- 2.7. Synthesis -- 3. Drivers and Predictors of Global Biodiversity -- 3.1. Hypothesized Drivers of Diversity -- 3.2. Spatial and Temporal Scale -- 3.3. Empirical Predictors of Diversity -- 3.4. Synthesis -- 4. Developing a Theory of Global Biodiversity -- 4.1. Basic Neutral Theory -- 4.2. Implementation in Forward and Coalescence Mode -- 4.3. Including Metabolic Theory -- 4.4. Including Habitat Area and Productivity -- 4.5. Including Temperature Niches -- 4.6. Discussion and Comparison with Other Theory -- 5. Predicting Global Biodiversity Patterns from Theory -- 5.1. Fitting Theoretical Predictions to Empirical Data -- 5.2. Ectotherms versus Endotherms -- 5.3. Including Niches -- 5.4. Synthesis -- 6. Conservation Applications -- 6.1. Global Biodiversity Hotspots and Conservation Priorities -- 6.2. Observed Biodiversity Change and Its Drivers -- 6.3. Projecting Biodiversity Change from Theory -- 6.4. The Future of Biodiversity -- 7. Conclusions -- 7.1. Summary of Major Findings -- 7.2. Ecological Theory -- 7.3. A Niche for Neutrality? -- 7.4. Spatial Scale -- 7.5. Ecological versus Evolutionary Time -- 7.6. Applications -- 7.7. Limitations -- 7.8. Final Outlook -- References -- Index.

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Control of macroalgal blooms at early developmental stages: Pilayella littoralis versus Enteromorpha spp. (1999)

Lotze, Heike K. ; Schramm, Winfrid ; Schories, Dirk ; [et al.]

Springer

Oecologia 119 (1999), S. 46-54

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ISSN: 1432-1939

Keywords: Key words Baltic Sea ; Coastal eutrophication ; Crustacean grazers germination ; Overwintering propagules

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Although blooms of opportunistic fast-growing macroalgae now occur frequently in coastal ecosystems affected by eutrophication, their initiation and control is little understood. Most previous studies have focused on the ecophysiology of adult algae only. We show that spores and/or germlings may represent critical stages in the life cycles and mass-developments of co-occurring opportunistic macroalgae in the Baltic (Pilayella littoralis and Enteromorpha spp.). We investigated the overwintering of spores, timing of germination, subsequent growth, and grazing on spores and germlings, in order to explain the initiation of mass blooms and species dominance patterns. In the field, Enteromorpha spp. showed 10- to 50-fold higher abundances of overwintering microscopic forms (up to 330 individuals cm−2) than P. littoralis. Moreover, we found continuous production of spores (up to 1.2 million settling spores m−2 h−1) from April to October in Enteromorpha spp., while there was evidence of only a short reproductive period in Pilayella. However, in spring, germlings and adults of P. littoralis appeared earlier in the field and reached a 10-fold higher biomass than Enteromorpha spp. In factorial laboratory experiments including temperature and light, there were clear differences in timing of germination. P. littoralis germinated at 5°C whereas Enteromorpha spp. required temperatures of 10–15°C for germination. In contrast, we detected only minor differences in growth response among adults of P. littoralis and Enteromorpha spp. Germination, not growth of adults, appeared to be the ecophysiological bottleneck for initiating mass spring development. Following the spring Pilayella bloom, Enteromorpha germlings occurred massively in the field (April–September), but rarely developed into adults. In laboratory feeding experiments we tested whether crustacean mesograzers common in summer may control development of Enteromorpha germlings. Both germination of settled spores and growth of germlings were reduced by 93–99% in the presence of grazers (Idotea chelipes and Gammarus locusta). Thus in addition to ecophysiological constraints, grazers, if present, may play a decisive role in the early life stages of macroalgal mass developments. These results mirror patterns of overwintering of seeds, germination control, seed and seedling predation in terrestrial plant communities.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004420050759

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Competition, coexistence and diversity on rocky shores (2002)

Worm, Boris ; Karez, Rolf

Springer

In: In: Competition and Coexistence. , ed. by Sommer, U. and Worm, B. Ecological Studies, 161 . Springer, Berlin, Germany, pp. 133-163. ISBN 978-3-642-62800-9

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Publication Date: 2017-01-26

Description: The question "Why are there so many species?" has puzzled ecologist for a long time. Initially, an academic question, it has gained practical interest by the recent awareness of global biodiversity loss. Species diversity in local ecosystems has always been discussed in relation to the problem of competi tive exclusion and the apparent contradiction between the competitive exclu sion principle and the overwhelming richness of species found in nature. Competition as a mechanism structuring ecological communities has never been uncontroversial. Not only its importance but even its existence have been debated. On the one extreme, some ecologists have taken competi tion for granted and have used it as an explanation by default if the distribu tion of a species was more restricted than could be explained by physiology and dispersal history. For decades, competition has been a core mechanism behind popular concepts like ecological niche, succession, limiting similarity, and character displacement, among others. For some, competition has almost become synonymous with the Darwinian "struggle for existence", although simple plausibility should tell us that organisms have to struggle against much more than competitors, e.g. predators, parasites, pathogens, and envi ronmental harshness.

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1007/978-3-642-56166-5_6

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Human transformations of the Wadden Sea ecosystem through time: a synthesis (2005)

Lotze, Heike ; Reise, K. ; Worm, Boris ; [et al.]

AWI | Springer

In: Helgoland Marine Research, 59 . pp. 84-95.

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Publication Date: 2019-08-06

Description: Todayrsquos Wadden Sea is a heavily human-altered ecosystem. Shaped by natural forces since its origin 7,500 years ago, humans gradually gained dominance in influencing ecosystem structure and functioning. Here, we reconstruct the timeline of human impacts and the history of ecological changes in the Wadden Sea. We then discuss the ecosystem and societal consequences of observed changes, and conclude with management implications. Human influences have intensified and multiplied over time. Large-scale habitat transformation over the last 1,000 years has eliminated diverse terrestrial, freshwater, brackish and marine habitats. Intensive exploitation of everything from oysters to whales has depleted most large predators and habitat-building species since medieval times. In the twentieth century, pollution, eutrophication, species invasions and, presumably, climate change have had marked impacts on the Wadden Sea flora and fauna. Yet habitat loss and overexploitation were the two main causes for the extinction or severe depletion of 144 species (~20% of total macrobiota). The loss of biodiversity, large predators, special habitats, filter and storage capacity, and degradation in water quality have led to a simplification and homogenisation of the food web structure and ecosystem functioning that has affected the Wadden Sea ecosystem and coastal societies alike. Recent conservation efforts have reversed some negative trends by enabling some birds and mammals to recover and by creating new economic options for society. The Wadden Sea history provides a unique long-term perspective on ecological change, new objectives for conservation, restoration and management, and an ecological baseline that allows us to envision a rich, productive and diverse Wadden Sea ecosystem and coastal society.

Type: Article , PeerReviewed

Format: text

DOI: 10.1007/s10152-004-0209-z

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Control of macroalgal blooms at early developmental stages: Pilayella litoralis versus Enteromorpha spp (1999)

Lotze, Heike ; Schramm, Winfried ; Schories, D. ; [et al.]

Springer

In: Oecologia, 119 . pp. 46-54.

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Publication Date: 2017-10-09

Description: Although blooms of opportunistic fast-growing macroalgae now occur frequently in coastal ecosystems affected by eutrophication, their initiation and control is little understood. Most previous studies have focused on the ecophysiology of adult algae only. We show that spores and/or germlings may represent critical stages in the life cycles and mass-developments of co-occurring opportunistic macroalgae in the Baltic (Pilayella littoralis and Enteromorpha spp.). We investigated the overwintering of spores, timing of germination, subsequent growth, and grazing on spores and germlings, in order to explain the initiation of mass blooms and species dominance patterns. In the field, Enteromorpha spp. showed 10- to 50-fold higher abundances of overwintering microscopic forms (up to 330 individuals cm-2) than P. littoralis. Moreover, we found continuous production of spores (up to 1.2 million settling spores m-2 h-1) from April to October in Enteromorpha spp., while there was evidence of only a short reproductive period in Pilayella. However, in spring, germlings and adults of P. littoralis appeared earlier in the field and reached a 10-fold higher biomass than Enteromorpha spp. In factorial laboratory experiments including temperature and light, there were clear differences in timing of germination. P. littoralis germinated at 5°C whereas Enteromorpha spp. required temperatures of 10-15°C for germination. In contrast, we detected only minor differences in growth response among adults of P. littoralis and Enteromorpha spp. Germination, not growth of adults, appeared to be the ecophysiological bottleneck for initiating mass spring development. Following the spring Pilayella bloom, Enteromorpha germlings occurred massively in the field (April-September), but rarely developed into adults. In laboratory feeding experiments we tested whether crustacean mesograzers common in summer may control development of Enteromorpha germlings. Both germination of settled spores and growth of germlings were reduced by 93-99% in the presence of grazers (Idotea chelipes and Gammarus locusta). Thus in addition to ecophysiological constraints, grazers, if present, may play a decisive role in the early life stages of macroalgal mass developments. These results mirror patterns of overwintering of seeds, germination control, seed and seedling predation in terrestrial plant communities.

Type: Article , PeerReviewed

Format: text

DOI: 10.1007/s004420050759

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Synthesis: Back to Santa Rosalia, or No Wonder There Are So Many Species (2002)

Sommer, Ulrich ; Worm, Boris

Springer

In: In: Competition and Coexistence. , ed. by Sommer, U. and Worm, B. Ecological Studies, 161 . Springer, Berlin, Germany, pp. 207-218. ISBN 978-3-642-62800-9

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Publication Date: 2017-01-26

Description: Modern competition research started with G.E. Hutchinson’s, Homage to Santa Rosalia, and his now-famous question “why are there so many species?” (Hutchinson 1959,1961). This confronted observed species richness with the competitive exclusion principle, a principle that had been derived from theory and from highly artificial experiments. It would always have been easy to point at the “artificial” character of the competitive exclusion principle. Indeed many researchers have refused to deal with Hutchinson’s question because they considered it a pseudo-problem, which arose from a contradiction between overly simplified theory and complicated reality. However, those who took Hutchinson’s challenge seriously have gained fundamental insights into how competition plays out in nature, how species coexist, and how communities function. In this final chapter we attempt to synthesize these insights as they have been presented in this book. We focus on six key topics: - Identification of major trade-off axes (Sect. 8.1) - Confirmation of the “intermediate disturbance hypothesis”, and detection of interactions among competition, resource supply, predation and disturbance in field experiments (Sect. 8.2) - The interplay of space colonization, dispersal and neighborhood competition in sessile communities (Sect. 8.3) - Potential for chaotic, self-generated heterogeneity in communities (Sect. 8.4) - Role of exclusive resources in competition among mobile animals (Sect. 8.5) - Coexistence by slow exclusion (Sect. 8.6)

Type: Book chapter , NonPeerReviewed

Format: text

DOI: 10.1007/978-3-642-56166-5_8

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