Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword by Robert M. May (Lord May of Oxford)
- Preface
- 1 Introduction: scaling biodiversity – what is the problem?
- PART I Spatial scaling of species richness and distribution
- PART II Alternative measures of biodiversity: taxonomy, phylogeny, and turnover
- PART III Scaling of biological diversity with energy and the latitudinal biodiversity gradient
- PART IV Processes, perspectives, and syntheses
- 16 Spatiotemporal scaling of species richness: patterns, processes, and implications
- 17 Scaling biodiversity under neutrality
- 18 General patterns in plant invasions: a family of quasi-neutral models
- 19 Extinction and population scaling
- 20 Survival of species in patchy landscapes: percolation in space and time
- 21 Biodiversity power laws
- Index
- Plate section
- References
19 - Extinction and population scaling
Published online by Cambridge University Press: 05 August 2012
Book contents
- Frontmatter
- Contents
- List of contributors
- Foreword by Robert M. May (Lord May of Oxford)
- Preface
- 1 Introduction: scaling biodiversity – what is the problem?
- PART I Spatial scaling of species richness and distribution
- PART II Alternative measures of biodiversity: taxonomy, phylogeny, and turnover
- PART III Scaling of biological diversity with energy and the latitudinal biodiversity gradient
- PART IV Processes, perspectives, and syntheses
- 16 Spatiotemporal scaling of species richness: patterns, processes, and implications
- 17 Scaling biodiversity under neutrality
- 18 General patterns in plant invasions: a family of quasi-neutral models
- 19 Extinction and population scaling
- 20 Survival of species in patchy landscapes: percolation in space and time
- 21 Biodiversity power laws
- Index
- Plate section
- References
Summary
Introduction
Arguably, the most important development in ecology in the past few decades has been the discovery of space. The spatial structure of populations and their interactions has become increasingly central to our understanding of ecological dynamics, revolutionizing many areas of both theory and application (e.g. Tilman & Kareiva, 1997). While this is true of all organisms, spatial aspects of population biology are particularly apparent in sessile organisms such as plants. Plant populations are spatially complex, with individuals typically clustered within patches that are themselves aggregated in habitats that are patchily distributed in space. Despite attempts to define the “natural” scale of patchiness (reviewed in Dale, 1999), most populations I know of appear aggregated at virtually any spatial scale. This greatly complicates the description of the abundance and distribution of species, as most of the useful measures are intrinsically scale bound. Indeed, many different aspects of abundance can be reflected by grid occupancy at some appropriate scale of resolution (Kunin, 1998). Thus the extent of a species' geographic range reflects its coarse-scale distribution, whereas population size or cover reflects fine-scale abundance, with factors such as the number of discrete subpopulations or habitat specialization being reflected at intermediate scales.
In an attempt to summarize such spatially complex patterns, the area occupied by a species may be plotted at multiple spatial scales on logarithmic axes, into a “scale area curve” that could summarize abundance scaling.
- Type
- Chapter
- Information
- Scaling Biodiversity , pp. 396 - 408Publisher: Cambridge University PressPrint publication year: 2007
References
, , & (2001). Water vole in the Scottish uplands: distribution patterns of disturbed and pristine populations ahead and behind the American mink invasion front. Animal Conservation, 4, 187–194.CrossRefGoogle Scholar
& (1997). A habitat-based metapopulation model of the California gnatcatcher. Conservation Biology, 11, 422–434.CrossRefGoogle Scholar
& (1977). Turnover rates in insular biogeography: effects of immigration on extinction. Ecology, 58, 445–449.CrossRefGoogle Scholar
& (2000). Dynamic biogeography and conservation of endangered species. Nature, 403, 84–86.CrossRefGoogle ScholarPubMed
& (1990). Spatial clustering for inhomogeneous populations. Journal of the Royal Statistical Society Series B – Methodological, 52, 73–104.Google Scholar
(1999). Spatial Pattern Analysis in Plant Ecology. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
(1975). The island dilemma: lessons of modern biogeographic studies for the design of natural reserves. Biological Conservation, 7, 129–146.CrossRefGoogle Scholar
(1998). Relative effects of habitat loss and fragmentation on population extinction. Journal of Wildlife Management, 61, 603–610.CrossRefGoogle Scholar
& (2002). Patchy reaction-diffusion and population abundance: the relative importance of habitat amount and arrangement. American Naturalist, 159, 40–56.Google ScholarPubMed
, & (1999). Does variation in census area confound density comparisons?Journal of Applied Ecology, 36, 191–204.CrossRefGoogle Scholar
Gilpin, M. E. & Soulé, M. E. (1986). Minimum viable populations: processes of extinction. In Conservation Biology: Science of Scarcity and Diversity, ed. , pp. 19–34. Sunderland, MD: Sinauer.Google Scholar
, , , , & (2004). Uses and abuses of fractal methodology in ecology. Ecology Letters, 7, 254–271.CrossRefGoogle Scholar
& (2003). Scale dependency of rarity, extinction risk, and conservation priority. Conservation Biology, 17, 1559–1570.CrossRefGoogle Scholar
, , & (2004). Coherence and discontinuity in the scaling of species distribution patternsProceedings of the Royal Society of London, Series B, 271, 81–88.CrossRefGoogle Scholar
& (1999). Habitat fragmentation and extinction thresholds on fractal landscapes. Ecology Letters, 2, 121–127.CrossRefGoogle Scholar
(2001). The Unified Neutral Theory of Biodiversity and Biogeography. Princeton: Princeton University Press.Google Scholar
, , & (2005). Metapopulation extinction risk under spatially autocorrelated disturbance. Conservation Biology, 19, 534–546.CrossRefGoogle Scholar
(1998). Extrapolating species abundance across spatial scales. Science, 281, 1513–1515.CrossRefGoogle ScholarPubMed
, & (1994). Spotted owl metapopulation dynamics in southern California. Journal of Animal Ecology, 63, 775–785.CrossRefGoogle Scholar
, , , & (2004). Connectivity and homogenisation of population sizes: an experimental approach in Lacerta vivipara. Journal of Animal Ecology, 73, 179–189.CrossRefGoogle Scholar
(1969). Some demographic and genetic consequences of environmental heterogeneity for biological control. Bulletin of the Entomological Society of America, 15, 237–240.CrossRefGoogle Scholar
& (2000). Spatially-correlated extinction in a metapopulation model of Leadbeater's possum. Biodiversity and Conservation, 9, 47–63.CrossRefGoogle Scholar
, & (2005). Theory for designing nature reserves for single species. American Naturalist, 165, 250–257.CrossRefGoogle ScholarPubMed
McDowall, W. (2003). Extinction in a spatially autocorrelated environment. MSc dissertation, University of Leeds.
, & , (2000). Self-similarity and clustering in the spatial distribution of species. Science, 290, Supplement 671a.CrossRefGoogle ScholarPubMed
(2002). Long term persistence of species and the SLOSS problem. Journal of Theoretical Biology, 218, 419–433.CrossRefGoogle ScholarPubMed
(1997). Analysis and modeling of the natural variability of climate. Journal of Climate, 10, 1331–1342.2.0.CO;2>CrossRefGoogle Scholar
, , , & (2006). Ecological correlates of range structure in rare and scarce British plants. Journal of Applied Ecology, 94, 581–596.CrossRefGoogle Scholar
& (2002). Internal structure and patterns of contraction in the geographic range of the Iberian lynx. Ecography, 25, 314–328.CrossRefGoogle Scholar
& (2003). Population fragmentation and extinction in the Iberian lynx. Biological Conservation, 109, 321–331.CrossRefGoogle Scholar
& (1996). Density dependence: are we searching at the wrong scale?Journal of Animal Ecology, 65, 556–566.CrossRefGoogle Scholar
& (2004). Power-law species-area relationships and self-similar species distributions within finite areas. Ecology Letters, 7, 60–68.CrossRefGoogle Scholar
& (1996). Scaling population density and spatial pattern for terrestrial mammalian carnivores. Oecologia, 105, 329–355.CrossRefGoogle ScholarPubMed
, & (2004). Patterns of extinction in prairie dog metapopulations: plague outbreaks follow El Nino events. Frontiers in Ecology and the Environment, 2, 235–240.Google Scholar
, , , & (2002). Scale-dependent effects of landscape context on three pollinator guilds. Ecology, 83, 1421–1432.CrossRefGoogle Scholar
, & (2003). Geometry of the species-area relationship in central European birds: testing the mechanism. Journal of Animal Ecology, 72, 509–519.CrossRefGoogle Scholar
, & (1992). Distribution of occupied and vacant butterfly habitats in fragmented landscapes. Oecologia, 92, 563–567.CrossRefGoogle Scholar
& (eds.) (1997). Spatial Ecology: the Role of Space in Population Dynamics and Interspecific Interactions. Princeton: Princeton University Press.Google Scholar
(1997). Fractals and Chaos in Geology and Geophysics. Cambridge: Cambridge University Press.CrossRefGoogle Scholar
, & (2003). Mass flowering crops enhance pollinator densities at a landscape scale. Ecology Letters, 6, 961–965.CrossRefGoogle Scholar
, , , & (2004). Spatial patterns in species diversity reveal biodiversity change. Nature, 432, 393–396.CrossRefGoogle Scholar
& (1999). Extinction thresholds for species in fractal landscapes. Conservation Biology, 13, 314–326.CrossRefGoogle Scholar