Your search keyword '"sampling biodiversity"' showing total 2 results

1. A general framework for the distance–decay of similarity in ecological communities.

Author

Morlon, Hélène, Chuyong, George, Condit, Richard, Hubbell, Stephen, Kenfack, David, Thomas, Duncan, Valencia, Renato, and Green, Jessica L.

Subjects

*BIOGEOGRAPHY, *BIODIVERSITY, *SPECIES diversity, *FORESTS & forestry, *SPECIES distribution, *POPULATION

Abstract

Species spatial turnover, or β-diversity, induces a decay of community similarity with geographic distance known as the distance–decay relationship. Although this relationship is central to biodiversity and biogeography, its theoretical underpinnings remain poorly understood. Here, we develop a general framework to describe how the distance–decay relationship is influenced by population aggregation and the landscape-scale species-abundance distribution. We utilize this general framework and data from three tropical forests to show that rare species have a weak influence on distance–decay curves, and that overall similarity and rates of decay are primarily influenced by species abundances and population aggregation respectively. We illustrate the utility of the framework by deriving an exact analytical expression of the distance–decay relationship when population aggregation is characterized by the Poisson Cluster Process. Our study provides a foundation for understanding the distance–decay relationship, and for predicting and testing patterns of beta-diversity under competing theories in ecology. [ABSTRACT FROM AUTHOR]

Published

2008

2. A general framework for the distance–decay of similarity in ecological communities

Author

Stephen P. Hubbell, Richard Condit, Jessica L. Green, George B. Chuyong, David Kenfack, Duncan W. Thomas, Renato Valencia, and Hélène Morlon

Subjects

Letter, spatial aggregation, species-abundance distribution, Sørensen index, Ecology (disciplines), Rare species, Population, Population Dynamics, Beta diversity, Models, Biological, Trees, Similarity (network science), Geographical distance, Quantitative Biology::Populations and Evolution, Poisson Distribution, education, Ecology, Evolution, Behavior and Systematics, Relative abundance distribution, species–area relationship, Distance decay, sampling biodiversity, tropical forests, Population Density, education.field_of_study, Tropical Climate, Ecology, Geography, Beta-diversity, distance–decay relationship, Poisson Cluster Process, spatial turnover, Biodiversity

Abstract

Species spatial turnover, or β-diversity, induces a decay of community similarity with geographic distance known as the distance–decay relationship. Although this relationship is central to biodiversity and biogeography, its theoretical underpinnings remain poorly understood. Here, we develop a general framework to describe how the distance–decay relationship is influenced by population aggregation and the landscape-scale species-abundance distribution. We utilize this general framework and data from three tropical forests to show that rare species have a weak influence on distance–decay curves, and that overall similarity and rates of decay are primarily influenced by species abundances and population aggregation respectively. We illustrate the utility of the framework by deriving an exact analytical expression of the distance–decay relationship when population aggregation is characterized by the Poisson Cluster Process. Our study provides a foundation for understanding the distance–decay relationship, and for predicting and testing patterns of beta-diversity under competing theories in ecology. Ecology Letters (2008) 11: 904–917

Published

2008