The relationship between body mass and abundance is a major focus for research in macroecology. The form of this relationship has been suggested to reflect the partitioning of energy among species. We revisit classical datasets to show that size-density relationships vary systematically among taxonomic groups, with most variation occurring at the order level. We use this knowledge to make a novel test of the ‘energy equivalence rule’, at the taxonomic scale appropriate for the data. We find no obvious relationship between order-specific exponents for abundance and metabolic rate, although most orders show substantially shallower (less negative) scaling than predicted by energy equivalence. This finding implies greater energy flux among larg...
The relationship between energy availability and species richness (the species-energy relationship) ...
Physiological processes are essential for understanding the distribution and abundance of organisms,...
It is suggested that Damuth’s ‘energy-equivalence rule’ for mammal populations follows from a partic...
The negative scaling of plant and animal abundance with body mass is one of the most fundamental rel...
Energy equivalence, the notion that population energy flux is independent of body mass, has become a...
The negative relationship between body size and population density in mammals is often interpreted a...
The Energetic Equivalence Rule (EER) is a controversial issue in ecology. This rule states that the ...
Body size often strongly covaries with demography across species. Metabolism has long been invoked a...
Hypotheses that relate body size to energy use are of particular interest in community ecology and m...
We studied size-abundance relationships in a species-rich Amazonian bird community and found that th...
<div><p>Hypotheses that relate body size to energy use are of particular interest in community ecolo...
Hypotheses that relate body size to energy use are of particular interest in community ecology and m...
Differences in population density between species of varying size are frequently attributed to metab...
The scaling of metabolic rates to body size is widely considered to be of great biological and ecolo...
The scaling of metabolic rates to body size is widely considered to be of great biological and ecolo...
The relationship between energy availability and species richness (the species-energy relationship) ...
Physiological processes are essential for understanding the distribution and abundance of organisms,...
It is suggested that Damuth’s ‘energy-equivalence rule’ for mammal populations follows from a partic...
The negative scaling of plant and animal abundance with body mass is one of the most fundamental rel...
Energy equivalence, the notion that population energy flux is independent of body mass, has become a...
The negative relationship between body size and population density in mammals is often interpreted a...
The Energetic Equivalence Rule (EER) is a controversial issue in ecology. This rule states that the ...
Body size often strongly covaries with demography across species. Metabolism has long been invoked a...
Hypotheses that relate body size to energy use are of particular interest in community ecology and m...
We studied size-abundance relationships in a species-rich Amazonian bird community and found that th...
<div><p>Hypotheses that relate body size to energy use are of particular interest in community ecolo...
Hypotheses that relate body size to energy use are of particular interest in community ecology and m...
Differences in population density between species of varying size are frequently attributed to metab...
The scaling of metabolic rates to body size is widely considered to be of great biological and ecolo...
The scaling of metabolic rates to body size is widely considered to be of great biological and ecolo...
The relationship between energy availability and species richness (the species-energy relationship) ...
Physiological processes are essential for understanding the distribution and abundance of organisms,...
It is suggested that Damuth’s ‘energy-equivalence rule’ for mammal populations follows from a partic...