Latitudinal gradients in biotic processes affecting plant growth and establishment. The idea that plant-animal interactions are more intense in the tropics underpins much thinking about tropical ecology, global patterns in plant traits, and latitudinal gradients in biodiversity. In this project, we will provide the first direct and global test of this idea by quantifying the intensity of herbivory, seed predation and density-dependent seedling mortality at approximately 100 study sites around th ....Latitudinal gradients in biotic processes affecting plant growth and establishment. The idea that plant-animal interactions are more intense in the tropics underpins much thinking about tropical ecology, global patterns in plant traits, and latitudinal gradients in biodiversity. In this project, we will provide the first direct and global test of this idea by quantifying the intensity of herbivory, seed predation and density-dependent seedling mortality at approximately 100 study sites around the world. We will also investigate the causes of these latitudinal gradients by determining which environmental variables are most closely associated with the strength of biotic interactions.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL100100080
Funder
Australian Research Council
Funding Amount
$2,859,732.00
Summary
Evolutionary ecology of vegetation. A more fundamental understanding will be developed about the architecture and ecology of vegetation and why it varies around the world. Understanding confers benefits for land management as well as cultural value. Under a high carbon dioxide future scenario, models will be needed that operate through fundamental mechanisms of evolution, competition and physiology, rather than through extrapolation from present-day plants. Australia is a leader in globalising p ....Evolutionary ecology of vegetation. A more fundamental understanding will be developed about the architecture and ecology of vegetation and why it varies around the world. Understanding confers benefits for land management as well as cultural value. Under a high carbon dioxide future scenario, models will be needed that operate through fundamental mechanisms of evolution, competition and physiology, rather than through extrapolation from present-day plants. Australia is a leader in globalising plant trait ecology, and the program will develop that role further. Through intensive short courses within the Sydney basin and at national scale, research capacity will be developed towards the coming four-way fusion among functional ecology, earth system science, comparative genomics and palaeobiology.Read moreRead less
Dimensions of ecological strategy for plants. A more fundamental understanding will be sought about the architecture and ecology of vegetation and why it varies around the world. Under a high- CO2 future, models will be needed that operate through fundamental mechanisms of evolution, competition and physiology, rather than through extrapolation from present-day plants.
Altering host-parasite interactions through wildlife conservation strategies. Disease outbreaks are heightened in endangered animals but strategies used to conserve these species often increase risk of disease; nowhere is this more critical than in species recovery programs. The project will study disease in a recovery program to improve conservation practice and protect Australia's wildlife, ensuring our ecosystems are sustained.
Latitudinal gradients and beyond: understanding the drivers of global patterns in plant ecology. There are astonishing gaps in our understanding of global patterns in the way plants grow, and the factors that underlie these patterns. We don’t know whether mean climatic conditions or extreme events are more important in shaping plant traits. We don’t know which environmental variables are most important in shaping most aspects of plant ecological strategy, and we don’t know what shape the relatio ....Latitudinal gradients and beyond: understanding the drivers of global patterns in plant ecology. There are astonishing gaps in our understanding of global patterns in the way plants grow, and the factors that underlie these patterns. We don’t know whether mean climatic conditions or extreme events are more important in shaping plant traits. We don’t know which environmental variables are most important in shaping most aspects of plant ecological strategy, and we don’t know what shape the relationship between latitude and most plant traits takes. This project will address these knowledge gaps, substantially improving our ability to predict the potential impacts of climate change on plants, and providing the basis for exciting new theory about the mechanisms driving the evolution of plant form and function in Australia, and around the world.Read moreRead less
Putting adaptation into vegetation models: towards a predictive theory of trait diversity and stand structure. By incorporating natural selection into models of vegetation, this project will help to predict what sorts of plants are found where and why. This will greatly improve the ability to predict the likely outcomes of human impacts (changing climates, increased disturbance, logging) for future vegetation and species diversity.
Origins of a biodiversity hotspot flora: diversification of the Australian Proteaceae. Why does Australia's only biodiversity hotspot, with nearly 3000 endemic plant species, occur in an area with poor soils and low rainfall? This project will analyse DNA sequences from over 1000 plant species of the Australian Proteaceae, many found only in this hotspot, to help us understand the evolutionary and ecological origins of this iconic flora.
Macroecology and phylogeny: the effects of evolutionary history on rarity and extinction risk in Australian vertebrates. We will combine ecological and phylogenetic analysis of Australian vertebrates to show how abundance and geographic range in living species has been shaped by the historical processes of speciation, transformations of range and abundance in relation to species age, and selective extinction. Our analysis will throw new light on the processes that have generated species diversit ....Macroecology and phylogeny: the effects of evolutionary history on rarity and extinction risk in Australian vertebrates. We will combine ecological and phylogenetic analysis of Australian vertebrates to show how abundance and geographic range in living species has been shaped by the historical processes of speciation, transformations of range and abundance in relation to species age, and selective extinction. Our analysis will throw new light on the processes that have generated species diversity in Australian vertebrates. We will also gain new understanding of the causes of rarity and vulnerability to extinction among living species, which will result in better identification and management of species at risk of extinction.Read moreRead less
A framework linking tree species coexistence, zonation and patterns of species richness in forests. Our curiosity-driven proposal capitalizes on a superb opportunity afforded by the occurrence of forest vegetation across a wide range of climates and soils in eastern Australia, an ideal setting for testing ideas about how environment shapes plant evolution as well as forest structure and dynamics. This research will contribute to international interchange of ideas by promoting interaction with co ....A framework linking tree species coexistence, zonation and patterns of species richness in forests. Our curiosity-driven proposal capitalizes on a superb opportunity afforded by the occurrence of forest vegetation across a wide range of climates and soils in eastern Australia, an ideal setting for testing ideas about how environment shapes plant evolution as well as forest structure and dynamics. This research will contribute to international interchange of ideas by promoting interaction with collaborators in New Zealand, and will generate a series of publications in high-impact international journals. We will help Australians better understand the forces that shape patterns of woody vegetation across local landscapes, and our carbon-balance framework may shed light on the causes of rarity of some tree species with conservation problems.Read moreRead less