How isolated is Antarctica? Assessing past and present plant colonisations. The project aims to assess how biologically isolated Antarctica is by discovering how, when and where natural colonisations of the continent have occurred. The research will focus on mosses, the dominant plant group in the Antarctic. genomic tools will be combined with environmental, spatial, and ecological data to assess mechanisms and directions of dispersal to and around Antarctica, and to predict areas most likely to ....How isolated is Antarctica? Assessing past and present plant colonisations. The project aims to assess how biologically isolated Antarctica is by discovering how, when and where natural colonisations of the continent have occurred. The research will focus on mosses, the dominant plant group in the Antarctic. genomic tools will be combined with environmental, spatial, and ecological data to assess mechanisms and directions of dispersal to and around Antarctica, and to predict areas most likely to be colonised in the future. This will help understand the processes underpinning the evolution and diversity of Antarctic species, and the vulnerability and adaptability of Antarctic ecosystems. Read moreRead less
Evolution of Australia's globally unique hotspot of floral diversity. Australia has a globally recognised biodiversity hotspot, the southwest of Western Australia, but this unique eucalypt-dominated flora is threatened. This project will gain new insights into the evolutionary processes that generate and maintain such diversity, their vulnerability; and how the iconic eucalypts came to dominate the Australian landscape.
Reconstructing the impact of climate change on Australian native species. This project will explore the impact of past climate change on Australian native animals to identify species and ecosystems at greatest potential risk, and to help predict and minimise the effects of future change.
Warrakan'puy Djäma: A new biocultural approach to fauna conservation. This project aims to record endangered Indigenous knowledge of fauna and integrate this with innovative Western science to develop Australia’s first cross-cultural fauna conservation strategy. In partnership with the Laynhapuy Indigenous Protected Area and one of Australia’s strongest Aboriginal cultural groups, the Yolngu, this project expects to generate new biocultural solutions to two of the most urgent challenges of our t ....Warrakan'puy Djäma: A new biocultural approach to fauna conservation. This project aims to record endangered Indigenous knowledge of fauna and integrate this with innovative Western science to develop Australia’s first cross-cultural fauna conservation strategy. In partnership with the Laynhapuy Indigenous Protected Area and one of Australia’s strongest Aboriginal cultural groups, the Yolngu, this project expects to generate new biocultural solutions to two of the most urgent challenges of our time: species and cultural loss. The expected outcomes include targeted on-ground fauna surveys with Elders, Rangers and youth, cross-cultural knowledge mapping, new species and landscape genetics. Innovative multimedia knowledge sharing platforms will demonstrate the multiple benefits of cross-cultural fauna science. Read moreRead less
Drivers of fine scale genetic spatial structuring in aquatic organisms. Understanding factors that influence genetic spatial structure of species is essential for conserving biodiversity. Movement of freshwater organisms in riverine environments is severely constrained by dendritic structure of streams, variation in aridity, and geomorphology. The project aims to test hypotheses of how these factors impact genetic patterns across east-west climatic gradients in eastern Australia. For most aquati ....Drivers of fine scale genetic spatial structuring in aquatic organisms. Understanding factors that influence genetic spatial structure of species is essential for conserving biodiversity. Movement of freshwater organisms in riverine environments is severely constrained by dendritic structure of streams, variation in aridity, and geomorphology. The project aims to test hypotheses of how these factors impact genetic patterns across east-west climatic gradients in eastern Australia. For most aquatic species, research is limited on genetic patterns across spatial scales with varying riverine dendritic structure and rarely incorporates historical data. Uncovering genetic spatial structure in aquatic ecosystems is necessary for conservation management and predicting species movements in the current changing climate.Read moreRead less
Evolutionary origins of sexual parasitism in an Australian freshwater fish. Carp gudgeons are the most abundant, widespread and biodiverse freshwater fishes in southeastern Australia. The unacknowledged presence of many cryptic species and sexually-parasitic lineages severely taints all research on this cornerstone group. This project aims to provide unrivalled evolutionary, genomic, and taxonomic insights into this new instance of vertebrate sexual parasitism, which offers a unique mix of resea ....Evolutionary origins of sexual parasitism in an Australian freshwater fish. Carp gudgeons are the most abundant, widespread and biodiverse freshwater fishes in southeastern Australia. The unacknowledged presence of many cryptic species and sexually-parasitic lineages severely taints all research on this cornerstone group. This project aims to provide unrivalled evolutionary, genomic, and taxonomic insights into this new instance of vertebrate sexual parasitism, which offers a unique mix of research advantages not displayed by any other sexual/unisexual complex. The knowledge gained could impact many research fields, including evolutionary theory addressing the unexplainable prevalence of sex, native fish ecology, and environmental monitoring of the Murray-Darling Basin, an ecosystem of world significance.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL110100104
Funder
Australian Research Council
Funding Amount
$2,939,883.00
Summary
New approaches to discovering biodiversity and understanding its response to past climate change. New technologies will be used to predict and discover biodiversity hotspots in Australia, especially in the monsoonal tropics. New capacity will be built in biodiversity science, and the results used to improve conservation policy and the effectiveness of conservation planning.