Understanding the evolutionary tempo and significance of the first animals through exceptional fossil preservation. This project will shed new light on the origins and early evolutionary history of the first complex marine animals that appeared over half a billion years ago. Extraordinarily preserved fossils, including soft tissues, from South Australia will highlight the rapid anatomical innovation that occurred during this crucial phase in the history of life.
Discovery Early Career Researcher Award - Grant ID: DE200101222
Funder
Australian Research Council
Funding Amount
$392,132.00
Summary
Australia's key role in the evolution of songbirds. This project aims to provide novel insights into the evolutionary history of songbirds, which originated in Australia and now make up over half of the world's birds. The project will combine fossil, morphological, and genomic data to describe early songbird diversity in Australia, reconstruct the evolutionary relationships of fossil species, estimate the timescale of their diversification, and resolve the timing and nature of key evolutionary c ....Australia's key role in the evolution of songbirds. This project aims to provide novel insights into the evolutionary history of songbirds, which originated in Australia and now make up over half of the world's birds. The project will combine fossil, morphological, and genomic data to describe early songbird diversity in Australia, reconstruct the evolutionary relationships of fossil species, estimate the timescale of their diversification, and resolve the timing and nature of key evolutionary changes in songbirds. The project is expected to produce critical new fossil evidence and to strengthen international and multidisciplinary collaborations. Expected outcomes include significant advances in our understanding of a major component of the Australian and global fauna.Read moreRead less
Fossils, rocks and early Cambrian clocks: calibrating body plan assembly and lineage splits in ancestral animals from Gondwana. The precise timing of when animal body plans evolved and rapidly diversified during the Cambrian Explosion remains mysterious. This project will investigate vast collections of exquisitely preserved early-middle Cambrian fossils from Australia to determine the precise order of evolutionary events at the root of the animal tree of life.
Discovery Early Career Researcher Award - Grant ID: DE190101052
Funder
Australian Research Council
Funding Amount
$372,959.00
Summary
All you can eat: evolution of feeding in the largest animals on Earth. This project aims to establish how Baleen whales, the largest animals on Earth and major ecosystem engineers, evolved their signature filter-feeding strategy. Unlike other mammals, whales are toothless, and instead use a keratinous, comb-like sieve to filter vast amounts of small prey from seawater. Various approaches, including biomechanics, three-dimensional imaging, geochemistry and quantitative palaeobiology will unravel ....All you can eat: evolution of feeding in the largest animals on Earth. This project aims to establish how Baleen whales, the largest animals on Earth and major ecosystem engineers, evolved their signature filter-feeding strategy. Unlike other mammals, whales are toothless, and instead use a keratinous, comb-like sieve to filter vast amounts of small prey from seawater. Various approaches, including biomechanics, three-dimensional imaging, geochemistry and quantitative palaeobiology will unravel how and when filter feeding emerged, how it diversified over time, and whether its evolution correlated with past environmental change. The project is expected to reveal clues on how whales became one of the greatest ecological actors in the sea, and will benefit conservation by providing a glimpse into their future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100957
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Using ancient fossils and new methods to unravel Australian mammal evolution in deep time. This project will explore the evolution of Australia's unique mammal fauna by studying fossil mammals recently discovered at Tingamarra, a 55 million year old fossil site in north-eastern Queensland. In particular, it will help us understand the origin, radiation and diversification of Australia's iconic marsupials.
Discovery Early Career Researcher Award - Grant ID: DE130101133
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Evolution, breeding biology and extinction of giant fowl in Australia and the Southwest Pacific. New investigation of the extinct giant flightless Australian mihirungs and similar giant fowl of Oceania by analysis of fossils will reveal their relationships and resolve the evolutionary history of fowl globally. This project will provide insight into breeding strategies of these fossil species and the causes and impacts of their extinction.
Integrating fossils and genomes to resolve the early evolution of snakes. This project aims to address a high-profile evolutionary controversy – the origin of snakes – by reconciling the anatomical and fossil evidence with the burgeoning genomic data. New genomic data surprisingly links snakes with the un-snakelike iguana, prompting claims that the genetic and the fossil/anatomical data are irreconcilable. The project aims to evaluate these key fossils, and reptile anatomy in general, in light o ....Integrating fossils and genomes to resolve the early evolution of snakes. This project aims to address a high-profile evolutionary controversy – the origin of snakes – by reconciling the anatomical and fossil evidence with the burgeoning genomic data. New genomic data surprisingly links snakes with the un-snakelike iguana, prompting claims that the genetic and the fossil/anatomical data are irreconcilable. The project aims to evaluate these key fossils, and reptile anatomy in general, in light of the new genomic tree. This has potential to greatly elucidate major evolutionary changes across the lizard-snake transition (for example, extensive mobility in the snake skull). The project also plans to assess the long-term evolutionary consequences of ‘snakiness’, such as the hypothesised irreversibility of limb loss, and increased resilience to mass extinction.Read moreRead less
Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this ....Ancestral state reconstruction and the evolution of Australian marsupials. This project aims to investigate the diversification and evolvability of Australian marsupials, by enabling genomes, ecology and 3D skeletal shape to synergistically inform evolutionary inference. This project expects to generate new knowledge of the processes that have promoted and maintained marsupial biodiversity, by tracing their evolution across a fossil gap that spans half of their history. Expected outcomes of this project include improved methods for merging fossils into the tree of life and for reconstructing the ecology and morphology of ancestors on phylogenetic trees. This should provide significant benefits, such as a coherent evolutionary context for informing research on marsupial biology, ecology and conservation.Read moreRead less
Dark canaries: new multidisciplinary understanding about the origins, radiation and response to environmental change of southern hemisphere bats. This project will overhaul global understanding of the origins of bats, their flight patterns and the role of echolocation in resource partitioning in an environmentally changing Australia. It will also provide information vital for conservation and novel biomimetic understanding of the modulation of ultrasound for medical and engineering purposes.
Discovery Early Career Researcher Award - Grant ID: DE120102034
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
How did mammals evolve large brains? A multidisciplinary view from the pouch. This project applies novel data collection techniques to explain how the large brain sizes of today's mammals (including humans) are possible. The focus will be on brain structure, development, and evolution in the mostly Australian marsupials, whose ancestral mode of brain development makes them an ideal group for studies of brain size evolution.