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.
Evolutionary dynamics in deep time: faunal turnover during the Ediacaran. This project aims to investigate the world’s oldest faunal succession in the fossil record by determining the presence and extent of a sedimentary gap and confirming the role of time in the control of fossil distribution. Significant breakthroughs and capacity building are expected in the areas of palaeontology, evolutionary biology and geology using a hitherto unrecognised hiatus in the rock succession. Project outcomes i ....Evolutionary dynamics in deep time: faunal turnover during the Ediacaran. This project aims to investigate the world’s oldest faunal succession in the fossil record by determining the presence and extent of a sedimentary gap and confirming the role of time in the control of fossil distribution. Significant breakthroughs and capacity building are expected in the areas of palaeontology, evolutionary biology and geology using a hitherto unrecognised hiatus in the rock succession. Project outcomes include enhanced understanding of the first animal communities on Earth – these should provide significant benefits, such as revealing Australia's unique record of oldest complex organisms, while bringing additional tourism to the region, and increasing the strength of the Flinders Ranges UNESCO World Heritage nomination.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100247
Funder
Australian Research Council
Funding Amount
$353,706.00
Summary
Out of China? Australia's earliest endemic jawed vertebrate faunas. This project will seek new fossil discoveries from Australian Devonian sediments to address questions of the origins, diversification and biogeographical dispersal of early jawed vertebrates. In particular, there is the potential to test or refine recent evolutionary hypotheses based on fossil finds from the Siluro-Devonian of southern China which served as a likely point of origin for several key vertebrate groups. Likely finds ....Out of China? Australia's earliest endemic jawed vertebrate faunas. This project will seek new fossil discoveries from Australian Devonian sediments to address questions of the origins, diversification and biogeographical dispersal of early jawed vertebrates. In particular, there is the potential to test or refine recent evolutionary hypotheses based on fossil finds from the Siluro-Devonian of southern China which served as a likely point of origin for several key vertebrate groups. Likely finds include fishes that test dermal bone-homologies between osteichthyans and placoderms, jawless fishes that may unveil details of the origin of jaws, and calibration of paleoatmospheric models via the observed size of Early Devonian fossil fishes.Read moreRead less
Glauconite: Archive Recording Timing and Triggers of Cambrian Radiation . This project aims to constrain the timing and speed of the Cambrian radiation of complex animals, and to test potential environmental triggers of this milestone bioevent. New laser mass spectrometry and mineral mapping technology will be integrated to precisely date glauconite – a silicate mineral commonly formed in Cambrian shallow marine animal habitats. This innovative and cost-effective approach will produce the first ....Glauconite: Archive Recording Timing and Triggers of Cambrian Radiation . This project aims to constrain the timing and speed of the Cambrian radiation of complex animals, and to test potential environmental triggers of this milestone bioevent. New laser mass spectrometry and mineral mapping technology will be integrated to precisely date glauconite – a silicate mineral commonly formed in Cambrian shallow marine animal habitats. This innovative and cost-effective approach will produce the first high-resolution timeline of early animal evolution, where the glauconite-based marine isotope record identifies the most likely environmental trigger for the Cambrian Radiation. Outcomes of this study include improved understanding of the drivers of animal evolution, and a new dating tool for basic and applied research.Read moreRead less
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
Detachments in evaporites and shales: their controls on fold-thrust belt style and wedge geometry. Deepwater fold-thrust belts comprise large structural traps, currently a major focus of Australian petroleum exploration. The structural style of a fold-thrust belt is controlled by its detachment and new field analogues will demonstrate the fundamental role of detachments.
Middle Age Earth: ocean chemistry and evolution in the Boring Billion. This project aims to investigate the role of ocean chemistry on the evolution of eukaryotes during the “Boring Billion” (1800-800 million years ago) and how sedimentary rocks record past ocean chemistry, by using innovative geochemical proxies. This project expects to generate new knowledge in geochemistry, sedimentology and paaleo-biology using interdisciplinary approaches. Expected outcomes include a quantitative understand ....Middle Age Earth: ocean chemistry and evolution in the Boring Billion. This project aims to investigate the role of ocean chemistry on the evolution of eukaryotes during the “Boring Billion” (1800-800 million years ago) and how sedimentary rocks record past ocean chemistry, by using innovative geochemical proxies. This project expects to generate new knowledge in geochemistry, sedimentology and paaleo-biology using interdisciplinary approaches. Expected outcomes include a quantitative understanding of the formation of sedimentary rocks, and of the links between evolution and marine nutrient and metal abundance. This should provide significant benefits, such as understanding the formation and alteration of ore-bearing sedimentary rocks and how life has evolved during Earth's Middle Age.Read moreRead less
Plumbing the gap: a mantle solution to the enigma of bimodal arc volcanism. Subduction zones and volcanic arcs are the most tectonically active regions on Earth and are crucial to understanding, geochemical cycles, tectonic-climate coupling, ore genesis and natural hazards. Bimodal volcanism is a long-recognised characteristic of arc crust that has never been satisfactorily explained, yet, it controls many of these processes. This project will test a new hypothesis that the two types of magmas .... Plumbing the gap: a mantle solution to the enigma of bimodal arc volcanism. Subduction zones and volcanic arcs are the most tectonically active regions on Earth and are crucial to understanding, geochemical cycles, tectonic-climate coupling, ore genesis and natural hazards. Bimodal volcanism is a long-recognised characteristic of arc crust that has never been satisfactorily explained, yet, it controls many of these processes. This project will test a new hypothesis that the two types of magmas originate from distinct mantle sources. It integrates novel high-pressure experiments with database analysis of natural volcanic rocks, covering magmatic systems from mantle source to volcano. This project will improve our understanding of arc processes, including the association of economic metals with bimodal arc volcanism.Read moreRead less
Unravelling vanadium biogeochemistry in modern marine sediments. This project aims to unravel the biogeochemistry of vanadium in modern marine sediments for use as a tracer of ancient oxygen concentrations in the oceans of the early Earth. This project will generate fundamental knowledge on the behaviour of vanadium in modern marine sediments by applying advanced analytical tools for imaging its concentration and chemical form at ultra-high resolution. This information is critical for accurate i ....Unravelling vanadium biogeochemistry in modern marine sediments. This project aims to unravel the biogeochemistry of vanadium in modern marine sediments for use as a tracer of ancient oxygen concentrations in the oceans of the early Earth. This project will generate fundamental knowledge on the behaviour of vanadium in modern marine sediments by applying advanced analytical tools for imaging its concentration and chemical form at ultra-high resolution. This information is critical for accurate interpretation of the geological record to infer the oxygen concentration of the oceans at various points in Earth's history. This interdisciplinary project will facilitate strong collaboration between Australian and Danish researchers in the field of marine geochemistry and paleoceanography.Read moreRead less