Cretaceous marine reptiles from the Eromanga Sea - a research project focussing on the fossils of Outback Queensland. The Eromanga Sea covered large tracts of north and central Australia between 140 and 95 million years ago. Major faunal components of this inland-sea were marine reptiles, such as plesiosaurs, ichthyosaurs and sea turtles. North Qld has extensive marine fossil deposits remaining to be systematically explored. Many world-significant specimens from these strata are housed in the Au ....Cretaceous marine reptiles from the Eromanga Sea - a research project focussing on the fossils of Outback Queensland. The Eromanga Sea covered large tracts of north and central Australia between 140 and 95 million years ago. Major faunal components of this inland-sea were marine reptiles, such as plesiosaurs, ichthyosaurs and sea turtles. North Qld has extensive marine fossil deposits remaining to be systematically explored. Many world-significant specimens from these strata are housed in the Australian, Queensland and Richmond Marine Fossil museums. This project intends to resolve fundamental questions concerning the evolution, environment, lifestyle and distribution of Cretaceous marine reptiles by improving their fossil record and analysing newly discovered Australian specimens, including the world's first plesiosaur embryo.Read moreRead less
Environmental change in northern Cenozoic Australia: a multidisciplinary approach. The Intergovernmental Panel on Climate Change (IPCC) warned that by 2020 to 2050, Australia will suffer significant biodiversity loss and water shortages. Our research will document and date the evolution of Australia's biota through three cycles of climate change over the last 25 million years to quantify and thereby better anticipate the nature and dimension of threats facing our natural and cultural communities ....Environmental change in northern Cenozoic Australia: a multidisciplinary approach. The Intergovernmental Panel on Climate Change (IPCC) warned that by 2020 to 2050, Australia will suffer significant biodiversity loss and water shortages. Our research will document and date the evolution of Australia's biota through three cycles of climate change over the last 25 million years to quantify and thereby better anticipate the nature and dimension of threats facing our natural and cultural communities. We will develop innovative techniques to date prehistoric biotic and climatic events and, using a range of tracers, characterize ancient environments and groundwater. This project will assist rural and regional Australia through education and job creation in geotourism and natural resource interpretation and provide a mechanism to combat generational skill shortage.Read moreRead less
Trace element geochemistry of microbialites: towards an independent record of biogenicity, microbial communities, and seawater chemistry. A vast amount of Australia's mineral wealth is held in rocks of Precambrian age, yet those rocks are notoriously difficult to date and correlate owing to the rarity of fossils. Successful discrimination of different microbialites using biochemically sensitive trace elements will provide a firm basis and rationale for stromatolite biostratigraphy and greatly in ....Trace element geochemistry of microbialites: towards an independent record of biogenicity, microbial communities, and seawater chemistry. A vast amount of Australia's mineral wealth is held in rocks of Precambrian age, yet those rocks are notoriously difficult to date and correlate owing to the rarity of fossils. Successful discrimination of different microbialites using biochemically sensitive trace elements will provide a firm basis and rationale for stromatolite biostratigraphy and greatly increase our ability to understand the geological evolution and distribution of Precambrian rocks and resources. Additionally, a better understanding of the information content of stromatolites will yield considerable insight into the origin of life on Earth and its relationship to Earth's evolving chemistry and environment. Read moreRead less
The evolution of Australian rainforest faunas and the implications of continuing climate change. Australia's rainforest animals and ecosystems have been evolving for millions of years yet we routinely use only the last 200 years to assess changes that will affect their future - far too short a time interval to distinguish short-term perturbations from long-term trends in lineage health or community response. Our multidisciplinary team proposes to learn from 55 million years of response to rainfa ....The evolution of Australian rainforest faunas and the implications of continuing climate change. Australia's rainforest animals and ecosystems have been evolving for millions of years yet we routinely use only the last 200 years to assess changes that will affect their future - far too short a time interval to distinguish short-term perturbations from long-term trends in lineage health or community response. Our multidisciplinary team proposes to learn from 55 million years of response to rainfall and other climate change documented by the spectacular national, natural treasures in the fossil deposits of Tingamarra, Riversleigh and Rockhampton, to assess probable impacts of future environmental change and inform development of effective, long-term conservation strategies for rainforest communities. Read moreRead less
Australian fossil marine reptiles: a research and regional museum program. Australian Mesozoic marine reptile fossils are common but poorly studied. Two of the most productive localities - Richmond QLD, Coober Pedy SA - are internationally important, spanning a poorly known stratigraphic interval of marine reptile evolution and representing a high-latitude geographic region subject to near freezing conditions. Such preservation occurs nowhere else and provides a unique opportunity for anatomical ....Australian fossil marine reptiles: a research and regional museum program. Australian Mesozoic marine reptile fossils are common but poorly studied. Two of the most productive localities - Richmond QLD, Coober Pedy SA - are internationally important, spanning a poorly known stratigraphic interval of marine reptile evolution and representing a high-latitude geographic region subject to near freezing conditions. Such preservation occurs nowhere else and provides a unique opportunity for anatomical, systematic and palaeobiological investigations. Such research benefits local communities because it forms the basis for regional museum displays, generates long-term tourism revenue, and encourages geological resources to be viewed as valuable natural assets to be responsibly managed for the future.Read moreRead less
Life and environments of the Lower Cretaceous Winton Formation, western Queensland: The Winton Dinosaur Project. This proposal is for research into vertebrate assemblages from newly discovered fossil sites in the Winton Formation, western Queensland. These sites indicate that the Winton Formation is one of the most palaeontologically productive Lower Cretaceous continental sequences in Australia. Within it are preserved vertebrates (including several new types of dinosaurs, crocodilians, turtles ....Life and environments of the Lower Cretaceous Winton Formation, western Queensland: The Winton Dinosaur Project. This proposal is for research into vertebrate assemblages from newly discovered fossil sites in the Winton Formation, western Queensland. These sites indicate that the Winton Formation is one of the most palaeontologically productive Lower Cretaceous continental sequences in Australia. Within it are preserved vertebrates (including several new types of dinosaurs, crocodilians, turtles, lungfish and freshwater sharks), invertebrates, plants and trace-fossils of a restricted biome over a relatively short time span. Research into these new sites will provide us with our first-ever detailed window on northern Australia's Lower Cretaceous lowland and coastal environments during the final break-up of Gondwana.Read moreRead less