Drying and dying in Australia: extraordinary creatures and climate change 15 million years ago. Australia's globally distinctive mammals were confronted 15 million years ago by a climate plunge from lush greenhouse to dry icehouse conditions. In northern Queensland, in the World Heritage-listed cave known as AL90, fossil-rich deposits span this interval of change. Entombed are dozens of extraordinarily well-preserved skulls and articulated skeletons including a growth series from pouch-young to ....Drying and dying in Australia: extraordinary creatures and climate change 15 million years ago. Australia's globally distinctive mammals were confronted 15 million years ago by a climate plunge from lush greenhouse to dry icehouse conditions. In northern Queensland, in the World Heritage-listed cave known as AL90, fossil-rich deposits span this interval of change. Entombed are dozens of extraordinarily well-preserved skulls and articulated skeletons including a growth series from pouch-young to adults of a rare, possibly sloth-like marsupial as well as more familiar kangaroos, thylacines and bats. Our fossil research will help align Australian records of biotic change with global palaeoclimatic events and provide a benchmark for measuring the nature and rate of environmental and biotic change that continues to transform our nation.Read moreRead less
Life and times of Beringian biota from luminescence and radiocarbon dating of sedimentary DNA: chronologies for palaeoenvironmental and archaeological archives. This study will yield important new data on the time of entry of humans into a previously uninhabited continent (North America) and the record of subsequent human-environment interactions. The same broad issues apply to Australia, so understanding the sequence and causes of events in Beringia will provide insights into human disruption o ....Life and times of Beringian biota from luminescence and radiocarbon dating of sedimentary DNA: chronologies for palaeoenvironmental and archaeological archives. This study will yield important new data on the time of entry of humans into a previously uninhabited continent (North America) and the record of subsequent human-environment interactions. The same broad issues apply to Australia, so understanding the sequence and causes of events in Beringia will provide insights into human disruption of the Australian ecosystem. The development of improved techniques in palaeogenetics and geochronology will benefit researchers worldwide, increase the capacity for commercial services, and enhance Australia's international standing in cutting edge science. We will train high-quality graduate students and create new collaborative initiatives and opportunities for research, exchange, training and education.Read moreRead less
Pleistocene evolutionary dynamics and past environments of Siberia: Reconstructions using luminescence dating of ancient DNA sedimentary archives. This study will yield critical new insights into faunal-environment interactions in Siberia and their long-term implications for the evolution and extinction of Siberia's biota. These fundamental issues are of relevance to Australian archaeology, palaeontology and biogeography, and so our discoveries are of direct interest to Australian researchers st ....Pleistocene evolutionary dynamics and past environments of Siberia: Reconstructions using luminescence dating of ancient DNA sedimentary archives. This study will yield critical new insights into faunal-environment interactions in Siberia and their long-term implications for the evolution and extinction of Siberia's biota. These fundamental issues are of relevance to Australian archaeology, palaeontology and biogeography, and so our discoveries are of direct interest to Australian researchers studying these disciplines. The methodological advancements in OSL dating and DNA techniques that will accompany this research will enhance Australia's international scientific standing and create new opportunities for collaborative initiatives in both cutting-edge scientific research and consulting activities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100721
Funder
Australian Research Council
Funding Amount
$451,836.00
Summary
A new dating tool for Australia’s cultural and natural history. This project aims to advance Australian geochronology and Earth magnetic field research by constructing high-quality paleomagnetic records from stalagmites and lake sediments. It is expected that this project will provide a new dating capacity in Australia for academia, cultural heritage and government in a region with rich Indigenous history. This should provide significant benefits advancing our understanding of Australia’s timeli ....A new dating tool for Australia’s cultural and natural history. This project aims to advance Australian geochronology and Earth magnetic field research by constructing high-quality paleomagnetic records from stalagmites and lake sediments. It is expected that this project will provide a new dating capacity in Australia for academia, cultural heritage and government in a region with rich Indigenous history. This should provide significant benefits advancing our understanding of Australia’s timeline and raising appreciation of the oldest continuous living culture in the world. The ancient geomagnetic field data will also be integrated into geomagnetic field models as part of the international effort understanding Earth’s magnetic field evolution and future impact on society.Read moreRead less
Novel tools for dating explosive volcanic eruptions in the critical window. This project will develop novel dating methods necessary for precise reconstruction of the eruption histories of super-volcanoes in the Asia-Pacific region over the last million years. The project outcomes will provide better models for predicting super-eruptions, thereby informing global climate change research, urban planning, and transport and telecommunications infrastructure engineering. Results will also improve ex ....Novel tools for dating explosive volcanic eruptions in the critical window. This project will develop novel dating methods necessary for precise reconstruction of the eruption histories of super-volcanoes in the Asia-Pacific region over the last million years. The project outcomes will provide better models for predicting super-eruptions, thereby informing global climate change research, urban planning, and transport and telecommunications infrastructure engineering. Results will also improve existing volcanic risk models used by insurers to quantify volcanic risks and calculate expected losses from volcanic eruptions, and greatly improve our ability to use eruption deposits as time markers for important events in human evolution.Read moreRead less
Present-Day Stress and Tectonics of Deltas and Deepwater Fold-Thrust Belts. The key benefit of the project will be to advance our understanding of the geological processes that control the development of deltas, and of the fold-thrust belts located in deepwater adjacent to deltas, by analysis of five examples worldwide. Global hydrocarbon exploration is successfully moving to deepwater fold-thrust belts. One of Australia's key under-explored frontier petroleum provinces is the Australian Bight B ....Present-Day Stress and Tectonics of Deltas and Deepwater Fold-Thrust Belts. The key benefit of the project will be to advance our understanding of the geological processes that control the development of deltas, and of the fold-thrust belts located in deepwater adjacent to deltas, by analysis of five examples worldwide. Global hydrocarbon exploration is successfully moving to deepwater fold-thrust belts. One of Australia's key under-explored frontier petroleum provinces is the Australian Bight Basin. The prospective parts of this basin comprise delta/deepwater fold-thrust belt systems and analysis of more data-rich systems worldwide will help provide the geological knowledge required to help re-invigorate exploration in the Bight Basin.Read moreRead less
Crustal Stress Field of SE Asia. The key project benefit is to advance our fundamental understanding of tectonic processes such as sedimentary basin development and continental collision. It has major implications for natural hazard assessment and resources exploration in SE Asia, consistent with Australia's participation in the APEC Energy Working Group. The project has major ancillary benefits. It will strengthen international links between Australia, SE Asia, the UK, USA and Germany. It will ....Crustal Stress Field of SE Asia. The key project benefit is to advance our fundamental understanding of tectonic processes such as sedimentary basin development and continental collision. It has major implications for natural hazard assessment and resources exploration in SE Asia, consistent with Australia's participation in the APEC Energy Working Group. The project has major ancillary benefits. It will strengthen international links between Australia, SE Asia, the UK, USA and Germany. It will provide high-quality research and training experience for the APD and PhD student involved, whom will spend time with research groups and oil companies in Australia, UK, USA and SE Asia. Finally, the project will increase the institutional capacity for contract research in SE Asia.Read moreRead less
Present-Day Crustal Stresses of NW Borneo: Neotectonics of an Active Collisional Margin. The key project benefit is to advance understanding of continental collision and the early evolution of mountain belts using a region with an unrivalled database from hydrocarbon exploration. The project will improve understanding of Australia's northern, collisional margins and petroleum exploration there, which is less advanced than in Borneo. The project has major ancillary benefits. It will strengthen in ....Present-Day Crustal Stresses of NW Borneo: Neotectonics of an Active Collisional Margin. The key project benefit is to advance understanding of continental collision and the early evolution of mountain belts using a region with an unrivalled database from hydrocarbon exploration. The project will improve understanding of Australia's northern, collisional margins and petroleum exploration there, which is less advanced than in Borneo. The project has major ancillary benefits. It will strengthen international links between Australia, Brunei, Malaysia and Germany. It will provide high quality research training for the RA and PhDs whom will spend time at the Universities of Brunei and Karlsruhe and at Shell Brunei and Shell Malaysia. Finally the project will increase the institutional capacity for contract research in SE Asia.Read moreRead less
Environmental Evolution of the Willandra Lakes World Heritage Area. The Willandra Lakes World Heritage Area ranks as the most significant area for documenting Australia TMs unique cultural and environmental history. Parts of this remarkable archive are being lost through erosion. This project is the basis for a strategic research alliance between the custodians and managers of the area and leading Australian research institutions to build a picture of the continent TMs human and environmental hi ....Environmental Evolution of the Willandra Lakes World Heritage Area. The Willandra Lakes World Heritage Area ranks as the most significant area for documenting Australia TMs unique cultural and environmental history. Parts of this remarkable archive are being lost through erosion. This project is the basis for a strategic research alliance between the custodians and managers of the area and leading Australian research institutions to build a picture of the continent TMs human and environmental history before this evidence is irretrievably lost. Lake Mungo is known to Australians as the site of the world TMs earliest cremation and a window into our remote past. We will provide novel insights into the evolution of the Australian landscape, its fragile environment and the history of its resilient inhabitants.Read moreRead less
Reducing 3D geological uncertainty via improved data interpretation methods. The integrity of 3D geological models heavily relies on robust and consistent data interpretation. This project proposes an innovative workflow for 3D modelling to minimise geological uncertainty. Advanced visualisation and intelligent decision support methods will be combined to assist geological interpretation. Feedback on interpretation will be provided based on data evidence and consistency with expert knowledge and ....Reducing 3D geological uncertainty via improved data interpretation methods. The integrity of 3D geological models heavily relies on robust and consistent data interpretation. This project proposes an innovative workflow for 3D modelling to minimise geological uncertainty. Advanced visualisation and intelligent decision support methods will be combined to assist geological interpretation. Feedback on interpretation will be provided based on data evidence and consistency with expert knowledge and previous interpretations. The process can be considered as a spelling and grammar checker for geological interpretation. The outcome of this study aims to achieve an improved workflow that reduces model uncertainty, resulting in a broad and significant impact on the management of Australian mineral, energy and water resources.Read moreRead less