Thermal structure and evolution of the Australian continent. Australia contains 40% of the world's known uranium resources. Uranium, with thorium and potassium, are heat-producing elements which affect the way temperature varies within the Earth. Outcomes from this project will lead to a better understanding of the potential for geothermal energy in Australia and provide a framework for assessing Australia's uranium resource. Understanding the crustal thermal regime is also fundamental to our kn ....Thermal structure and evolution of the Australian continent. Australia contains 40% of the world's known uranium resources. Uranium, with thorium and potassium, are heat-producing elements which affect the way temperature varies within the Earth. Outcomes from this project will lead to a better understanding of the potential for geothermal energy in Australia and provide a framework for assessing Australia's uranium resource. Understanding the crustal thermal regime is also fundamental to our knowledge of many earth processes. The project will enhance Australia's international research standing, provide training for an early career researcher and contribute to the development of an environmentally sustainable Australia, a National research priority.Read moreRead less
Airborne vibration isolation for geophysical exploration. Sensitive airborne instrumentation for geophysical exploration is almost always degraded in sensitivity by the high levels of vibration and acoustic noise in survey aircraft. This project will develop a prototype robust vibration isolator with exceptional isolation across the audio frequency band. The device uses advanced techniques developed for gravitational wave detection. The system will be tested in survey aircraft using both vib ....Airborne vibration isolation for geophysical exploration. Sensitive airborne instrumentation for geophysical exploration is almost always degraded in sensitivity by the high levels of vibration and acoustic noise in survey aircraft. This project will develop a prototype robust vibration isolator with exceptional isolation across the audio frequency band. The device uses advanced techniques developed for gravitational wave detection. The system will be tested in survey aircraft using both vibration sensors and actual survey instrumentation to confirm its effectiveness, robustness and durability.Read moreRead less
Coupled subduction dynamics and continent deformations: understanding the Asian and Red Sea tectonics. Modeling slab pull forces and lithospheric deformation provides a new insight in the dynamics of plate tectonics. Unraveling the self-consistent formation of faults, rifts, shear zones and up to passive margin will further the understanding of our planet. Furthermore the application of these models to specific geological contexts will support the exploration and assessment of inaccessible Ear ....Coupled subduction dynamics and continent deformations: understanding the Asian and Red Sea tectonics. Modeling slab pull forces and lithospheric deformation provides a new insight in the dynamics of plate tectonics. Unraveling the self-consistent formation of faults, rifts, shear zones and up to passive margin will further the understanding of our planet. Furthermore the application of these models to specific geological contexts will support the exploration and assessment of inaccessible Earth's resources, such as hydrocarbons pools, located along the deep Australian continent margins, and diamonds and ore deposits, associated with continental shear zones, which potential is still to be fully discovered.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0232306
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
GPS receivers and support equipment for geophysical observatories in Antarctica. Global Positioning System (GPS) equipment and supporting electronics systems are required for monitoring of the uplift of the Earth's crust near the Lambert Glacier. This will lead to fundamental insights into the past and present-day mass-balance changes of the Antarctic
ice sheet. This research will provide critical data on the changes in the Antarctic ice sheet, a region where scientific information is currently ....GPS receivers and support equipment for geophysical observatories in Antarctica. Global Positioning System (GPS) equipment and supporting electronics systems are required for monitoring of the uplift of the Earth's crust near the Lambert Glacier. This will lead to fundamental insights into the past and present-day mass-balance changes of the Antarctic
ice sheet. This research will provide critical data on the changes in the Antarctic ice sheet, a region where scientific information is currently poorly defined or lacking altogther. Combined with other geophysical data, the results of this project will produce, for the first time, constraints on the contribution of Antarctica to global ice and sea-level models.
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Sea-level change in the Australasian region during the past 6000 years: Understanding the past to predict the future. Interactions of climate, ice, oceans, and solid earth result in complex variations sea level in time and space. This proposal develops a predictive understanding of this change through an interdisciplinary integration of geophysical theory and geologic observations. Focus is on the Australian area and on the present interglacial but the outcomes will be placed in a global frame. ....Sea-level change in the Australasian region during the past 6000 years: Understanding the past to predict the future. Interactions of climate, ice, oceans, and solid earth result in complex variations sea level in time and space. This proposal develops a predictive understanding of this change through an interdisciplinary integration of geophysical theory and geologic observations. Focus is on the Australian area and on the present interglacial but the outcomes will be placed in a global frame. Outcomes will include estimates of rates and amplitudes of sea-level change, of changes in ice volume, of land movements from isostatic and tectonic causes. It also provides the framework necessary for separating natural change from anthropogenic change during the recent past and for predicting future regional and global sea-level change on a century time scale.Read moreRead less
ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functi ....ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functional materials, ii) high-tech IT/communications/sensing materials, iii) materials solutions for manufacturing, iv) materials for a sustainable Australia, and v) emerging materials technologies. Key programs will promote interdisciplinary workshops and early career researcher interactions.Read moreRead less
Crustal fault system dynamics and earthquake prediction. The greatest challenge in earthquake science is prediction. Yet this possibility remains elusive. However, recent advances using an innovative numerical simulation model provided the first clear evidence for an underlying physical mechanism for earthquake forecasting, and observational studies have recently identified two independent precursors suggesting that this mechanism operates in the crust. The proposed project will use advanced sim ....Crustal fault system dynamics and earthquake prediction. The greatest challenge in earthquake science is prediction. Yet this possibility remains elusive. However, recent advances using an innovative numerical simulation model provided the first clear evidence for an underlying physical mechanism for earthquake forecasting, and observational studies have recently identified two independent precursors suggesting that this mechanism operates in the crust. The proposed project will use advanced simulation models and an innovative, multidisciplinary approach to obtain an improved understanding of crustal fault system dynamics with the aim of resolving the earthquake prediction question and progressing towards the scientific underpinning needed for intermediate-term earthquake forecasting.Read moreRead less
Special Research Initiatives - Grant ID: SR0354605
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
The Earth System Dynamics Network for a Sustainable Australia. Earth comprises systems of enormous complexity that sustain all life and control the distribution of mineral, energy and water resources. Thus understanding these dynamic systems provides the key to sustainable resource usage. The aim of The Earth System Dynamics Network is to facilitate scientific interactions through establishment of an earth and environmental sciences grid that links national and regional data assets with high per ....The Earth System Dynamics Network for a Sustainable Australia. Earth comprises systems of enormous complexity that sustain all life and control the distribution of mineral, energy and water resources. Thus understanding these dynamic systems provides the key to sustainable resource usage. The aim of The Earth System Dynamics Network is to facilitate scientific interactions through establishment of an earth and environmental sciences grid that links national and regional data assets with high performance computing through open sourced middleware. The result will be an unparalleled predictive capacity for complex Earth systems. The outcome will be confidence in the knowledge that underpins our decisions as stakeholders to keep Australia sustainable.Read moreRead less
Nano-machining of diamond-like carbon (DLC): Scientific basis and technical potential. Nanotechnology will be the basis for the next post-industrial revolution, and will be the main driver of future national economies. It is crucially important that at the very least Australia is a significant niche player in those developments. The project represents an effort to promote those goals.
Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but st ....Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but strong, and specialised nanoparticles made using biocompatible processes. The knowledge and methods developed will benefit the biotechnology and nanotechnology sectors, as well as research in soft-matter science, quantum computing, photonics and healthcare. The value proposition for innovation in these fields will increasingly rely on new nanomanufacturing approaches.Read moreRead less