Hydrogen generation by subsurface iron mineral transformations. Aim
The aim of this project is to elucidate key factors responsible for natural hydrogen generation in Australian subsurface environments.
Significance
Large amounts of this valuable resource are produced naturally with estimates of production rates of this “gold” hydrogen at least 100 times the annual demand for this critical resource.
Expected Outcomes
Based on improved understanding of the source of natural hydrogen, predictive ....Hydrogen generation by subsurface iron mineral transformations. Aim
The aim of this project is to elucidate key factors responsible for natural hydrogen generation in Australian subsurface environments.
Significance
Large amounts of this valuable resource are produced naturally with estimates of production rates of this “gold” hydrogen at least 100 times the annual demand for this critical resource.
Expected Outcomes
Based on improved understanding of the source of natural hydrogen, predictive tools will be developed that will assist in assessing the viability in Australia of hydrogen exploration and engineered retrieval.
Benefits
Ready access to naturally produced hydrogen could enable Australia to replace hydrogen that is currently generated via the use of unabated hydrocarbons.Read moreRead less
Visualising molecular level detail in single cells and intact tissues. The goal of this project is to deliver a new toolkit for imaging cells at an unprecedented resolution and level of chemical detail. We will expand the capabilities of two existing, but complementary, methods: optical fluorescence microscopy with responsive probes and X-ray fluorescence imaging. Expected outcomes include improved techniques and benchmarks for visualising bacterial and mammalian cells; development of new molecu ....Visualising molecular level detail in single cells and intact tissues. The goal of this project is to deliver a new toolkit for imaging cells at an unprecedented resolution and level of chemical detail. We will expand the capabilities of two existing, but complementary, methods: optical fluorescence microscopy with responsive probes and X-ray fluorescence imaging. Expected outcomes include improved techniques and benchmarks for visualising bacterial and mammalian cells; development of new molecules for elucidating cellular chemistry; better utilisation of valuable synchrotron resources; and greater understanding of the strengths and limitations of current microscopy workflows. Results should benefit the biotechnology sector, and may lead to improved medical, diagnostic, and bioremediation capacity.Read moreRead less
Targeted electrolyte design for high energy aqueous batteries. The Project aims to develop a new generation, high-energy aqueous battery. A range of new aqueous electrolytes with large working window at low concentration will be designed to replace traditional, flammable and toxic organic electrolytes, and; low-cost and multi-electron reaction materials will be developed as high-capacity electrodes to replace traditional intercalation-type materials. The Project will establish the structure-prop ....Targeted electrolyte design for high energy aqueous batteries. The Project aims to develop a new generation, high-energy aqueous battery. A range of new aqueous electrolytes with large working window at low concentration will be designed to replace traditional, flammable and toxic organic electrolytes, and; low-cost and multi-electron reaction materials will be developed as high-capacity electrodes to replace traditional intercalation-type materials. The Project will establish the structure-property relationship for electrolytes and interphases via advanced characterization(s) and computation. The new battery will be safe, energetic and sustainable for the billion-dollar energy storage market for electric vehicle, and smart-grid whilst addressing concurrently battery safety and boosted energy-density.Read moreRead less
Unravelling how aquatic coastal networks regulate nitrogen removal . The aim of this project is to determine the nitrogen removal pathways of the coastal zone using a number of innovative field and modelling approaches. Little is known about how the complex coastal landscape controls trade-offs that maximise nitrogen removal but minimise nitrous oxide (a potent greenhouse gas) emissions. The outcomes of this study will significantly advance our understanding of the coastal zone in regional and g ....Unravelling how aquatic coastal networks regulate nitrogen removal . The aim of this project is to determine the nitrogen removal pathways of the coastal zone using a number of innovative field and modelling approaches. Little is known about how the complex coastal landscape controls trade-offs that maximise nitrogen removal but minimise nitrous oxide (a potent greenhouse gas) emissions. The outcomes of this study will significantly advance our understanding of the coastal zone in regional and global nitrogen budgets. This will provide significant benefits such as a new science-based quantitative framework to facilitate best practice management to reduce terrestrial nitrogen loads and associated downstream impacts such as eutrophication, and reduce nitrous oxide emissions and associated global warming.
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East Antarctica: subglacial heat flux constraints for ice sheet modelling. This project aims to quantify the heat flux from the East Antarctic continent into the base of the ice sheet via the derivation of a large geochemical database, together with elevation-based modelling and new heat flux measurements in regions formerly contiguous with East Antarctica. This subglacial heat flux is poorly constrained in current ice sheet models, but directly affects ice sheet behaviour. The output of this pr ....East Antarctica: subglacial heat flux constraints for ice sheet modelling. This project aims to quantify the heat flux from the East Antarctic continent into the base of the ice sheet via the derivation of a large geochemical database, together with elevation-based modelling and new heat flux measurements in regions formerly contiguous with East Antarctica. This subglacial heat flux is poorly constrained in current ice sheet models, but directly affects ice sheet behaviour. The output of this project will be a greatly improved heat flux map for East Antarctica that can be used in ice sheet modelling studies. This should drive significant improvement in models for the evolution of the East Antarctic Ice Sheet, resulting in more accurate projections of ice discharge and associated sea level change.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC190100034
Funder
Australian Research Council
Funding Amount
$3,574,272.00
Summary
ARC Training Centre for Green Chemistry in Manufacturing. Globally, there is demand for products that are effective, safe and environmentally benign. The ARC Training Centre for Green Chemistry in Manufacturing aims to utilise local and global experts to provide the next generation of Australian chemists and engineers, with skills to develop innovative products and processes that are intrinsically safe and benign. It will provide collaborating partners and the broader manufacturing industry with ....ARC Training Centre for Green Chemistry in Manufacturing. Globally, there is demand for products that are effective, safe and environmentally benign. The ARC Training Centre for Green Chemistry in Manufacturing aims to utilise local and global experts to provide the next generation of Australian chemists and engineers, with skills to develop innovative products and processes that are intrinsically safe and benign. It will provide collaborating partners and the broader manufacturing industry with new products and processes with strong export potential, and the ability to respond to the market pressures, underpinned by green chemistry and sustainable principles. Resulting benefits include increased competitiveness for Australia's manufacturing industry, jobs, social as well as environmental benefitsRead moreRead less
Mapping mineral systems of deep Australia. We aim at enabling mineral resource discoveries by calibrating geophysical surveys using geochemical and petrophysical properties measured on mantle samples brought to the surface by recent volcanoes. National geophysical surveys deliver images of geophysical gradients in the deeper part of the Australian continent. The interpretation of these gradients in geological terms and in terms of economic mineral systems is the key to unlock deep exploration su ....Mapping mineral systems of deep Australia. We aim at enabling mineral resource discoveries by calibrating geophysical surveys using geochemical and petrophysical properties measured on mantle samples brought to the surface by recent volcanoes. National geophysical surveys deliver images of geophysical gradients in the deeper part of the Australian continent. The interpretation of these gradients in geological terms and in terms of economic mineral systems is the key to unlock deep exploration success. This project will turn Australia’s investment in National geophysical surveys into new discoveries of base metals. The benefit stems from enabling the transition to a clean economy which requires a much broader range of critical minerals and a larger quantity of base metals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100054
Funder
Australian Research Council
Funding Amount
$1,341,398.00
Summary
Dedicated High-throughput 3D-Electron Diffractometer. This proposal aims to install the first dedicated high-throughput 3D-electron diffractometer in the Southern Hemisphere, and one of the first in the world. It will be able to rapidly solve the atomic-scale structures of molecules and materials for which this is now extremely difficult and time-consuming – or impossible – due to the inability to grow large enough crystals for traditional X-ray diffraction. It will thus provide a significant ad ....Dedicated High-throughput 3D-Electron Diffractometer. This proposal aims to install the first dedicated high-throughput 3D-electron diffractometer in the Southern Hemisphere, and one of the first in the world. It will be able to rapidly solve the atomic-scale structures of molecules and materials for which this is now extremely difficult and time-consuming – or impossible – due to the inability to grow large enough crystals for traditional X-ray diffraction. It will thus provide a significant advantage for chemists, physicists, biologists, geologists, and engineers who rely on detailed structural knowledge to rationally optimise the properties of their compounds, from pharmaceutical activity to carbon capture to superconductivity, to the substantial benefit of multiple national priority areas.Read moreRead less