Future copper metallurgy for the age of e-mobility and the circular economy. Copper, nickel, cobalt, chromium and tin metals are essential for the manufacture of new battery materials, electrical and electronic devices and technologies that will enable the global transition to sustainable energy systems. There are major technical challenges associated with the industrial scale high temperature production, separation and recycling of these metals. The aim of the present study is develop advanced ....Future copper metallurgy for the age of e-mobility and the circular economy. Copper, nickel, cobalt, chromium and tin metals are essential for the manufacture of new battery materials, electrical and electronic devices and technologies that will enable the global transition to sustainable energy systems. There are major technical challenges associated with the industrial scale high temperature production, separation and recycling of these metals. The aim of the present study is develop advanced chemical thermodynamic databases and models that can be used to predict the outcomes of these complex chemical reactions, and in doing so provide the industry with the vital fundamental scientific information and tools needed to be able to design and improve new, more efficient metal production and recycling technologies. Read moreRead less
Thermodynamic basis for ironmaking and slag recycling in circular economy. This project aims to develop new, powerful state-of-the-art computer-based tools to predict the outcomes of complex chemical reactions, high-temperature ironmaking and slag recycling processes. Globally, over 1 billion tonnes of iron are produced each year consuming 30 billion billion (Quintillion) Joules energy! and creating over 300 million tonnes of molten oxides (slags). Our industry partners need new advanced thermod ....Thermodynamic basis for ironmaking and slag recycling in circular economy. This project aims to develop new, powerful state-of-the-art computer-based tools to predict the outcomes of complex chemical reactions, high-temperature ironmaking and slag recycling processes. Globally, over 1 billion tonnes of iron are produced each year consuming 30 billion billion (Quintillion) Joules energy! and creating over 300 million tonnes of molten oxides (slags). Our industry partners need new advanced thermodynamic databases and computer models with which to optimise their major industrial processes and develop new technologies. By delivering these tools, this project expects to benefit both industry and the community through improved process efficiencies, and reductions in energy usage, pollutants, and environmental impacts.
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Microstructure control of hot-dip coated Al-Zn based alloy layers on steel . The process of hot-dip metal coating of steel has evolved to provide reliable products that find widespread application in many industries, including building and construction. This project aims to address and understand an intermittent processing problem using innovative approaches involving characterisation by synchrotron techniques and state-of-the art microscopy. Expected outcomes include increased manufacturing e ....Microstructure control of hot-dip coated Al-Zn based alloy layers on steel . The process of hot-dip metal coating of steel has evolved to provide reliable products that find widespread application in many industries, including building and construction. This project aims to address and understand an intermittent processing problem using innovative approaches involving characterisation by synchrotron techniques and state-of-the art microscopy. Expected outcomes include increased manufacturing efficiencies by identifying the cause of an intermittent processing defect and implementing methods of controlling this defect. This will help BlueScope and Australia maintain a world-leading reputation for high-quality coating products for domestic and export markets.Read moreRead less
Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing an ....Data-driven monitoring of raceway dynamics in ironmaking blast furnaces. Raceway dynamics in ironmaking blast furnaces affect operational stability and cost considerably, yet their dynamic behaviour has not been well monitored online. The project aims to develop a data-driven model for monitoring the internal state of gas-solid-powder reacting flow in the raceway and predicting raceway anomalies online. It will be achieved by combining particle-fluid numerical simulations with data processing and reduced-order state observer, supported by lab/plant experiments, and collaborating with two industry partners from coal and steel industries. The project outcomes including codes, models and raceway control strategies can help promote Australian metallurgical coal's global markets and ultimately the Australian economy.Read moreRead less
New Lead-Free Brass Solutions for Drinking Water Applications. The aim of this Linkage Project is to provide viable material solutions to address the health problem of Lead-contamination in drinking water arising from Leaded-brass plumbing products and the impact Lead-removal from brass will have on the brass industry. In order to achieve this, this project engages leading multidisciplinary researchers along with Australian and international industry partners from across the brass industry suppl ....New Lead-Free Brass Solutions for Drinking Water Applications. The aim of this Linkage Project is to provide viable material solutions to address the health problem of Lead-contamination in drinking water arising from Leaded-brass plumbing products and the impact Lead-removal from brass will have on the brass industry. In order to achieve this, this project engages leading multidisciplinary researchers along with Australian and international industry partners from across the brass industry supply and sales network. This project seeks to identify and harness the key material-product attributes required to develop and implement new, lead-free alloy alternatives that meet health-compliance, production and commercial viability, that offer benefits across the industry network and health benefits to society.Read moreRead less
The molecular basis for efficacy at G protein coupled receptors. This project aims to investigate the molecular steps underlying the relationship between sensing by signal-transmitting proteins on the cell surface called G protein-coupled receptors and cellular response. The project aims to build on studies that have sought to understand the primary, molecular basis for this cellular volume control. This project seeks to use these novel approaches to fill this knowledge gap, providing a deeper u ....The molecular basis for efficacy at G protein coupled receptors. This project aims to investigate the molecular steps underlying the relationship between sensing by signal-transmitting proteins on the cell surface called G protein-coupled receptors and cellular response. The project aims to build on studies that have sought to understand the primary, molecular basis for this cellular volume control. This project seeks to use these novel approaches to fill this knowledge gap, providing a deeper understanding of how physiology and medicines work. The project expects to expand fundamental understanding of signal transmission at this receptor class. This project will deliver benefits including expanded basic knowledge and a contribution to future improvements in drug development.Read moreRead less
New copper lead processes for critical metals recovery from complex sources. The project aims to facilitate the development of novel processes for the efficient recovery and recycling of critical and strategic metals from complex sources such as sophisticated electronic components and hazardous wastes. The project expects to generate advanced chemical thermodynamic models and tools, to predict the products of complex reactions. This project should lead to improved recovery of various metals requ ....New copper lead processes for critical metals recovery from complex sources. The project aims to facilitate the development of novel processes for the efficient recovery and recycling of critical and strategic metals from complex sources such as sophisticated electronic components and hazardous wastes. The project expects to generate advanced chemical thermodynamic models and tools, to predict the products of complex reactions. This project should lead to improved recovery of various metals required for the manufacture of advanced materials and devices used in industry.Read moreRead less
Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and ....Understanding dynamic interfaces in electrochemical systems. This project aims to develop nanoscale characterisation methods to understand dynamic processes in zinc-ion batteries and high temperature electrolysis systems under real working (in operando) conditions. This project expects to reveal critical solid-liquid and solid-gas interfacial processes in these two distinctly different electrochemical systems. The expected outcomes include improved understanding of electrochemical interfaces and improved tools and methods to observe nanoscale interfacial processes. This information can be used to underpin mechanistic models, which will facilitate new materials design. Read moreRead less
Nanoarchitectured anti-corrosion coatings for zinc-plated steel. Zinc-plated steel is widely used in buildings, households and vehicles, but the long-term performance is limited due to corrosion resulting from exposure to high humidity or alkaline conditions. Currently, available chromium coatings are toxic, while polymeric coatings lack durability. This project aims to use nanotechnology to develop highly effective, multifunctional anti-corrosive coatings in which long-term protection is achiev ....Nanoarchitectured anti-corrosion coatings for zinc-plated steel. Zinc-plated steel is widely used in buildings, households and vehicles, but the long-term performance is limited due to corrosion resulting from exposure to high humidity or alkaline conditions. Currently, available chromium coatings are toxic, while polymeric coatings lack durability. This project aims to use nanotechnology to develop highly effective, multifunctional anti-corrosive coatings in which long-term protection is achieved by controlling the wettability and self-healing properties. The project is excepted to generate new knowledge in coating materials that limit corrosion and address environmental problems. This advanced manufacturing technology should be of high-value benefit to manufacturers and consumers of zinc-plated steel.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101233
Funder
Australian Research Council
Funding Amount
$447,237.00
Summary
Developing the toolbox of compounds that target acid-sensing proteins. This project aims to examine the interaction between acid-sensing proteins and their modulatory compounds. Animals, including humans, must sense changes in environmental acidity to successfully interact with the surrounding world. Expected outcomes of the project include a better understanding of which regions of these proteins detect acidity, and to develop new compounds that modulate the proteins’ function. This would advan ....Developing the toolbox of compounds that target acid-sensing proteins. This project aims to examine the interaction between acid-sensing proteins and their modulatory compounds. Animals, including humans, must sense changes in environmental acidity to successfully interact with the surrounding world. Expected outcomes of the project include a better understanding of which regions of these proteins detect acidity, and to develop new compounds that modulate the proteins’ function. This would advance our fundamental knowledge in the physiological process of acid sensing. This expects to provide significant benefits, by aiding the potential development of agrochemicals and pain-relieving medications that regulate acid-sensing protein function, resulting in economic benefit to Australia via these new products.
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