UNDERSTANDING PHASE TRANSITIONS THROUGH PRECISE STRUCTURAL STUDIES. This project will examine the fundamental nature of the structural phase transitions that are critical for the utilisation of numerous advanced materials. Researchers at Sydney University and the Australian National University in collaboration with staff at ANSTO are world leaders in the structural analysis of such materials. Through comprehensive experimental and theoretical studies of a number of such materials this project w ....UNDERSTANDING PHASE TRANSITIONS THROUGH PRECISE STRUCTURAL STUDIES. This project will examine the fundamental nature of the structural phase transitions that are critical for the utilisation of numerous advanced materials. Researchers at Sydney University and the Australian National University in collaboration with staff at ANSTO are world leaders in the structural analysis of such materials. Through comprehensive experimental and theoretical studies of a number of such materials this project will enhance the ability of industry to develop new and improved materials.Read moreRead less
The effects of local strain on the crystal chemistry of solid solutions. The concept of the solid solution, the substitution of one kind of atom for another in a crystal structure, is a central idea in both mineral sciences and solid state chemistry. Such atomic substitutions alter local crystal chemistry and hence always introduce strain into crystal lattices. In this project we aim to characterize this substitutional strain. Ultimately this should lead to a better understanding of the geologic ....The effects of local strain on the crystal chemistry of solid solutions. The concept of the solid solution, the substitution of one kind of atom for another in a crystal structure, is a central idea in both mineral sciences and solid state chemistry. Such atomic substitutions alter local crystal chemistry and hence always introduce strain into crystal lattices. In this project we aim to characterize this substitutional strain. Ultimately this should lead to a better understanding of the geological history of rocks, improvements in metal recovery from ores and to the design and synthesis of new materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100236
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Facilities for spectroscopy and diffraction at high pressures. The provision of infrastructure for the study of novel materials under high pressures will enhance Australia's capability in creating new materials and in creating new devices that meet needs in communication, environment and medicine applications. The new facility will enable researchers to understand the response of structures to extreme pressures and will exploit the unique capabilities of the synchrotron light.
Structural studies of titanyl and zirconyl sulfate hydrates. This project aims to provide knowledge that will inform the development of new methods of extraction and refining of titanium from ilmenite ores. In addition the knowledge gained in this research will aid the design and synthesis advanced ceramics and nanocomposites, and will provide the fundamental understanding of material structures that are required to adequately control the formation of such materials.
Controlling precipitation processes in the production of value-added zirconia. Doral Specialty Chemicals produces specialised zirconia products from zircon sands mined in WA. Doping the zirconia with metals such as yttrium and aluminium can produce advanced ceramics, with applications in areas such as solid oxide fuel cells and oxygen sensors. The aim of this project is to improve the fundamental understanding of the chemistry in the initial processing steps, so that the process can be readily m ....Controlling precipitation processes in the production of value-added zirconia. Doral Specialty Chemicals produces specialised zirconia products from zircon sands mined in WA. Doping the zirconia with metals such as yttrium and aluminium can produce advanced ceramics, with applications in areas such as solid oxide fuel cells and oxygen sensors. The aim of this project is to improve the fundamental understanding of the chemistry in the initial processing steps, so that the process can be readily modified to produce new doped zirconia ceramics, without the extensive empirical process development currently required. The resulting ability to quickly produce new compositions on a commercial scale will put this industry in a world-leading position, dramatically increasing the added value of the zirconia products.Read moreRead less
Enzyme-Mediated Machining of Chelators to Bind and Recover Valuable Metals. Metals are critical components of electronic devices and electrical products. Rapid disposal cycles create a major problem in managing e-waste metals and identifies an opportunity in the circular economy for recovery and re-use. Organic compounds that bind metal ions (chelators) are useful but could be improved to select a target metal from a mixture. This project aims to dissect a method used by bacteria to biosynthesiz ....Enzyme-Mediated Machining of Chelators to Bind and Recover Valuable Metals. Metals are critical components of electronic devices and electrical products. Rapid disposal cycles create a major problem in managing e-waste metals and identifies an opportunity in the circular economy for recovery and re-use. Organic compounds that bind metal ions (chelators) are useful but could be improved to select a target metal from a mixture. This project aims to dissect a method used by bacteria to biosynthesize chelators and hijack this to bioengineer new classes of chelators. Outcomes include new chelators and advanced knowledge of metal selectivity, with potential environmental and economic benefits arising from recovery of valuable metals. The project will benefit chemical biology research training for real-world applications.Read moreRead less
Special Research Initiatives - Grant ID: SR0354751
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Australian Bio-Metals Research Network. The aim of the Bio-Metals Research Network is to connect the extensive Australian expertise in the study of metal ions in relation to the Environment, Health and Frontier Technologies. The Network is inter-disciplinary and brings together over 50 group leaders in the biological, biomedical and physical sciences. A major aim of the Network will be to provide a molecular understanding of biological and environmental processes and disease states as well as pr ....Australian Bio-Metals Research Network. The aim of the Bio-Metals Research Network is to connect the extensive Australian expertise in the study of metal ions in relation to the Environment, Health and Frontier Technologies. The Network is inter-disciplinary and brings together over 50 group leaders in the biological, biomedical and physical sciences. A major aim of the Network will be to provide a molecular understanding of biological and environmental processes and disease states as well as providing new materials for the development of new technologies. The Network will interact in research and education with Bio-Metals groups around the world and will develop collaborative funding proposalsRead moreRead less
Chemistry of the Transport of Nutrient Copper in Biological Cells. Nutrient trace metals such as copper are needed for enzymes by living organisms but are toxic in excess. Defects in copper metabolism cause Menkes and Wilson diseases in humans and there are direct connections to neurodegenerative diseases (eg, Alzheimer, Parkinson, Creutzfeldt-Jakob, motor neuron diseases). It is crucial to understand how healthy cells control toxic but essential copper so that enlightened intervention is possib ....Chemistry of the Transport of Nutrient Copper in Biological Cells. Nutrient trace metals such as copper are needed for enzymes by living organisms but are toxic in excess. Defects in copper metabolism cause Menkes and Wilson diseases in humans and there are direct connections to neurodegenerative diseases (eg, Alzheimer, Parkinson, Creutzfeldt-Jakob, motor neuron diseases). It is crucial to understand how healthy cells control toxic but essential copper so that enlightened intervention is possible when disturbances of copper metabolism become pathological. The chemistry of key molecules will be studied to reveal their essential properties and thereby to understand the molecular basis of the copper-linked diseases.Read moreRead less
Molecular Characterisation of Metal Transport Proteins. The trace metals are essential to life. The secrets of their catalytic and structural roles are under intensive scrutiny. The molecular mechanisms which regulate concentrations of nutrient metals in biological cells remain poorly understood. Errors in metal metabolism cause disease. For example, defects in copper metabolism cause Menkes and Wilson diseases in humans and there are connections of copper and zinc to neuro-degenerative disea ....Molecular Characterisation of Metal Transport Proteins. The trace metals are essential to life. The secrets of their catalytic and structural roles are under intensive scrutiny. The molecular mechanisms which regulate concentrations of nutrient metals in biological cells remain poorly understood. Errors in metal metabolism cause disease. For example, defects in copper metabolism cause Menkes and Wilson diseases in humans and there are connections of copper and zinc to neuro-degenerative diseases such as Alzheimer and Creutzfeldt-Jakob (mad cow). This project will study the chemistry of metabolic pathways responsible for import of nutrient copper and other metals into biological cells.Read moreRead less
Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are relat ....Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are related to the properties of the enzymes themselves or the ways in which their experiments have been conducted.Read moreRead less