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.
An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will b ....An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will be enhanced considerably by working on this project. Further, we will promote the relationship between the fundamental science of polar crystalline materials and practical applications. If successful, the results will enhance Australia's capacity and standing in this highly competitive area. Read moreRead less
Coupled Structural and Elastic Response Studies of the Phase Transformation Behaviour of Environment-Friendly, Lead-free Piezoceramics. The ultimate aim of this project is to identify high performance, environment-friendly i.e. lead free, piezoceramic materials capable of replacing the currently market dominant, lead-based materials. Such piezoceramics have widespread industrial applications. Understanding the factors that control the capacity of such materials to respond to applied stress or el ....Coupled Structural and Elastic Response Studies of the Phase Transformation Behaviour of Environment-Friendly, Lead-free Piezoceramics. The ultimate aim of this project is to identify high performance, environment-friendly i.e. lead free, piezoceramic materials capable of replacing the currently market dominant, lead-based materials. Such piezoceramics have widespread industrial applications. Understanding the factors that control the capacity of such materials to respond to applied stress or electric field is critical to the discovery, optimization and, ultimately, industrial exploitation 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. Development of advanced materials is a designated National Research Priority area. Read moreRead less
Understanding nanostructure in lead-containing piezoceramics - the key to improved and environmentally-friendly materials. Lead-containing piezoelectric ceramics form the basis of multi-billion dollar industries, posing an increasingly serious environmental threat due to the toxicity of lead. By obtaining a detailed understanding of how their properties arise from their nanoscale structure and chemistry, our research will lead to improvements in existing materials and aid the quest for environme ....Understanding nanostructure in lead-containing piezoceramics - the key to improved and environmentally-friendly materials. Lead-containing piezoelectric ceramics form the basis of multi-billion dollar industries, posing an increasingly serious environmental threat due to the toxicity of lead. By obtaining a detailed understanding of how their properties arise from their nanoscale structure and chemistry, our research will lead to improvements in existing materials and aid the quest for environmentally-friendly alternatives. We will use a methodology for the elucidation of local structure and dynamics in which we are world leaders. The project will further enhance our standing in the field, provide excellent research training for students and early-career researchers and highlight the power and potential of Australia's new Synchrotron and OPAL research reactor.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: LE0668302
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Floating-zone Crystal Growth Facility. Optical floating-zone furnaces are powerful and efficient tools for the discovery and characterisation of new materials. They are widely used in the solid-state chemistry, condensed-matter physics, materials science, and engineering communities. This optical floating-zone furnace, the first in Australia, will support and encourage the growing number of local researchers in these fields. It will allow them to take much better advantage of the new research re ....Floating-zone Crystal Growth Facility. Optical floating-zone furnaces are powerful and efficient tools for the discovery and characterisation of new materials. They are widely used in the solid-state chemistry, condensed-matter physics, materials science, and engineering communities. This optical floating-zone furnace, the first in Australia, will support and encourage the growing number of local researchers in these fields. It will allow them to take much better advantage of the new research reactor and synchrotron being constructed in Australia by maximising their ability to grow crystals of technologically and scientifically important materials, particularly electronic and magnetic materials, for fundamental and applied research at those facilities.Read moreRead less
Dual-ion electrochemical systems. The project aims to develop dual-ion electrochemical systems. In contrast to conventional single-ion rechargeable cells, the charge storage process in the cathodes of these devices is facilitated by a second, negative ion. Dual-ion systems represent robust alternatives to current lithium-ion batteries and lithium-ion capacitors, addressing their sustainability and energy density limitations. The project’s outcomes are in the form of new sustainable energy storag ....Dual-ion electrochemical systems. The project aims to develop dual-ion electrochemical systems. In contrast to conventional single-ion rechargeable cells, the charge storage process in the cathodes of these devices is facilitated by a second, negative ion. Dual-ion systems represent robust alternatives to current lithium-ion batteries and lithium-ion capacitors, addressing their sustainability and energy density limitations. The project’s outcomes are in the form of new sustainable energy storage technologies with attrative energy and power densities for a wide range of applications. This should provide a significant benefit to society, the economy and the environment in enabling an easier transition to clean energy and ensuring energy security in Australia.Read moreRead less
Crystal-chemical tuning of order and disorder: a strategy for the discovery of novel solid state ionic conductors. The ultimate aim of this project is to discover novel ionic conductors suitable for use in energy technologies. By identifying, comprehensively characterising and optimising a number of such materials, this project will provide industry with the opportunity to implement them in new and improved devices.