Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453320
Funder
Australian Research Council
Funding Amount
$347,886.00
Summary
Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable ....Advanced Spectroscopy for Nano-characterisation of Materials Chemistry and Properties. This application proposes to establish a cutting-edge spectroscopic facility which includes; electron energy-loss spectroscopy (EELS), energy-dispersive X-ray spectroscopy (EDS), cathodoluminescence (CL), photoluminescence (PL) and micro-Raman spectroscopy. Each of the spectrometers to be installed has significantly higher sensitivity and resolution than any other facility available in Australia and is capable of full spectrum imaging. This new spectroscopic infrastructure will enable the knowledge-based development of new materials by allowing complete characterisation of structure-composition-property relationships at the nanometre level.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.
Australian Laureate Fellowships - Grant ID: FL210100017
Funder
Australian Research Council
Funding Amount
$3,115,000.00
Summary
Nanoscale-interactions making future functional materials more powerful . Traditional crystal chemistry can no longer meet the demands for development of new functional materials - the foundation of modern industry. The program aims to overcome this challenge by introducing a new strategy into experimental and theoretical research to transform our understanding and application of nanoscale structural and chemical features in materials. The program expects to build new crystal chemistry that incl ....Nanoscale-interactions making future functional materials more powerful . Traditional crystal chemistry can no longer meet the demands for development of new functional materials - the foundation of modern industry. The program aims to overcome this challenge by introducing a new strategy into experimental and theoretical research to transform our understanding and application of nanoscale structural and chemical features in materials. The program expects to build new crystal chemistry that includes nanoscale-interaction information and deep machine-learning to improve the predictability of material properties. Potential outcomes of the program include enhanced capacity for revolutionary materials development thus keeping Australia's leading position in innovative technology, benefiting academia and industry.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
Responsive nanoporous organic cages. This project will generate advanced materials that are constructed from functional nanoscale building blocks. The general design principles developed in this work will be utilised to synthesise a nanoporous adsorbent system that is able to self regulate its physical properties through dynamic structural responses to its environment.
Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of t ....Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of this project are to create new, ground-breaking materials and/or nanosystems that overcome intrinsic weakness of conventional semiconductors and significantly improve their photocatalytic and photoelectrochemical performance, for the benefit of the utilisation of solar and light energy in energy, environment and health. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668100
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
High Resolution Simultaneous DSC/DTA-TGA-FTIR System. National Research Priorities including 'New Materials' 'Frontier Technologies for Building and Transforming Australian Industries' and 'Developing Deep Earth Resources' will all be addressed and the benefits will include new materials such as carbon nanotubes and layered silicate composites. It will also contribute economically through technological development, supporting existing Australian companies in the development of more effective pro ....High Resolution Simultaneous DSC/DTA-TGA-FTIR System. National Research Priorities including 'New Materials' 'Frontier Technologies for Building and Transforming Australian Industries' and 'Developing Deep Earth Resources' will all be addressed and the benefits will include new materials such as carbon nanotubes and layered silicate composites. It will also contribute economically through technological development, supporting existing Australian companies in the development of more effective products and help keep pace with new and innovative advances in technology and to bring in vitality to strategic alliances with industry already launched by the University through a Sustainable Regions Program grant titled 'Building nanotechnology business potential in the Campbelltown-Camden region'.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
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
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.