ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functi ....ARC Research Network for Advanced Materials. Materials science/engineering is decidedly interdisciplinary, covering all science and impacting on all manufacturing industry. This network will promote interactions that do not usually occur between materials researchers and students across Australia and internationally from diverse disciplines. The scope is broadly based on advanced materials production, processing and properties but focused in four areas, involving: i) innovative structural/functional materials, ii) high-tech IT/communications/sensing materials, iii) materials solutions for manufacturing, iv) materials for a sustainable Australia, and v) emerging materials technologies. Key programs will promote interdisciplinary workshops and early career researcher interactions.Read moreRead less
Magnetic and electric field tuneable magnetic heterostructures. Australian science and technology will be a leading participant in the creation of a new, useful magneto-electric composite material whose properties arise from careful atomic level design. This goal has been long sought after, and only recently come within reach. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale together with intensive searches for additional examples of useful materia ....Magnetic and electric field tuneable magnetic heterostructures. Australian science and technology will be a leading participant in the creation of a new, useful magneto-electric composite material whose properties arise from careful atomic level design. This goal has been long sought after, and only recently come within reach. Recent proof-of-concept demonstrations have inspired an explosion of activity on a global scale together with intensive searches for additional examples of useful material combinations. In this project, young Australian scientists and research students will have opportunities to receive training and become involved in a National Priority Frontier Technology rich in possibilities for generation of intellectual property.Read moreRead less
Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering applicat ....Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering application. This study aims to investigate two promising candidate materials: CoNi and MnAs. Expected outcomes include the characterisation of their functional properties and understanding of the mechanisms of magnetoelasticity in these materials. Such understanding is expected to contribute to the development of practical magnetoelastic materials and their applications.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560850
Funder
Australian Research Council
Funding Amount
$295,320.00
Summary
Scanning Cathodoluminescence Microscopy and Spectroscopy Facility. Cathodoluminescence (CL), the emission of light during electron irradiation, has emerged as a unique analytical tool to characterise luminescence centres and study luminescence mechanisms in technologically important materials at the nano-scale. The main aim of this project is to establish a state-of-the-art scanning CL microscopy and spectroscopy facility in Australia. The facility will enable high spatial resolution CL analysis ....Scanning Cathodoluminescence Microscopy and Spectroscopy Facility. Cathodoluminescence (CL), the emission of light during electron irradiation, has emerged as a unique analytical tool to characterise luminescence centres and study luminescence mechanisms in technologically important materials at the nano-scale. The main aim of this project is to establish a state-of-the-art scanning CL microscopy and spectroscopy facility in Australia. The facility will enable high spatial resolution CL analysis of technologically important semiconductors and novel nano-structured materials, e.g. quantum dots and ceramic nano-crystals. These studies will facilitate a deeper understanding of the physics of light emission from nano-structured materials and enable the fabrication of higher quality opto-electronic materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882246
Funder
Australian Research Council
Funding Amount
$750,000.00
Summary
Comprehensive Analysis Facility for Thin Films and Surfaces. The provision of infrastructure for the analysis of thin films will enhance Australia's capabilities in creating new materials and in creating new devices that meet needs in medicine, communications, the environment and security. As devices become smaller, sufaces and interfaces dominate their performance. The new facility will enable researchers to understand the structure and composition of the interior and interfaces of thin films a ....Comprehensive Analysis Facility for Thin Films and Surfaces. The provision of infrastructure for the analysis of thin films will enhance Australia's capabilities in creating new materials and in creating new devices that meet needs in medicine, communications, the environment and security. As devices become smaller, sufaces and interfaces dominate their performance. The new facility will enable researchers to understand the structure and composition of the interior and interfaces of thin films as well as mapping local variations in their key properties. Instruments with unique capabilities will measure elemental composition, crystallographic phase, defect and void distributions and spatially resolved stress, electrical, mechanical and magnetic properties.Read moreRead less
Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U ....Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U.S.A. An understanding of the factors that maximise the containment of cracks is essential to the design and development of the next generation of advanced layer composites for many biomechanical and other engineering applications.Read moreRead less
Testing, modelling and engineering applications of topologically interlocking structures. The CI and his international collaborator have recently proposed a new principle of design of materials and structures based on topological interlocking of constituent elements. Elements of simple shape, such as tetrahedra, are assembled in structures that keep their integrity without any binder or connectors. Unusual properties, such as high fracture toughness and damage tolerance were found. The project a ....Testing, modelling and engineering applications of topologically interlocking structures. The CI and his international collaborator have recently proposed a new principle of design of materials and structures based on topological interlocking of constituent elements. Elements of simple shape, such as tetrahedra, are assembled in structures that keep their integrity without any binder or connectors. Unusual properties, such as high fracture toughness and damage tolerance were found. The project aims at investigating the mechanical and acoustic properties of the newly discovered interlockable geometries (cubes, octahedra, dodecahedra and icosahedra) and identifying the areas of application. The project will promote the international leading role of the collaborating institutions in this novel field.Read moreRead less
Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technolog ....Multi-scale Modelling and Simulation of Self-assembling Photonic Crystals. By using bandgaps and introduced defect states, photonic crystals provide the opportunities to shape and mould the flow of light. A success in fabricating 3D photonic crystals with complete bandgaps in a controllable and large-scale fashion will revolutionise the information & telecommunication industry. This ability will provide Australia with a significant niche opportunity at the leading edge of this frontier technology. It builds on Australia's established strength in material science, photonics, and information & communication technology. The mathematical models, simulation platform, and fabrication methods developed in this project will also be applicable to creating other highly-structured, functional materials.Read moreRead less
Memory effects in magnetic metals: origin, utility and control in magnetoelectronics using layered nanopatterns. The work is in the important area of magneto-electronics, a field recognised by the 2007 Nobel Prize awarded in Physics. Training opportunities for Honours and postgraduate students will be provided at the forefront of this high profile area, thereby expanding Australian knowledge base and capability. New opportunities for interaction between several groups in Australia will be create ....Memory effects in magnetic metals: origin, utility and control in magnetoelectronics using layered nanopatterns. The work is in the important area of magneto-electronics, a field recognised by the 2007 Nobel Prize awarded in Physics. Training opportunities for Honours and postgraduate students will be provided at the forefront of this high profile area, thereby expanding Australian knowledge base and capability. New opportunities for interaction between several groups in Australia will be created. The projects will involve PhD students shared between Australian institutions and collaborating groups overseas, thereby cementing collaborations while simultaneously providing unique training environments. The project will use and support activities associated with the Australian major facilities. Read moreRead less
Fabrication of robust nanoscale optical biosensors using the novel spinning disc reactor technology. Spinning Disc Reactor (SDR) technology is new to Australia and will have wide ranging applications in nano-technology, and is destined to attract significant industrial interest beyond the proposed application in nano-scale biosensors. SDR is based on continuous flow and is more benign (less chemical waste) than traditional batch technology with a smaller footprint and significantly reduced capit ....Fabrication of robust nanoscale optical biosensors using the novel spinning disc reactor technology. Spinning Disc Reactor (SDR) technology is new to Australia and will have wide ranging applications in nano-technology, and is destined to attract significant industrial interest beyond the proposed application in nano-scale biosensors. SDR is based on continuous flow and is more benign (less chemical waste) than traditional batch technology with a smaller footprint and significantly reduced capital outlay. The emergence of SDR technology will revolutionize the practice of nano-engineering leading to miniaturization of devices, advances in information technologies and intelligent systems, and the revolution in medical science. The exciting research will enhance public opinion towards science.Read moreRead less