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
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
A NEW CONCEPT IN DESIGN OF MATERIALS AND STRUCTURES BASED ON TOPOLOGICALLY INTERLOCKED ELEMENTS. The project aims to develop a new concept in materials design based on assemblies of interlocked elements. Interlocking is achieved topologically by special arrangements of blocks without connectors. Such assemblies can form structures possessing special mechanical properties and serve as load-bearing skeletons in composites with a binder phase providing desired functional properties. Various types o ....A NEW CONCEPT IN DESIGN OF MATERIALS AND STRUCTURES BASED ON TOPOLOGICALLY INTERLOCKED ELEMENTS. The project aims to develop a new concept in materials design based on assemblies of interlocked elements. Interlocking is achieved topologically by special arrangements of blocks without connectors. Such assemblies can form structures possessing special mechanical properties and serve as load-bearing skeletons in composites with a binder phase providing desired functional properties. Various types of interlocked assemblies will be modelled, produced and tested to determine their mechanical and acoustic properties. A range of experimental techniques tailored for these unusual assemblies will be employed. The expected outcome will be the implementation of the new design principle in multifunctional materials and structures.Read moreRead less
Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancemen ....Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancement in both scientific knowledge and technologies for Australia, and provide huge opportunities to boost Australian telecommunication industries, which are developing quickly in recent years.Read moreRead less
Development of nano-structured thermoelectric materials for power generation from heat. To make thermoelectric technology attractive for practical power generation purposes, new high efficiency materials have to be developed. Our fabricated nanostructured thermoelectric materials will have improved performance due to the peculiarities in electrical and thermal transport. The novel thermoelectric materials and constructed prototype devices with high thermoelectric performance will be practically ....Development of nano-structured thermoelectric materials for power generation from heat. To make thermoelectric technology attractive for practical power generation purposes, new high efficiency materials have to be developed. Our fabricated nanostructured thermoelectric materials will have improved performance due to the peculiarities in electrical and thermal transport. The novel thermoelectric materials and constructed prototype devices with high thermoelectric performance will be practically used for various power generation purposes. This offers a long-term solution to the global warming threat through decreasing amounts of waste heat presently generated. It will also strengthen Australia's position in world-wide research on thermoelectricity.Read moreRead less
Novel nanostructured InVO4 and related vanadates photocatalysts for water splitting under visible light irradiation. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including sustainable energy supply, solar energy applications, and environmental purification. This novel material system could lead to highly efficient photocatalysts for application in solar energy to split w ....Novel nanostructured InVO4 and related vanadates photocatalysts for water splitting under visible light irradiation. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including sustainable energy supply, solar energy applications, and environmental purification. This novel material system could lead to highly efficient photocatalysts for application in solar energy to split water to produce hydrogen. The outcomes of this project will position Australian researchers among the pioneering groups in this area and will benefit several major technology-related fields including sustainable energy supply, environmental protection engineering, and materials manufacture technology.Read moreRead less
Development of high performance III-V semiconductor photoconductive antennas for terahertz applications. The practical applications of terahertz (THz) radiation include scientific probing for material characterisation, screening for weapons, explosives and biohazards, imaging for concealed objects and medical diagnostics, chemical and biological analysis, astronomy and space research. The success of this project will lead to the creation of a new generation of high performance THz emitters/detec ....Development of high performance III-V semiconductor photoconductive antennas for terahertz applications. The practical applications of terahertz (THz) radiation include scientific probing for material characterisation, screening for weapons, explosives and biohazards, imaging for concealed objects and medical diagnostics, chemical and biological analysis, astronomy and space research. The success of this project will lead to the creation of a new generation of high performance THz emitters/detectors essential for above applications, making great contribution to the Nation in the areas of science, technology, health, security and economy.Read moreRead less
Advanced products through multiscale microstructure engineering. The metals manufacturing industry is one of the most important in Australia. Future growth and sustainability of the sector is critically dependent on the development of innovative metal products and materials.. In this program Australia's leading research group in metal manufacturing will develop new products and processes through the controlled manipulation of the microstructure at a number of levels: from nano scale to macro s ....Advanced products through multiscale microstructure engineering. The metals manufacturing industry is one of the most important in Australia. Future growth and sustainability of the sector is critically dependent on the development of innovative metal products and materials.. In this program Australia's leading research group in metal manufacturing will develop new products and processes through the controlled manipulation of the microstructure at a number of levels: from nano scale to macro scale. The areas of application include the automotive industry, biomaterials, surface engineering and the emerging area of microforming technologiesRead moreRead less
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
Charge transfer mechanism in 3-dimensional pore-solid nanoarchitectures for electrochemical systems. This project represents a significant scientific and economic advance for Australia because: 1) it is likely to create advanced energy storage and conversion devices, with excellent working efficiency and kinetics, which will induce dramatic improvements to our environment 2) the project will establish local expertise and scientific know-how on electrochemical energy storage and conversion system ....Charge transfer mechanism in 3-dimensional pore-solid nanoarchitectures for electrochemical systems. This project represents a significant scientific and economic advance for Australia because: 1) it is likely to create advanced energy storage and conversion devices, with excellent working efficiency and kinetics, which will induce dramatic improvements to our environment 2) the project will establish local expertise and scientific know-how on electrochemical energy storage and conversion systems, which will place Australia at the forefront of this important area of lithium ion battery and PEM fuel cells; 3)relevant Australian enterprises in electric vehicle and portable device manufacturing will reap the benefits of these discoveries.
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