New Paradigm for Materials Technology for AZS Glassmaking Refractories. The project aims to enable the inexpensive manufacture of widely used refractories with reduced energy and materials costs and improved thermal and mechanical properties. The project plans to exploit technology patented by the researchers to fabricate percolated mullite materials from fly ash by sintering, yielding properties equivalent or superior to those of fuse-cast alumina-zirconia-silica refractories (AZS). AZS is expe ....New Paradigm for Materials Technology for AZS Glassmaking Refractories. The project aims to enable the inexpensive manufacture of widely used refractories with reduced energy and materials costs and improved thermal and mechanical properties. The project plans to exploit technology patented by the researchers to fabricate percolated mullite materials from fly ash by sintering, yielding properties equivalent or superior to those of fuse-cast alumina-zirconia-silica refractories (AZS). AZS is expensive since it requires melting by fuse-casting and high-purity raw materials. The project aims to eliminate both requirements by sintering and use of waste fly ash, giving microstructures of dense, direct-bonded, percolated, mullite, single crystals, with residual impurities in the interstices that do not affect creep.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100092
Funder
Australian Research Council
Funding Amount
$270,000.00
Summary
A co-thermal evaporation system for the production of chalcogenide thin films for photonics. This project will provide important infrastructure underpinning the production of novel photonic materials that will allow the fabrication of devices that will support advances in the optical internet; in sensing of dangerous or illicit materials; in defense science and in astro-physics. The production of high performance photonic materials for such applications can lead to new commercial ventures in Aus ....A co-thermal evaporation system for the production of chalcogenide thin films for photonics. This project will provide important infrastructure underpinning the production of novel photonic materials that will allow the fabrication of devices that will support advances in the optical internet; in sensing of dangerous or illicit materials; in defense science and in astro-physics. The production of high performance photonic materials for such applications can lead to new commercial ventures in Australia. Read moreRead less
Development of hierarchical carbon nanotube-glass fibre composites. Development of hierarchical carbon nanotube-glass fibre composites. This project aims to develop a new generation of hierarchical carbon nanotube-glass fibre reinforced composites, using a novel synthesis method that grafts carbon nanotubes (CNTs) onto glass fibre and glass fabric. These hierarchical nano- and micro-fibre composites will have improved in-plane mechanical properties, enhanced fracture toughness and higher electri ....Development of hierarchical carbon nanotube-glass fibre composites. Development of hierarchical carbon nanotube-glass fibre composites. This project aims to develop a new generation of hierarchical carbon nanotube-glass fibre reinforced composites, using a novel synthesis method that grafts carbon nanotubes (CNTs) onto glass fibre and glass fabric. These hierarchical nano- and micro-fibre composites will have improved in-plane mechanical properties, enhanced fracture toughness and higher electric conductivity. This project will use a comprehensive experimental and theoretical study to develop design tools for producing this new generation of composites. The anticipated outcome is lighter and stronger glass fibre composite structures, such as wind turbines in the renewable wind energy industry and boats in the marine industry.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE160100357
Funder
Australian Research Council
Funding Amount
$345,000.00
Summary
Ultrastable metallic glasses. The aim of this project is to create a new class of amorphous alloy – ultrastable metallic glass – by a relatively simple vapour-deposition route. These materials are expected to exhibit unprecedentedly low energy states and properties of high thermal stability, elastic modulus, strength, and hardness not achievable in metallic glasses produced by conventional routes. These new materials may also provide a platform for addressing the longstanding issues of relaxatio ....Ultrastable metallic glasses. The aim of this project is to create a new class of amorphous alloy – ultrastable metallic glass – by a relatively simple vapour-deposition route. These materials are expected to exhibit unprecedentedly low energy states and properties of high thermal stability, elastic modulus, strength, and hardness not achievable in metallic glasses produced by conventional routes. These new materials may also provide a platform for addressing the longstanding issues of relaxation dynamics in glassy physics. The unique properties of ultrastable metallic glasses are expected to make them useful in a range of applications, including highly wear- and corrosion-resistant coatings on electronics and biomedical devices and components.Read moreRead less
A New Paradigm for the Solid State Synthesis of Layered Materials. Advanced ceramic materials with outstanding properties or combinations of properties are usually made from three (ternary) or more components. Their solid-state synthesis is hampered by the formation and retention of intermediate phases which degrade their performance. We have devised a method for circumventing intermediate phase formation in advanced materials and reducing synthesis temperatures by up to 600 degrees. This projec ....A New Paradigm for the Solid State Synthesis of Layered Materials. Advanced ceramic materials with outstanding properties or combinations of properties are usually made from three (ternary) or more components. Their solid-state synthesis is hampered by the formation and retention of intermediate phases which degrade their performance. We have devised a method for circumventing intermediate phase formation in advanced materials and reducing synthesis temperatures by up to 600 degrees. This project will explore the underlying atomic scale mechanism of the method. This knowledge will allow the low cost, low greenhouse gas emission synthesis of advanced ceramics for use in renewable, conventional and nuclear power generation.Read moreRead less
Synthesis and processing of fine powders and nano-materials by electric discharge assisted milling under hot and cold plasmas. The discovery of a new materials synthesis and processing technique, called Electric Discharge Assisted Ball Milling, has generated great interest within the materials science community. Preliminary results, recently published in Nature, have demonstrated that mechanical milling using both hot and cold plasmas can result in extremely rapid synthesis of a wide range of ma ....Synthesis and processing of fine powders and nano-materials by electric discharge assisted milling under hot and cold plasmas. The discovery of a new materials synthesis and processing technique, called Electric Discharge Assisted Ball Milling, has generated great interest within the materials science community. Preliminary results, recently published in Nature, have demonstrated that mechanical milling using both hot and cold plasmas can result in extremely rapid synthesis of a wide range of materials. The fundamental mechanisms for this rapid mechano-synthesis method will be elucidated by detailed studies of a range of technologically important materials including, ultrafine, nanostructural and nanosized powders, carbides, nitrides and borides, and energy efficient high surface area products for hydrogen storage and electrode applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883056
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Vacuum Ultraviolet Spectrophotometer and Rapid Photoluminescence Mapping System for Development of Advanced Materials and Biosystems. Australia's energy and renewable energy, defence, biosystem and pharmaceutical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries is expected to be largely driven by advances in materials and biosystems. The installation of the p ....Vacuum Ultraviolet Spectrophotometer and Rapid Photoluminescence Mapping System for Development of Advanced Materials and Biosystems. Australia's energy and renewable energy, defence, biosystem and pharmaceutical industries are spearheading the advancement of technologies in the global competitive market. They are the engines of Australian economy's strength. Future progress of these industries is expected to be largely driven by advances in materials and biosystems. The installation of the proposed facilities will add a new dimension to high-level research performance and significantly enhance the capability for characterization of various forms of materials and biosystems in Australia. The continual development of advanced material and biosystem technology will potentially provide a sustainable means for meeting the increasing global challenge for the industries.Read moreRead less
Control of Nano-Structure for Enhancing the Performance of Magnesium Diboride Superconductor by Chemical Doping. Superconductor technology will play a significant role in a wide range of industry sectors and environments in the twenty first century. Widespread applications now depend significantly on cost-effective resolution of fundamental materials and fabrication issues. The aim of the proposed program is to bring together international experts from four leading groups to tailor the microstru ....Control of Nano-Structure for Enhancing the Performance of Magnesium Diboride Superconductor by Chemical Doping. Superconductor technology will play a significant role in a wide range of industry sectors and environments in the twenty first century. Widespread applications now depend significantly on cost-effective resolution of fundamental materials and fabrication issues. The aim of the proposed program is to bring together international experts from four leading groups to tailor the microstructure at nanoscale to improve flux pinning and the critical current density of the newly discovered magnesium diboride superconductors through readily available chemical doping. The expected outcome is the capability to produce a new generation of superconductors having high performance at low costRead moreRead less
Molecular dynamic simulation and experimental study on the mechanisms of high critical current density in superconductors. The aim of this project is to establish a collaboration between the Institute for Superconducting and Electronic Materials (ISEM) and the team at Nanjing University to study the mechanisms of high critical current density (or flux pinning) in superconductors. Molecular dynamic simulation combined with experimental techniques, such as transport and magnetic measurements will ....Molecular dynamic simulation and experimental study on the mechanisms of high critical current density in superconductors. The aim of this project is to establish a collaboration between the Institute for Superconducting and Electronic Materials (ISEM) and the team at Nanjing University to study the mechanisms of high critical current density (or flux pinning) in superconductors. Molecular dynamic simulation combined with experimental techniques, such as transport and magnetic measurements will be used. The results of this work will expand our understanding of the pinning mechanisms of high temperature superconductors and MgB2 superconductors, with the hope of further enhancing the current carrying capacity, and therefore promoting the practical applications of superconductors.Read moreRead less