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
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
New Pillared Nanoporous Materials for Hydrogen Production by Photoinduced Water Splitting. The increasing concern over the limited supply of conventional energy sources has triggered world-wide efforts in developing alternative energy generation systems. Hydrogen produced from sunlight and water is considered as an ultimate solution for the hydrogen economy. This project addresses the material needs for more efficient and cleaner means of generating/utilising energy. The novel nanoporous materia ....New Pillared Nanoporous Materials for Hydrogen Production by Photoinduced Water Splitting. The increasing concern over the limited supply of conventional energy sources has triggered world-wide efforts in developing alternative energy generation systems. Hydrogen produced from sunlight and water is considered as an ultimate solution for the hydrogen economy. This project addresses the material needs for more efficient and cleaner means of generating/utilising energy. The novel nanoporous materials with increased photocatalytic water splitting efficiency will lead to new breakthrough in technologies for energy conversion materials. The preparation approach is also applicable to other functional layered materials, providing new opportunities for innovative nanotechnology to more efficient and greener energy industries.Read moreRead less
Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve des ....Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve designs for prolonged life. The project is connected to the dental community and international crown material manufacturers through a broader NIH project in the USA. The improved materials and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a bro ....Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a broader National Institutes of Health project in the USA. The improved understanding of damage mechanisms in natural teeth and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Nano/micro grinding mechanisms and technologies for brittle materials. The successful completion of the project will solve a long standing problem, that is, the ductile removal mechanism in the machining of brittle materials and create a strong knowledge base for the development of technology and characterization techniques for nano/micro mechanical machining of such materials. This will strengthen UWA's research capability and international competitiveness in the field of nano/micro manufacturi ....Nano/micro grinding mechanisms and technologies for brittle materials. The successful completion of the project will solve a long standing problem, that is, the ductile removal mechanism in the machining of brittle materials and create a strong knowledge base for the development of technology and characterization techniques for nano/micro mechanical machining of such materials. This will strengthen UWA's research capability and international competitiveness in the field of nano/micro manufacturing. The pragmatic grinding technology developed for fabricating micro aspherical mould inserts and lenses will directly benefit the optics/photonics, microelectronics and biomedical industries in Australia. This will help to position Australia in the forefront of emerging industries in the new millenniumRead 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
A high performance and environment-friendly piezoelectric detector platform for biosensor applications. The development of high performance, lead-free, piezoelectric films and their incorporation into devices is rapidly becoming an urgent task as a result of recent legislation banning the use of lead in electronic components. The successful development of piezoelectric biosensors, as proposed in this project, has numerous potential benefits including the prospect of rapid and cheap biosensor dev ....A high performance and environment-friendly piezoelectric detector platform for biosensor applications. The development of high performance, lead-free, piezoelectric films and their incorporation into devices is rapidly becoming an urgent task as a result of recent legislation banning the use of lead in electronic components. The successful development of piezoelectric biosensors, as proposed in this project, has numerous potential benefits including the prospect of rapid and cheap biosensor devices as well as an environment-friendly, sensitive and real time solution for on-site drug, chemical and biological sensing. Successful development of the latter would provide immediate benefit in the areas of national security, food safety as well as in environmental and health monitoring. Read moreRead less
Design of Advanced Geopolymeric Materials Based on Nanostructural Characterisation and Modelling. Geopolymers are a class of advanced aluminosilicate materials primarily utilised in the construction and building products industries, where their application as a replacement for ordinary Portland cement provides the potential for highly significant Greenhouse gas emission reductions. Australian research has led to the increasingly widespread commercial use of this technology in a range of areas. D ....Design of Advanced Geopolymeric Materials Based on Nanostructural Characterisation and Modelling. Geopolymers are a class of advanced aluminosilicate materials primarily utilised in the construction and building products industries, where their application as a replacement for ordinary Portland cement provides the potential for highly significant Greenhouse gas emission reductions. Australian research has led to the increasingly widespread commercial use of this technology in a range of areas. Development of a full understanding of the exact chemical structure of geopolymers is essential to finding and developing new applications for these materials as well as maximising their use in known applications.Read moreRead less