A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element an ....A Mechanistic Approach to the Compression Properties of Z-Pinned Composites. The proposed research is a fundamental investigation of the compressive mechanical properties and failure mechanisms of fibre reinforced polymer (FRP) composites reinforced with z-pins. These composites are a new material with strong potential applications in aerospace structures subject to high compressive loads, however their compressive properties are poorly understood. Using theoretical modelling, finite element analysis and experimentation, the research program will greatly enhance the fundamental understanding of the strengthening and failure mechanisms of z-pinned composites. A key outcome of the research will be design guidelines for optimising the pinning of composites for maximum structural performance in aerospace applications.Read moreRead less
Design and synthesis of transparent conducting metal oxides. With advances in solar cell and flexible display technologies the demand and performance requirements for transparent conductors used as electrodes in these devices will increase dramatically. This research program is focused on developing new materials to meet the demand and the challenges of new, more advanced technologies. The project has the potential to generate valuable intellectual property in the form of new generation transpar ....Design and synthesis of transparent conducting metal oxides. With advances in solar cell and flexible display technologies the demand and performance requirements for transparent conductors used as electrodes in these devices will increase dramatically. This research program is focused on developing new materials to meet the demand and the challenges of new, more advanced technologies. The project has the potential to generate valuable intellectual property in the form of new generation transparent conducting oxide materials for a rapidly growing set of applications. The new devices will directly improve our standard of living and additional economic benefits will come from commercialisation of the technology both here and overseas.Read moreRead less
Novel Carbon Coatings for Exceptional Performance. Carbon coatings are technologically important and have many applications in automotive and biomedical industries worldwide. An example automotive application is as a coating for high performance fuel injectors. Carbon coatings have significant unrealised potential for applications in hostile environments such as those encountered in high performance engineering components and in the human body. This project will develop new types of carbon coat ....Novel Carbon Coatings for Exceptional Performance. Carbon coatings are technologically important and have many applications in automotive and biomedical industries worldwide. An example automotive application is as a coating for high performance fuel injectors. Carbon coatings have significant unrealised potential for applications in hostile environments such as those encountered in high performance engineering components and in the human body. This project will develop new types of carbon coatings with properties and performance tailored to applications in biomedical engineering, energy conversion, automotive engineering, manufacturing and microelectronics. The result will be a range of new carbon coatings with exceptional properties and cost-effective synthesis methods.Read moreRead less
Geopolymers for nuclear applications. With the pressing need for the reduction of Greenhouse emissions from electricity generation in Australia, one option that must be seriously considered is nuclear energy. However, the issue of waste storage is a highly significant one that must be addressed. Geopolymeric cements are expected to perform much better than traditional Portland cements in nuclear applications, both for solidification of radioactive wastes and also for the construction of undergro ....Geopolymers for nuclear applications. With the pressing need for the reduction of Greenhouse emissions from electricity generation in Australia, one option that must be seriously considered is nuclear energy. However, the issue of waste storage is a highly significant one that must be addressed. Geopolymeric cements are expected to perform much better than traditional Portland cements in nuclear applications, both for solidification of radioactive wastes and also for the construction of underground waste storage bunkers. This project will use Australia's strong existing knowledge in geopolymers research, and apply it to the development of materials to fill the need for environmentally secure waste storage solutions.Read moreRead less
Graphene based nanostructures for high performance devices. Graphene sheets are the building blocks of graphite and a huge variety of carbon based nanostructures. Stacked graphene sheets have the unique property of the highest known thermal conductivity. By manipulating graphene sheets into three-dimensional channels and interconnects, vastly increased heat fluxes can be extracted from sensitive nanoscale devices such as microprocessors and micro electro mechanical systems. The potential of stac ....Graphene based nanostructures for high performance devices. Graphene sheets are the building blocks of graphite and a huge variety of carbon based nanostructures. Stacked graphene sheets have the unique property of the highest known thermal conductivity. By manipulating graphene sheets into three-dimensional channels and interconnects, vastly increased heat fluxes can be extracted from sensitive nanoscale devices such as microprocessors and micro electro mechanical systems. The potential of stacks of graphene as electrical contacts and interconnects will also be explored. By combining thermal and electrical functions, graphene will allow more efficient use of the valuable space on future devices. The outcome will be more efficient nanoscale devices to meet ever increasing performance demands.Read moreRead less
Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid ....Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid state electrolytes for application in a wide range of electrochemical devices. The understanding gained by this work can be applied to a wide range of important materials e.g. separation membranes, nanofilters and catalysts which help address a number of National Research Priorities.Read moreRead less
Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel comb ....Switchable interfaces. The discovery project will challenge some of the most demanding issues regarding adhesion and molecular separation: - Surfaces that can release/prevent bio-film formation can provide novel solutions for corrosion-protection, implants, anti-fouling in medical devices as well as in industrial piping and reactors. - Materials for separation on the molecular level, which can bring new possibilities for fast and selective processes to the pharmaceutical industry. The novel combination of the two materials research fields - plasma-polymerisation and electroactive materials- will lead to an international capability at the forefront of separation and adhesion research.Read moreRead less
Smart Materials Between Two and Three Dimensions. Shape-memory alloys involving martensitic transformations, are important as smart materials. Both the transformation nucleation and the sample morphology are unsolved issues relevant for these applications. Of particular note are the softening of certain lattice-vibrational frequencies, the development of a tweed-like microstructure on cooling the material and the role of defects, particularly the sample surface, in the transformation process. ....Smart Materials Between Two and Three Dimensions. Shape-memory alloys involving martensitic transformations, are important as smart materials. Both the transformation nucleation and the sample morphology are unsolved issues relevant for these applications. Of particular note are the softening of certain lattice-vibrational frequencies, the development of a tweed-like microstructure on cooling the material and the role of defects, particularly the sample surface, in the transformation process. This project addresses these issues using model materials in thin-film and bulk-crystal forms. Capacitance dilatometry, optical, electron and scanning-probe microscopies, and x-ray techniques, will unlock an understanding of the physical and metallurgical conditions controlling these transformations.Read moreRead less
Fatigue Life Prediction of Nano-filler Modified Composites. The proposed project aims to study the behaviour and the failure mechanisms of polymer nanocomposites under cyclic loading. The outcomes of the project will make original contributions to our knowledge base on such materials. The mechanics modelling and statistical analysis of the prediction of fatigue life will provide a sound physical basis and a useful tool for any future improvement and optimisation of the composites to achieve bett ....Fatigue Life Prediction of Nano-filler Modified Composites. The proposed project aims to study the behaviour and the failure mechanisms of polymer nanocomposites under cyclic loading. The outcomes of the project will make original contributions to our knowledge base on such materials. The mechanics modelling and statistical analysis of the prediction of fatigue life will provide a sound physical basis and a useful tool for any future improvement and optimisation of the composites to achieve better reliability and integrity in their intended applications. This study will bring economic benefits to the end-users of advanced material technology including the Australian materials industries. 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