Thermo-electro-chemo-mechanical properties of biological systems. The proposal is aimed at developing a new theoretical framework for piezoelectric biological materials and structures, through theoretical analysis, computation and numerical simulations, as well as experimental investigations, to produce high-reliability, high-performance hydrogel components and smart soft tissue structures. It is envisaged that successful outcomes of this program will give the Australian biological industry a te ....Thermo-electro-chemo-mechanical properties of biological systems. The proposal is aimed at developing a new theoretical framework for piezoelectric biological materials and structures, through theoretical analysis, computation and numerical simulations, as well as experimental investigations, to produce high-reliability, high-performance hydrogel components and smart soft tissue structures. It is envisaged that successful outcomes of this program will give the Australian biological industry a technology edge over their competitors and provide easy-to-use guidelines for the design of smart biological systems.Read moreRead less
Structures and properties of tissue engineering matrices for cartilage and bone: Imaging, visualising and modelling tissue/scaffold constructs in 3D. Tissue engineering of bone and cartilage has the potential to lower costs and improve outcomes. The first stage requires the design of porous 3D scaffolds. To date they have been found less than ideal for clinical applications. Our ability to design and optimise scaffolds has been ad hoc, as local structure and properties have not been measurable ....Structures and properties of tissue engineering matrices for cartilage and bone: Imaging, visualising and modelling tissue/scaffold constructs in 3D. Tissue engineering of bone and cartilage has the potential to lower costs and improve outcomes. The first stage requires the design of porous 3D scaffolds. To date they have been found less than ideal for clinical applications. Our ability to design and optimise scaffolds has been ad hoc, as local structure and properties have not been measurable during tissue growth and repair. In this proposal, an interdisciplinary group from three universities will utilise microCT imaging, visualisation and numerical modelling to determine these structures and properties. This will provide an invaluable understanding for the further development of tissue engineering scaffolds.Read moreRead less
Structural Characterization of Ion Beam Synthesized Metallic Nanocrystals using Advanced Synchrotron based Analytical Techniques. Metallic nanocrystals formed by ion implantation represent a highly relevant class of nanomaterials with significant potential applications in communication technology. A detailed understanding of the structure of such crystals, as proposed in the project, will yield considerable information for efficient utilization of ion beam synthesized nanocrystals. This will enh ....Structural Characterization of Ion Beam Synthesized Metallic Nanocrystals using Advanced Synchrotron based Analytical Techniques. Metallic nanocrystals formed by ion implantation represent a highly relevant class of nanomaterials with significant potential applications in communication technology. A detailed understanding of the structure of such crystals, as proposed in the project, will yield considerable information for efficient utilization of ion beam synthesized nanocrystals. This will enhance Australia's strength in nanotechnology and materials science and create the potential for technical innovation. Furthermore, this project will produce significant know-how in synchrotron based analytical techniques which is invaluable with respect to future research at the forthcoming Australian synchrotron facility.Read moreRead less
Tailoring superconducting hybrid multilayered film systems for electric and electronic applications. This project focuses on the development of new scientific and technological aspects of the fabrication, properties and operation of novel hybrid systems for revolutionizing electricity handling and electronics. It will also solve some existing problems of film structures with promising multilayer technology. Hybrid systems, often make the headlines in science and are gaining an increasingly promi ....Tailoring superconducting hybrid multilayered film systems for electric and electronic applications. This project focuses on the development of new scientific and technological aspects of the fabrication, properties and operation of novel hybrid systems for revolutionizing electricity handling and electronics. It will also solve some existing problems of film structures with promising multilayer technology. Hybrid systems, often make the headlines in science and are gaining an increasingly promising outlook in materials engineering, nanotechnology and electronics, promising eventual application in a broad range of industries. This project will establish Australia's capability at the forefront in this area. The outcomes predicted will benefit existing Australian companies and may establish new companies dealing with these hybrid systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0219038
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
Focused Ion Beam System for multidisciplinary applications. A Focused Ion Beam (FIB)system to be housed in a central facility and configured for maximum flexibility and utility over a very wide range of disciplines and applications. It will be used for micromachining and nanoscale fabrication, as an imaging device sensitive to crystal orientation and as a preparation device for scanning and transmission electron microscopy. It will support research including electronic and opto-electronic mater ....Focused Ion Beam System for multidisciplinary applications. A Focused Ion Beam (FIB)system to be housed in a central facility and configured for maximum flexibility and utility over a very wide range of disciplines and applications. It will be used for micromachining and nanoscale fabrication, as an imaging device sensitive to crystal orientation and as a preparation device for scanning and transmission electron microscopy. It will support research including electronic and opto-electronic materials, nanotechnology, complex mesoscale structures, earth sciences, small system optics, fracture behaviour of polymers and biocomposites.Read moreRead less
Self-assembly and complexity: networks and patterns from materials to markets. Self-assembly leads the formation of patterns without external directing agents. It is responsible for the growth of complex multiscale structures found in biology and materials science and is a crucial concept for development of viable nanotechnologies. Complex systems, from biological ecosystems to financial markets and the Internet, are also characterized by spontaneous clustering and linkages that determine their ....Self-assembly and complexity: networks and patterns from materials to markets. Self-assembly leads the formation of patterns without external directing agents. It is responsible for the growth of complex multiscale structures found in biology and materials science and is a crucial concept for development of viable nanotechnologies. Complex systems, from biological ecosystems to financial markets and the Internet, are also characterized by spontaneous clustering and linkages that determine their collective behaviour. The project will investigate in detail the geometry, topology, materials science and statistical physics of networks, leading to design and characterization of robust self-assembled materials and complex systems.Read moreRead less
Left-handed metamaterials and negative refraction. This project will establish and support the first team in Australia working in the field of left-handed metamaterials, artificial materials in which waves behave in a unique and counter-intuitive way. The project will promote this new field, enhance its rapid development, and facilitate emerging novel technologies in Australia. It will also lead to close international collaborations with active theoretical and experimental groups, and bring impo ....Left-handed metamaterials and negative refraction. This project will establish and support the first team in Australia working in the field of left-handed metamaterials, artificial materials in which waves behave in a unique and counter-intuitive way. The project will promote this new field, enhance its rapid development, and facilitate emerging novel technologies in Australia. It will also lead to close international collaborations with active theoretical and experimental groups, and bring important expertise to Australia. We believe our initial efforts of purely fundamental nature and extensive collaboration with the overseas groups will have a significant impact on the development of this field and related novel technologies in Australia, attracting strong interest from industry.Read moreRead less
Transport properties from Nuclear Magnetic Resonance. Australia is embarking on the development of major gas fields offshore western Australia. These developments are very costly (~1Billion) and tools to manage the risk in development are well sought after. NMR response is the only tool offering a good correlation to permeability, one of the major factors whether oil/gas recovery is economical. The actual rocks studied will be selected to make the results of the study of immediate value to Austr ....Transport properties from Nuclear Magnetic Resonance. Australia is embarking on the development of major gas fields offshore western Australia. These developments are very costly (~1Billion) and tools to manage the risk in development are well sought after. NMR response is the only tool offering a good correlation to permeability, one of the major factors whether oil/gas recovery is economical. The actual rocks studied will be selected to make the results of the study of immediate value to Australian oil and gas producers.
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Stamp forming of lightweight fibre-metal laminate systems. A key criteria in the development of new vehicles is weight reduction. The aim of this project is to investigate the formability of fibre metal laminates (FMLs) for automotive applications. These hybrid material systems have significant advantages in terms of strength, weight, noise and impact reduction over metals. The major research issue addressed here is how can such materials be formed for volume production.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561186
Funder
Australian Research Council
Funding Amount
$447,967.00
Summary
Surface Mechanical Property Analysis Facility. The aim of this proposal is to develop a facility for the mechanical properties analysis of material surfaces. The facility will enable an understanding of the performance of materials in a wide range of contact and abrasion situations and in very small volumes such as thin films and components of multiphase composites. The unique features of the proposed facility are that it is capable of analysis down to exceptionally low sub-micron length scale, ....Surface Mechanical Property Analysis Facility. The aim of this proposal is to develop a facility for the mechanical properties analysis of material surfaces. The facility will enable an understanding of the performance of materials in a wide range of contact and abrasion situations and in very small volumes such as thin films and components of multiphase composites. The unique features of the proposed facility are that it is capable of analysis down to exceptionally low sub-micron length scale, under multiple forms of loading and over a range of temperatures. It is applicable to the design of abrasion resistant materials, characterisation of very thin surface films for applications such as microelectronics and biomedical implants and design of advanced composites.Read moreRead less