Engineering the kinetic stability of alloys for advanced stainless material development. A framework for understanding and designing metals and alloys with kinetic stability in mind will allow for discovery and breakthrough science to underpin technological innovation. This work has potential benefits for multiple industry sectors, with the ultimate intent of developing advanced materials for use in transport, construction, energy generation and medicine; all sectors of which can improve our qua ....Engineering the kinetic stability of alloys for advanced stainless material development. A framework for understanding and designing metals and alloys with kinetic stability in mind will allow for discovery and breakthrough science to underpin technological innovation. This work has potential benefits for multiple industry sectors, with the ultimate intent of developing advanced materials for use in transport, construction, energy generation and medicine; all sectors of which can improve our quality of life, whilst also addressing the multi-billion dollars of loss attributed to metallic corrosion each year. Such work will also benefit Australia through the development of a strategic international capability in a highly interdisciplinary field.Read moreRead less
Functionalisation of boron nitride nanotubes: preparation, underlying mechanism and potential sensor applications. Building on Australian expertise in synthesis and characterisations of nanomaterials, this project will carry out comprehensive and systematic research in functionalisation of boron nitride nanotubes and explore their potential applications. The success of this project will enhance Australian international reputation in nanotechnology development and ensure our leading position in t ....Functionalisation of boron nitride nanotubes: preparation, underlying mechanism and potential sensor applications. Building on Australian expertise in synthesis and characterisations of nanomaterials, this project will carry out comprehensive and systematic research in functionalisation of boron nitride nanotubes and explore their potential applications. The success of this project will enhance Australian international reputation in nanotechnology development and ensure our leading position in this highly competitive area. The outcome of this project will promote the potentially functional applications of boron nitride nanotubes in various nanodevices and nanosensors. It will also offer trainings for Australia's future scientists and will further strengthen international scientific collaboration in these fields.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0221983
Funder
Australian Research Council
Funding Amount
$900,000.00
Summary
Interface, Particle and Complex Fluid Characterisation Laboratory. This laboratory will provide a state-of-the-art characterisation facility for complex fluids. This will service the needs of 27 research staff and 38 postgraduate students and involve collaboration between twelve major research groups based at the Universities of Melbourne, Newcastle, Monash, La Trobe and RMIT. The facility will enhance the research activities of the collaborating institutions in key strategic areas. The laborat ....Interface, Particle and Complex Fluid Characterisation Laboratory. This laboratory will provide a state-of-the-art characterisation facility for complex fluids. This will service the needs of 27 research staff and 38 postgraduate students and involve collaboration between twelve major research groups based at the Universities of Melbourne, Newcastle, Monash, La Trobe and RMIT. The facility will enhance the research activities of the collaborating institutions in key strategic areas. The laboratory will also act as a facility for undertaking consulting projects with industry groups by the applicants.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560672
Funder
Australian Research Council
Funding Amount
$202,705.00
Summary
Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced op ....Ultrafast laser facility for chemical, biological and physical investigations of advanced materials. Ultrafast laser techniques are becoming indispensable in many diverse scientific disciplines. Within the Australian scientific community, there is a great need for enhanced access to sophisticated ultrafast laser instrumentation. The expansion to the femtosecond laser facility through the addition of state-of-the-art laser devices, will enable novel laser spectroscopy measurements and advanced optical microscopy techniques to be applied to investigations of advanced materials and biological systems. Access to such instrumentation is crucial to fields including photoluminescent conductive polymers, nanoparticles, engineered supramolecules for artificial photosynthetic systems, and photoactivated therapy and drug delivery/release technology.Read moreRead less
Industrial-strength X-ray Phase Tomography. The unique 3D imaging capability provided as a result of this project will have application to advanced manufacturing as a non-destructive evaluation for materials and micro-components. For instance, the internal structure of aerogels, porous light metals, polymers and carbon fibre based materials can all be imaged at the microscale. Similar benefits flow in health sciences where organic processes can be observed in place and where, for instance, small ....Industrial-strength X-ray Phase Tomography. The unique 3D imaging capability provided as a result of this project will have application to advanced manufacturing as a non-destructive evaluation for materials and micro-components. For instance, the internal structure of aerogels, porous light metals, polymers and carbon fibre based materials can all be imaged at the microscale. Similar benefits flow in health sciences where organic processes can be observed in place and where, for instance, small animals used in research and clinical testing can be inspected internally without having to destroy them, thus allowing for repeated measurements.Read moreRead less
Increasing the efficacy of laboratory x-ray sources for imaging. X-ray laboratory sources are used extensively for imaging: from the humble dental and medical x-ray to sophisticated 3D non-destructive testing methods; from the microscopic to large mechanical parts. This project will pursue methods that improve the imaging capability of such equipment with direct application across the fields of materials and medical imaging.
Membrane-associated structure and the effect of metals on Abeta peptide from Alzheimer's disease. Alzheimer's disease currently affects 5% of Australians over 65, and will triple by year 2050 without an effective therapy. Much research to understand the causes of the disease has focused on the distinctive amyloid deposits found in patients' cerebral tissue. Recent evidence suggests that nerve cell death is actually directly caused by soluble forms of the protein fragments and metals that form th ....Membrane-associated structure and the effect of metals on Abeta peptide from Alzheimer's disease. Alzheimer's disease currently affects 5% of Australians over 65, and will triple by year 2050 without an effective therapy. Much research to understand the causes of the disease has focused on the distinctive amyloid deposits found in patients' cerebral tissue. Recent evidence suggests that nerve cell death is actually directly caused by soluble forms of the protein fragments and metals that form these deposits. We will investigate the specific molecular structure of these fragments with metals in relation to vesicles which mimic the nerve cell surface. This information may facilitate future biomedical efforts work to develop therapies, as well as develop general techniques to study similar structural problems.Read moreRead less
Biodegradable polymeric microparticles for targeted delivery. The use of microparticles with tuneable physicochemical properties and loading characteristics is of interest in the fields of biomaterials, drug delivery and imaging. Such engineered particles are likely to address problems associated with conventional drugs and drug carriers, including poor disease site selectivity, polymer toxicity, non-biodegradability and free diffusion of drugs throughout the body. These microparticles may provi ....Biodegradable polymeric microparticles for targeted delivery. The use of microparticles with tuneable physicochemical properties and loading characteristics is of interest in the fields of biomaterials, drug delivery and imaging. Such engineered particles are likely to address problems associated with conventional drugs and drug carriers, including poor disease site selectivity, polymer toxicity, non-biodegradability and free diffusion of drugs throughout the body. These microparticles may provide direct advantages to society, including minimally invasive and fast in-vivo diagnostics, localised delivery of drugs and therapeutic agents with increased bioavailability, patient acceptability and reduced healthcare costs.Read moreRead less
Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for re ....Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for research into life-saving therapeutic strategies aimed at many pharmaceutical targets embedded in cell membranes, protein misfolding disorders such as Alzheimer's disease and Huntington's disease, as well as development of the next generation of "green" plastics and other advanced polymers.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