Thin Films of Oxide Ceramics. Aluminium oxide films are used extensively in the Australian industries of Protective & Decorative Coatings (examples include door-knobs and cutting-tools). The industry will be offered a remarkably simple process for preparation of high quality films. In the microelectronic industry, the uses of aluminium oxide films as a dielectric alternative to silicon dioxide has just started to emerge world - wide and this new process would make a dramatic impact with commerci ....Thin Films of Oxide Ceramics. Aluminium oxide films are used extensively in the Australian industries of Protective & Decorative Coatings (examples include door-knobs and cutting-tools). The industry will be offered a remarkably simple process for preparation of high quality films. In the microelectronic industry, the uses of aluminium oxide films as a dielectric alternative to silicon dioxide has just started to emerge world - wide and this new process would make a dramatic impact with commercial benefits for Australia. 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
Structural and Electronic Properties of Layered Bismuth Oxides. A systematic study of the role of cation substitutions and temperature on the structural and electronic properties of a number of layered bismuth oxides will undertaken with the aim of developing improved ferroelectric materials for use in electronic devices.
Complex Phenomena and Phase Transitions in Ferroric Perovskites. The ultimate aim of this project is to identify high performance, multiferroic magnetoelectrics suitable for use in the next generation electronic devices. These oxides exhibit a strong interaction between the polarisation and magnetic response. Understanding the factors that control the response of such materials to applied magnetic and electric fields is critical to the discovery, optimization and, ultimately, industrial exploi ....Complex Phenomena and Phase Transitions in Ferroric Perovskites. The ultimate aim of this project is to identify high performance, multiferroic magnetoelectrics suitable for use in the next generation electronic devices. These oxides exhibit a strong interaction between the polarisation and magnetic response. Understanding the factors that control the response of such materials to applied magnetic and electric fields 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
Ferrihydrite : Fundamentals of a Natural Nanomaterial. The overarching goal of this project is to obtain the depth of knowledge necessary to achieve specific size, composition and morphology control in the crystallization of nanometer-sized iron oxides. The project focusses on the structural characteristics of the oxy-hydroxide phase ferrihydrite, which is a key intermediate in the formation of other iron oxides. The project will employ characterization techniques such as small-angle scattering ....Ferrihydrite : Fundamentals of a Natural Nanomaterial. The overarching goal of this project is to obtain the depth of knowledge necessary to achieve specific size, composition and morphology control in the crystallization of nanometer-sized iron oxides. The project focusses on the structural characteristics of the oxy-hydroxide phase ferrihydrite, which is a key intermediate in the formation of other iron oxides. The project will employ characterization techniques such as small-angle scattering, high resolution TEM, electron nanodiffraction and magnetic energy barrier distribution measurements to study crystallization processes of the iron oxy-hydroxide ferrihydrite, both in vivo and in vitro. The knowledge gained from the biological realm will allow us to devise new laboratory techniques for the preparation of nanoparticles, and provide important information about iron biomineralization to advance the treatment of iron overload diseases.Read moreRead less
Specific-ion effects in non-aqueous solvents. A test for Hofmeister. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of a ....Specific-ion effects in non-aqueous solvents. A test for Hofmeister. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of a colloidal solution. This world-leading research will enable us to improve our fundamental understanding of colloids and thereby facilitate advances in topics as diverse as enzymatic action and minerals purification, ensuring Australia remains at the forefront of science in this field.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560758
Funder
Australian Research Council
Funding Amount
$187,000.00
Summary
Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will ena ....Dynamics at Interfaces: a facility for the characterisation of the dynamics of structural reorganisation and adsorption at interfaces. Controlling the flow, stability, and general performance of finely dispersed materials is important in a great number of industries from cosmetics to minerals purification. These properties are often controlled by the addition of material that forms a film at the interface between the dispersed material and the solvent. We seek to develop a facility that will enable the properties of this film to be characterized, in particular the rate at which the film responds to mechanical and chemical changes. With this knowledge we hope to relate the nanoscopic properties of the adsorbed film to macroscopic properties of the dispersion and be able to tune the structure of the surface film, in order to control the bulk properties of complex fluids.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346515
Funder
Australian Research Council
Funding Amount
$507,000.00
Summary
Fluorescence Detector for the Australian National Beamline Facility. X-ray absorption spectroscopy (XAS) is an extremely important synchrotron radiation tool for determining the local structure around an X-ray absorbing atom. This has many applications in the study of materials, minerals, metal complexes, and metalloproteins and can often be used to obtain information that is not available by other techniques, because structural information can be obtained in the solid or solution state and in ....Fluorescence Detector for the Australian National Beamline Facility. X-ray absorption spectroscopy (XAS) is an extremely important synchrotron radiation tool for determining the local structure around an X-ray absorbing atom. This has many applications in the study of materials, minerals, metal complexes, and metalloproteins and can often be used to obtain information that is not available by other techniques, because structural information can be obtained in the solid or solution state and in mixtures. The current proposal is aimed at introducing new technology into the Australian National Beamline Facility that will greatly improve the quality and quantity of experiments that can be performed and extend studies into dilute solutions and protein samples.Read moreRead less
Special Research Initiatives - Grant ID: SR0354636
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecula ....Australian Computational Molecular Science Network. Computational Molecular Science (CMS) involves the use of theory and computational methods to simulate and visualise molecular systems ranging from small atmospheric species to proteins, nucleic acids, chemical polymers and materials. It represents our most incisive expression of what we understand about the molecular basis of nature. The CMS network will integrate and cross-fertilize both fundamental and application-based expertize in molecular scale computations in the fields of nanoscience, biomaterials, biotechnology, biomedical science and environmental science. It will uncover and explore critical new interdisciplinary science and create new molecular-based paradigms that will drive advances in these fields over the next decade.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560818
Funder
Australian Research Council
Funding Amount
$154,000.00
Summary
A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1 ....A Pico-Newton Scale Force Measurement Apparatus for Polymer Physics and Non-equilibrium Statistical Mechanics. We propose to build a state-of-the-art Optical Tweezers apparatus that measures small forces and torques on micron-sized objects located in 'optical traps'. Using a single laser beam and computer-generated holograms, we will create arrays of optical traps that move or 'dance', and alter the force/torque-imposing properties of each trap. This proposed research equipment will be used (1) to study the physics of single synthetic polymer and naturally occuring biopolymer chains, (2) to quantify experimentally, and for the first time, newly predicted molecular-scale forces, and (3) to demonstrate new theories in non-equilibrium statistical mechanics that quantitatively describe the operation of nanomachines. Read moreRead less