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Adhesive Bonding for LoadBearing Joints in Aluminium Fast Ferries. The aim of this project is to investigate new chemical pre-treatment techniques and new sensor technologies for specific use in adhesively bonding aluminium in the Australian Fast Ferry industry. These technologies are important in increasing the use of adhesives in ships, possibly leading to considerable weight savings, which, in turn increases the payload of the vessel. These advances in shipbuilding practice can help maintain ....Adhesive Bonding for LoadBearing Joints in Aluminium Fast Ferries. The aim of this project is to investigate new chemical pre-treatment techniques and new sensor technologies for specific use in adhesively bonding aluminium in the Australian Fast Ferry industry. These technologies are important in increasing the use of adhesives in ships, possibly leading to considerable weight savings, which, in turn increases the payload of the vessel. These advances in shipbuilding practice can help maintain the world-leading status of the Australian Fast Ferry industry. The technology also has the potential to expand the market for Australian-manufactured adhesives. The project also offers a stimulating learning environment for a PhD student.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989068
Funder
Australian Research Council
Funding Amount
$637,120.00
Summary
Equipment for Metastable Induced Electron Spectroscopy: surface analysis with excellent surface sensitivity. One of the major research strengths of Australia is surface science as it is important for both fundamental and industry related research. In many cases it is crucial to investigate the outermost layer of a material or mineral. Metastable Induced Electron Spectroscopy is an ideal technique as it is sensitive exclusively to the outermost layer of a broad range of samples. The information g ....Equipment for Metastable Induced Electron Spectroscopy: surface analysis with excellent surface sensitivity. One of the major research strengths of Australia is surface science as it is important for both fundamental and industry related research. In many cases it is crucial to investigate the outermost layer of a material or mineral. Metastable Induced Electron Spectroscopy is an ideal technique as it is sensitive exclusively to the outermost layer of a broad range of samples. The information gained is not accessible by any other method. The proposed equipment will be the first of this type in Australia and will complement existing surface science facilities. The project will enhance Australia's position in surface science internationally and a large number of projects will benefit from access to the equipment.Read moreRead less
Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanom ....Nanotribology and Nanorheometry: A Fundamental Study of the Dynamic Interactions of Particles and Surfaces at the Molecular Level. Friction and deformation occur from the mutual motion and interaction of microscopic particles and surfaces. This research aims to develop new theories and measurement techniques for these non-equilibrium phenomena by combining mathematical analysis and numerical computations with dynamic force measurement, surface modification, and surface characterisation on nanometre and molecular length scales. These insights and data will be critically important in designing low-friction surfaces that save energy and wear, in developing nanoscopic probes for the mechanical and structural properties of soft polymeric and bio-materials, and in making high performance coatings that control adhesion and particle aggregation in technologically advanced applications.Read moreRead less
Numerical Modelling and Experimental Studies to Design and Engineer Nanoparticulate Systems for Bioapplications. Project outcomes will enhance Australia's reputation for scientific innovation in the field of bio-nanotechnology. The project will expand the knowledge base in this area and increase Australia's international profile in research on nanomaterials for bio-related applications. The project partners UNSW and Australian company (Minomic), integrating their skills, expertise and facilities ....Numerical Modelling and Experimental Studies to Design and Engineer Nanoparticulate Systems for Bioapplications. Project outcomes will enhance Australia's reputation for scientific innovation in the field of bio-nanotechnology. The project will expand the knowledge base in this area and increase Australia's international profile in research on nanomaterials for bio-related applications. The project partners UNSW and Australian company (Minomic), integrating their skills, expertise and facilities to address current limitations in understanding the stability of magnetic nanoparticles in biological fluids. The Australian partners will play a leading role in commercializing new applications for functionalized magnetic nanoparticles. The project will provide an excellent multidisciplinary research environment and training for early career researchers.Read moreRead less
Structure of Adsorbed Surfactant Layers at Ionic Liquid-Air Interfaces. The research conducted in the project will greatly enhance our understanding of the physical properties of ionic liquids, an important new class of designer solvents. Australian researchers will receive advanced training and experience using Sum Frequency Spectroscopy in the laboratory of OI Rutland, and in the use of Neutron Reflection. This project is especially timely with the imminent start-up of the new Australian resea ....Structure of Adsorbed Surfactant Layers at Ionic Liquid-Air Interfaces. The research conducted in the project will greatly enhance our understanding of the physical properties of ionic liquids, an important new class of designer solvents. Australian researchers will receive advanced training and experience using Sum Frequency Spectroscopy in the laboratory of OI Rutland, and in the use of Neutron Reflection. This project is especially timely with the imminent start-up of the new Australian research reactor, OPAL, and will help to seed an active program by Australian researchers at this facility.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0345760
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Nanoscale Interaction Forces in Particulate and Molecular Systems. We seek to establish a world-class facility for the measurement of nanoscale interaction forces. The ability to measure forces between particles, polymers, emulsion droplets, bubbles, proteins and powders will augment our research capabilities in minerals and material processing, thin film technology, structured surfaces, and in molecular and bio-technology (eg. proteins, DNA, cells, bone, bio-implants). A Molecular Force Probe ....Nanoscale Interaction Forces in Particulate and Molecular Systems. We seek to establish a world-class facility for the measurement of nanoscale interaction forces. The ability to measure forces between particles, polymers, emulsion droplets, bubbles, proteins and powders will augment our research capabilities in minerals and material processing, thin film technology, structured surfaces, and in molecular and bio-technology (eg. proteins, DNA, cells, bone, bio-implants). A Molecular Force Probe (Asylum Research) instrument will allow precise and flexible force measurements on the nano-metre scale. The proposed multi-disciplinary facility will advance research in the areas of engineering, chemistry, pharmacology and biotechnology.
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Effect of cane sugar juice composition on scaling rate and scale composition in sugar mills. The Australia sugar industry produces 1100 GWh of renewable electricity annually, abating ~1.1 M tonnes of CO2-equivalent of greenhouse gases. This can be increased if the juice evaporation performance, which largely determines the energy efficiency of the sugar factory, can be improved through reduced fouling of evaporators. This project will investigate the effect of juice composition on fouling of sug ....Effect of cane sugar juice composition on scaling rate and scale composition in sugar mills. The Australia sugar industry produces 1100 GWh of renewable electricity annually, abating ~1.1 M tonnes of CO2-equivalent of greenhouse gases. This can be increased if the juice evaporation performance, which largely determines the energy efficiency of the sugar factory, can be improved through reduced fouling of evaporators. This project will investigate the effect of juice composition on fouling of sugar factory evaporators so that a model to predict scale type and scale propensity can be developed. This will enable the development of better scale control strategies, resulting in reduced energy usage and reduced usage of the hazardous and polluting chemicals required to remove scale.Read moreRead less
Membrane Fouling in Submerged Hollow Fibre Membrane Bioreactor Systems: Theory, Modelling and Fouling Control. The outcomes of this project will provide fundamental insights into the mechanisms of fouling in submerged hollow fibre membrane bioreactors (SHFMBR) and will provide a sound base for optimization of design and operation of SHFMBR systems. Given the crucial role of the SHFMBR in wastewater treatment and water reuse, this project will significantly contribute to the national priority are ....Membrane Fouling in Submerged Hollow Fibre Membrane Bioreactor Systems: Theory, Modelling and Fouling Control. The outcomes of this project will provide fundamental insights into the mechanisms of fouling in submerged hollow fibre membrane bioreactors (SHFMBR) and will provide a sound base for optimization of design and operation of SHFMBR systems. Given the crucial role of the SHFMBR in wastewater treatment and water reuse, this project will significantly contribute to the national priority area of 'an environmentally sustainable Australia (water-a critical resource)'. In addition, the outcomes of this project on quantitative simulation of the gel/cake structure and resulting transport phenomena will promote Australia's reputation for high quality fundamental and applied research in the area of membrane filtration. Read moreRead less
Kinetic Control of Nanomaterial Assembly by Novel Polymerisable Surfactants. To build a competitive edge in the future Australian industries need to exploit the manipulation of matter at and near molecular length scales in order to create and use advanced nanostructured materials. In this project, using newly-discovered reactive surfactants we will develop novel methods for assembling and templating the formation of nanostructured polymeric and composite materials with a very broad range of pot ....Kinetic Control of Nanomaterial Assembly by Novel Polymerisable Surfactants. To build a competitive edge in the future Australian industries need to exploit the manipulation of matter at and near molecular length scales in order to create and use advanced nanostructured materials. In this project, using newly-discovered reactive surfactants we will develop novel methods for assembling and templating the formation of nanostructured polymeric and composite materials with a very broad range of potential applications. Australian postgraduate and postdoctoral researchers will be trained in advanced techniques for the creation and characterisation of self-assembled materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453823
Funder
Australian Research Council
Funding Amount
$445,124.00
Summary
Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated ....Atomic Force Microscopy Facility for Soft Interfaces. This proposal seeks to establish a specialized atomic force microscopy facility capable of performing measurements on nanometre scales at soft interfaces. This will service the needs of and collaboration between leading researchers at the Universities of Newcastle, Melbourne, New South Wales and James Cook University. The facility will allow direct measurements of properties of the interactions between atoms, molecules and surfaces associated with soft interfaces which are required for ongoing research in fluid-fluid interfaces, surfactant and polymer adsorbed layers, and biomolecules as well as to develop new processes in emerging fields of nanotechnology, biotechnology, and medical and pharmaceutical production.Read moreRead less