Surface engineering of oriented nano-layers for performance control. This research project will deliver knowledge on how to graft oriented, self assembled films from a surface, develop structure-property relationships at a nano-scale, develop a means to control these properties and develop characterization techniques at nano-scales. This research project, if successful, will deliver the ability to tailor the properties of a surface in a manner and over a range of properties that is not even cont ....Surface engineering of oriented nano-layers for performance control. This research project will deliver knowledge on how to graft oriented, self assembled films from a surface, develop structure-property relationships at a nano-scale, develop a means to control these properties and develop characterization techniques at nano-scales. This research project, if successful, will deliver the ability to tailor the properties of a surface in a manner and over a range of properties that is not even contemplated today.
In addition to the scientific benefits, there are also immediate commercial applications in Australia and worldwide for ophthalmic products (e.g. anti-fog and easy to clean lenses), if the balance of properties can be obtained.
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New-generation starch-based paper coatings. This project is to make a new hybrid biomaterial which encapsulates starch in a synthetic polymer latex for use in paper manufacture. A novel process has been devised for this by the parties. This project is the fundamental research and development needed to turn successful preliminary experiments into commercial reality; it involves a unique combination of cereal and polymer scientists and paper technologists. The product has the potential to set up a ....New-generation starch-based paper coatings. This project is to make a new hybrid biomaterial which encapsulates starch in a synthetic polymer latex for use in paper manufacture. A novel process has been devised for this by the parties. This project is the fundamental research and development needed to turn successful preliminary experiments into commercial reality; it involves a unique combination of cereal and polymer scientists and paper technologists. The product has the potential to set up a new industry to use starch from Australian cereal grains to replace imports and create new markets, as well as reducing environmental problems from paper manufacture.Read moreRead less
Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliv ....Photochemical Design of Microstructured Aerospace Materials. Commercial aviation and shipping spend over US$300 billion on fuel and emit almost 3 billion tonnes of carbon dioxide annually at an enormous environmental cost. This project will provide the material chemistry innovation basis for the production of drag reduction surfaces that can be applied to enable a more effective airflow over an aircraft, thus reducing fuel consumption. Critically, the material design approach will not only deliver a high performance coating for the production of drag reduction surfaces, but allow these surfaces to be tailored to specific application profiles including UV resistance and anti-fouling properties. The project will place an Australian company at the forefront of drag reduction technologyRead moreRead less
Graft copolymers from starch and synthetic monomers. Polymer dispersions, manufactured as latexes in large quantities in Australia and elsewhere, have myriad applications, such as in adhesives, bitumen modifiers, paints and paper coatings. This project will create the enabling science to replace by starch the current synthetic products used to stop these dispersions from coagulating. This will create new uses for renewable resources and will reduce environmental insult by avoiding the leaching o ....Graft copolymers from starch and synthetic monomers. Polymer dispersions, manufactured as latexes in large quantities in Australia and elsewhere, have myriad applications, such as in adhesives, bitumen modifiers, paints and paper coatings. This project will create the enabling science to replace by starch the current synthetic products used to stop these dispersions from coagulating. This will create new uses for renewable resources and will reduce environmental insult by avoiding the leaching of biologically incompatible chemicals. By using starch from crops suited for Australia's arid climate, the new technology will reduce both our dependence on imported products and our greenhouse gas emissions.Read moreRead less
Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The c ....Modifying and Improving Porous Sol-Gel Materials for Water Purification. XeroCoat is commercialising nanotechnology research out of UQ's Physics department. XeroCoat has received much local and international interest in its signature product 'XeroCoat'. The company is rapidly expanding and has established new research facilities with production facilities to be set-up. This will result in high technology, employment growth for Australia. Links with Flinders could see expansion into SA. The company operates in 'Sol-Gel' nanotechnology, which has huge global, academic and commercial interest. However in Australia this technology has only been serviced by Flinders, ANSTO and ANSTO's spin-out company Ceramisphere. The project will help to build a new Australian high tech industry in sol-gel nanotechnology.Read moreRead less
Rubbery nanoparticles for improved plastics, additives and adhesives through novel low-temperature polymerization. This project will create the enabling science for producing better pressure-sensitive adhesives, leather treatment, bitumen additives and engineering plastics, by the first-ever synthesis of acrylic latex at low temperatures. This will allow certain reaction processes to predominate that will result in molecular architectures that are very different from those currently made. The re ....Rubbery nanoparticles for improved plastics, additives and adhesives through novel low-temperature polymerization. This project will create the enabling science for producing better pressure-sensitive adhesives, leather treatment, bitumen additives and engineering plastics, by the first-ever synthesis of acrylic latex at low temperatures. This will allow certain reaction processes to predominate that will result in molecular architectures that are very different from those currently made. The result will be enhanced material properties, such as better-wearing leather coatings, greater scratch and shock resistance in vehicle and domestic plastics (with reduced environmental insult in manufacture and usage), improved endurance for bitumen road surfaces, and layered packaging that needs less adhesive per unit of strength.Read moreRead less
Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research pro ....Manipulating the self-assembly properties of fungal hydrophobin proteins for the design of novel biological polymers. Hydrophobin-based products will be novel biocompatible and biodegradable products with applications in the fields of medical implants, biosensors, detergents, coatings and pharmaceutical and industrial emulsions. They have the potential to directly improve the lives of all Australians and to be of benefit to the Australian economy and environment. This collaborative research project will enable Australian scientists to gain from working with a multinational company and to acquire skills in the rapidly expanding fields of structural and molecular biology. The University of Sydney will own any intellectual property arising from this work and will benefit from the commercialisation of hydrophobin-based products.Read moreRead less
Mechanistic investigation of fluorinated coatings for stone preservation. We will investigate mechanisms governing the synthesis of a latex used for stone preservation. This latex is made from novel and unusual starting materials, and will be the most complex system for which mechanisms have been investigated. We will redesign the synthesis procedure to control particle size and composition of the functional species at the particle surface. This will enable both particle size and surface composi ....Mechanistic investigation of fluorinated coatings for stone preservation. We will investigate mechanisms governing the synthesis of a latex used for stone preservation. This latex is made from novel and unusual starting materials, and will be the most complex system for which mechanisms have been investigated. We will redesign the synthesis procedure to control particle size and composition of the functional species at the particle surface. This will enable both particle size and surface composition to be tailored as desired. The results will be used to investigate the influence of these quantities on interactions between particles and sandstone surfaces. The outcomes will be used by the industrial partner to devise improved protective coatings for stone surfaces in Australian conditions.Read moreRead less
Mechanisms and modelling of gels for protein separation. Gradipore approached Sydney University to collaborate on fundamental science needed to improve polymer gels for separation and characterization of proteins. These gels have many applications: e.g. proteomics and diagnostics. Presently, control of polymer microstructure in the synthesis of these gels is by trial and error. This project will create an accurate model of the process so pore size can be predicted. This involves novel work in ex ....Mechanisms and modelling of gels for protein separation. Gradipore approached Sydney University to collaborate on fundamental science needed to improve polymer gels for separation and characterization of proteins. These gels have many applications: e.g. proteomics and diagnostics. Presently, control of polymer microstructure in the synthesis of these gels is by trial and error. This project will create an accurate model of the process so pore size can be predicted. This involves novel work in experimental and theoretical methods developed by the Sydney University group. The result will be qualitative and quantitative understanding which can be subsequently used to tailor-make gels for new applications.Read moreRead less
Study the Utility of Novel Drug Polymer Conjugates. The products likely to arise from the technology described in this proposal could have application in medical, veterinary and agricultural industries. It offers the potential to treat diseases that are at present poorly treated by enabling delivery direct to the diseased organ (e.g. eye - bacterial endophthalmitis). Completion of the project will also assist a fledgling biotech company transition to a development company with a multiple produ ....Study the Utility of Novel Drug Polymer Conjugates. The products likely to arise from the technology described in this proposal could have application in medical, veterinary and agricultural industries. It offers the potential to treat diseases that are at present poorly treated by enabling delivery direct to the diseased organ (e.g. eye - bacterial endophthalmitis). Completion of the project will also assist a fledgling biotech company transition to a development company with a multiple product portfolio, which will have a direct economic benefit to Australia both in terms of potential export earnings and as an employer highly skilled staff. The project will also provide research training and career opportunities for developing Australian based researchers.Read moreRead less