Electron transfer in proteins, a study of mechanism and function. Our research will probe the mechanisms by which nature's living systems build, maintain, and reproduce. We present an ability to understand these processes at a detailed molecular level using science and technology at the forefront of multidisciplinary research. The research will provide a foundation for new smart materials, technologies and future industries, and also ways forward for future basic scientific research and endeavo ....Electron transfer in proteins, a study of mechanism and function. Our research will probe the mechanisms by which nature's living systems build, maintain, and reproduce. We present an ability to understand these processes at a detailed molecular level using science and technology at the forefront of multidisciplinary research. The research will provide a foundation for new smart materials, technologies and future industries, and also ways forward for future basic scientific research and endeavor. All this is done with the best international researchers and capabilities within a local environment that will help to train the next generation of Australian scientists.Read moreRead less
Mimicking peptide structure - towards an aqueous environment. In this proposal we develop a fundamental understanding of the balance between 'weak' and 'strong' forces to define the properties of peptides and proteins. This will allow the design of new biological probes and materials with tailor-made chemical and physical properties for use in bioengineering, biotechnology, proteomics, and drug design. One such example is the design and preparation of a new chemical agent for the non-surgical tr ....Mimicking peptide structure - towards an aqueous environment. In this proposal we develop a fundamental understanding of the balance between 'weak' and 'strong' forces to define the properties of peptides and proteins. This will allow the design of new biological probes and materials with tailor-made chemical and physical properties for use in bioengineering, biotechnology, proteomics, and drug design. One such example is the design and preparation of a new chemical agent for the non-surgical treatment for cataract, the major cause of blindness world-wide.Read moreRead less
New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging populatio ....New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging population) and also important new biopolymers for use in health technologies of the future.Read moreRead less
Conformationally constrained and immobilized beta-peptides. The research builds on world-class expertise in Australia (particularly Adelaide) in proteomics to provide a basis for fundamental advances in chemistry that will underpin the development of new pharmaceuticals and smart materials, and future technologies and industries. We create a mix of research at the interface of disciplines within academia and industry, with linkages to the very best international researchers and centres. A new cr ....Conformationally constrained and immobilized beta-peptides. The research builds on world-class expertise in Australia (particularly Adelaide) in proteomics to provide a basis for fundamental advances in chemistry that will underpin the development of new pharmaceuticals and smart materials, and future technologies and industries. We create a mix of research at the interface of disciplines within academia and industry, with linkages to the very best international researchers and centres. A new critical mass of expertise in a number of advancing areas of chemistry, biology, and materials science will be introduced to Australia. This will enhance existing strengths and opportunities in proteomics and biomedical research for the treatment of disease.Read moreRead less
Double Exposure Photoresists for the 32 and 22 nm Lithographic Nodes. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of double exposure lithography. The novel photoactive polymeric films to be developed are expected to support the next generation of microchips. A major outcome of this project ....Double Exposure Photoresists for the 32 and 22 nm Lithographic Nodes. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of double exposure lithography. The novel photoactive polymeric films to be developed are expected to support the next generation of microchips. A major outcome of this project will be establishment of Australia as a world-leader in this rapidly expanding field. Furthermore the technology can be applied broadly to many printing technologies.Read moreRead less
Advanced Lithographic Solutions using Block Copolymers: Integrating Self Assembly and Lithography. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of self assembly in photolithography. Plastics with tailored properties will be made and used to develop novel processes to reduce the defectivity i ....Advanced Lithographic Solutions using Block Copolymers: Integrating Self Assembly and Lithography. The semiconductor industry is one of the largest world-wide, with annual revenue of $220B and employing over 1.5M people around the world. This project provides a unique opportunity for development within Australia of significant expertise in the field of self assembly in photolithography. Plastics with tailored properties will be made and used to develop novel processes to reduce the defectivity in integrated circuit manufacture. The ultimate benefit will be faster and more energy efficient microprocessors. A major outcome of this project will be establishment of Australia as a world-leader in this rapidly expanding field. Furthermore, the technology can be applied broadly to many other applications such as high density data storage.Read moreRead less
Nanoparticles with designed morphology for surface-coating applications. Significantly improved water-based paints, with zero volatile organic content and organic opacifiers, are highly desirable for environmental and health reasons. The science needed to produce such paints has been persistently elusive. USyd and Dulux will collaborate to achieve these paints by using Australian-developed platform technologies that allow polymer architecture to be controlled at molecular and nanoscale levels. T ....Nanoparticles with designed morphology for surface-coating applications. Significantly improved water-based paints, with zero volatile organic content and organic opacifiers, are highly desirable for environmental and health reasons. The science needed to produce such paints has been persistently elusive. USyd and Dulux will collaborate to achieve these paints by using Australian-developed platform technologies that allow polymer architecture to be controlled at molecular and nanoscale levels. This will give us the means to make structured nanoparticles with morphologies that had been regarded as unachievable, and that are the key to dispensing with harmful ingredients in paints.Read moreRead less
Novel Lanthanide Complexes and Polymeric Luminescent Chelates for Biomedical Imaging and Bioassay. The development of advanced materials and frontier technologies such as the luminescent chelates proposed here is essential for Australia's evolution as a competitive nation in fields such as biomedical imaging and clinical diagnostics. For example, the total expenditure on fluorescent reagents in 2004 exceeded US$1.5 billion, with an estimated 25% annual growth. With proven applications in diagnos ....Novel Lanthanide Complexes and Polymeric Luminescent Chelates for Biomedical Imaging and Bioassay. The development of advanced materials and frontier technologies such as the luminescent chelates proposed here is essential for Australia's evolution as a competitive nation in fields such as biomedical imaging and clinical diagnostics. For example, the total expenditure on fluorescent reagents in 2004 exceeded US$1.5 billion, with an estimated 25% annual growth. With proven applications in diagnostic immunoassay and high throughput screening, the use of luminescent lanthanide complexes allows significant improvements over traditional fluorophores, facilitating miniaturisation and ultimately leading to reduced costs for the consumer.Read moreRead less
Metallographitic Discs as New Materials. Materials science plays a pivotal role in determining and improving economic performance and quality of life. While application of materials is the ultimate goal, basic understanding of a material's behaviour from the atomic/nano-level to macrostructural level is also of critical importance. This project builds upon the recent success of soluble, well-defined carbon discs in molecular electronics, through the preparation and study of metal-containing deri ....Metallographitic Discs as New Materials. Materials science plays a pivotal role in determining and improving economic performance and quality of life. While application of materials is the ultimate goal, basic understanding of a material's behaviour from the atomic/nano-level to macrostructural level is also of critical importance. This project builds upon the recent success of soluble, well-defined carbon discs in molecular electronics, through the preparation and study of metal-containing derivatives as new advanced crystalline and liquid crystalline materials. The possibility of enhanced electronic, optical and/or magnetic properties, along with good processability, make these materials potential candidates as the active component of future, technologically important devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237384
Funder
Australian Research Council
Funding Amount
$156,000.00
Summary
Raman Spectroscopy Mapping Facility. This proposal seeks to provide a confocal Raman spectrometer for researchers at the Universities of Wollongong, Western Sydney, Newcastle and University of Technology, Sydney. The Facility will have the exceptional capability of characterising and mapping, at the micron level, the chemical nature of a wide range of advanced materials under development in our laboratories. The information derived will be of critical value for potential applications such as new ....Raman Spectroscopy Mapping Facility. This proposal seeks to provide a confocal Raman spectrometer for researchers at the Universities of Wollongong, Western Sydney, Newcastle and University of Technology, Sydney. The Facility will have the exceptional capability of characterising and mapping, at the micron level, the chemical nature of a wide range of advanced materials under development in our laboratories. The information derived will be of critical value for potential applications such as new corrosion-protection coatings, highly selective chemical and biochemical sensors, and new solar energy materials. The Facility will also be invaluable for the quantitative characterisation of forensic and geological samples that are otherwise difficult to identify due to their heterogeneous nature.Read moreRead less