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Janus particles and nanorattles: new materials for paint technology. This project will pave the way for self cleaning paints that achieve opacity with greatly reduced titanium dioxide levels. Painted surfaces will maintain their clean and new look for longer and a clean town look will be much more readily maintained. More efficient use of titanium dioxide will reduce the need for sand mining and reduce the cost of quality paint.
Polymer micro-capsules for stain-resistant paint. This project aims to create an advanced micro-capsule system to be used in the manufacturing of high-performance waterborne paints on a large scale. Surface coatings seal, strengthen, and decorate the majority of surfaces in the building industry. Despite their importance, advances in paint science have only been incremental and a truly stain-resistant, robust and environmentally friendly coating has yet to be developed. This project will use pol ....Polymer micro-capsules for stain-resistant paint. This project aims to create an advanced micro-capsule system to be used in the manufacturing of high-performance waterborne paints on a large scale. Surface coatings seal, strengthen, and decorate the majority of surfaces in the building industry. Despite their importance, advances in paint science have only been incremental and a truly stain-resistant, robust and environmentally friendly coating has yet to be developed. This project will use polymer Janus nanoparticles to radically redesign architectural coatings, with the goal to reduce the use of non-renewable components, and increase stain-resistance and durability. This new technology will lead to less disruption for the environment, and important economic and technological benefits for Australia.Read moreRead less
Key Functional Additives in Paint Technology. The goal of this project is to create two novel advanced particle systems with complex architecture that can be manufactured on a large scale, which aim to lead to high-performance waterborne paints. It is intended that these paints will have three functional characteristics: provide more efficient use of titanium dioxide; display pronounced water-resistance; and contribute to removing the need for organic solvents from the gloss paint sector. This r ....Key Functional Additives in Paint Technology. The goal of this project is to create two novel advanced particle systems with complex architecture that can be manufactured on a large scale, which aim to lead to high-performance waterborne paints. It is intended that these paints will have three functional characteristics: provide more efficient use of titanium dioxide; display pronounced water-resistance; and contribute to removing the need for organic solvents from the gloss paint sector. This research aims to provide the means to create paint films with greatly improved properties at reduced cost, with reduced requirement for non-renewable resources and reduced environmental footprint.Read moreRead less
Polymer nanofibres for advanced paint formulations. Surface coatings seal, strengthen, and decorate the majority of surfaces in the building industry—a $72 billion market. Despite their importance, advances in paint science have only been incremental and a truly robust and water resistant paint coating has yet to be developed. Dulux Group Australia and the University of Sydney will use polymer nanofibres as additives to radically redesign architectural coatings, with the goal to drastically incr ....Polymer nanofibres for advanced paint formulations. Surface coatings seal, strengthen, and decorate the majority of surfaces in the building industry—a $72 billion market. Despite their importance, advances in paint science have only been incremental and a truly robust and water resistant paint coating has yet to be developed. Dulux Group Australia and the University of Sydney will use polymer nanofibres as additives to radically redesign architectural coatings, with the goal to drastically increase their durability. The partnership will bring a technological breakthrough that will lead to less disruption for the environment, and important economic and technological benefits for Australia.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL170100014
Funder
Australian Research Council
Funding Amount
$3,275,680.00
Summary
Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromo ....Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromolecules to advanced functional photoresists for 3D laser lithography as well as materials that self-report structural transformations by light or are reprogrammable in their properties by photonic fields. Harnessing the power of light as a precision tool for the construction of advanced macromolecular materials will provide technology outcomes for Australian manufacturing industries from electronics to health. This includes laser-driven 3D printing technology at the nano-level, light-adaptive smart reprogrammable coatings and materials, synthetic proteins responsive to light as well as tailor-made single cell niches.Read moreRead less
Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a pl ....Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a platform for electrochemical conversion of nitrogen gas to ammonia and optimise it for use with surplus renewable energy supplies. The project is expected to contribute to mitigation of greenhouse emissions and create a technology for distributed production of ammonia and ammonium fertilisers.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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100109
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-t ....Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-the-art research and training facilities for these techniques.Read moreRead less
Unravelling how liquids wet surfaces with new dynamic measurements. This project aims to transform our understanding of how liquids wet surfaces in order to provide a step-change in advanced material design. This will be achieved by developing a unifying theory of surface wetting by integrating new microscale models of dynamic wetting with new macroscale automated measurement techniques capable of rapidly generating large datasets, to determine precisely how surface chemistry and surface roughne ....Unravelling how liquids wet surfaces with new dynamic measurements. This project aims to transform our understanding of how liquids wet surfaces in order to provide a step-change in advanced material design. This will be achieved by developing a unifying theory of surface wetting by integrating new microscale models of dynamic wetting with new macroscale automated measurement techniques capable of rapidly generating large datasets, to determine precisely how surface chemistry and surface roughness influence wetting. Expected outcomes include predictive models of surface wetting across multiple scales, and robust high-throughput measurement methods informing optimal design of next-generation materials for all applications where liquids and surfaces interact.Read moreRead less
Polymer nanoobjects functionalized by polymer brushes: preparation, organization and integration in devices. The proposed project targets the collaboration between two leading research teams. The University of Marburg is leading in the area of the preparation of nanoobjects, while the research team at CAMD (UNSW) focuses on the preparation of well-controlled polymer structures via RAFT polymerisation. The combined strength of both groups seeks to improve the properties of nanodevices by the atta ....Polymer nanoobjects functionalized by polymer brushes: preparation, organization and integration in devices. The proposed project targets the collaboration between two leading research teams. The University of Marburg is leading in the area of the preparation of nanoobjects, while the research team at CAMD (UNSW) focuses on the preparation of well-controlled polymer structures via RAFT polymerisation. The combined strength of both groups seeks to improve the properties of nanodevices by the attachment of well-defined polymer layers. We expect therefore an optimum scientific output with both groups focusing on their research potency next to being able to access new knowledge. The visit to the German research group enables the Australian researchers access to a leading team in nanotechnology.Read moreRead less