Very thin, highly oriented and featured diamond films. The technology for making very thin diamond films, having sculpted surface features and fabricated from tiny and highly oriented individual diamond crystallites, would enable widespread potential applications, including eg surface acoustic wave devices, optical biosensors for ?lab-on-a-chip?, and field emitter arrays for paper thin, bright and wide angle flat panel displays, amongst others. Diamond is uniquely suited to these applications, ....Very thin, highly oriented and featured diamond films. The technology for making very thin diamond films, having sculpted surface features and fabricated from tiny and highly oriented individual diamond crystallites, would enable widespread potential applications, including eg surface acoustic wave devices, optical biosensors for ?lab-on-a-chip?, and field emitter arrays for paper thin, bright and wide angle flat panel displays, amongst others. Diamond is uniquely suited to these applications, and the capability to manipulate film properties and features which is the key requirement, is within grasp.Read moreRead less
Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The nov ....Production of hydrogen from biomass by integrated catalytic aqueous hydrolysis and reforming in subcritical water. The outcomes of this project will lead to the development of a novel process for efficient and cost-effective hydrogen production from renewable biomass using integrated hydrolysis and catalytic aqueous reforming at low temperatures. Such technological innovation will provide significant benefits to Australia as a whole for transition to a truly sustainable hydrogen economy. The novel reaction system and research methodologies proposed in this proposal will certainly enhance Australia's science and technology capability and international competitiveness, in the area of reaction engineering. Also of the national benefit is the successful training of a postgraduate at PhD level who will no doubt add to future scientific research workforce.Read moreRead less
Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but st ....Sustainable processes for next-generation surface coatings and core-shell nanoparticles based on biomolecular templating. Nanotechnology promises new materials with broad impact, yet our ability to manufacture complex nanomaterials using sustainable processes is very limited. This project will advance our knowledge of nanomaterial manufacture using inspiration from how complex materials are made in nature. This project will deliver next-generation surface coatings that are incredibly thin but strong, and specialised nanoparticles made using biocompatible processes. The knowledge and methods developed will benefit the biotechnology and nanotechnology sectors, as well as research in soft-matter science, quantum computing, photonics and healthcare. The value proposition for innovation in these fields will increasingly rely on new nanomanufacturing approaches.Read moreRead less
Improvements and Optimisation of Water Electrolysis for Hydroxy Gas Production for Metal Cutting Applications. The current technique for metal cutting mainly uses oxygen-acetylene flames, which means for the large number of Australian remote communities oxygen and acetylene bottles have to be transported from major cities. This incurs significant transport costs and associated environmental emissions and presents major safety concerns. Hydroxy flames using electrolysis of water can alleviate the ....Improvements and Optimisation of Water Electrolysis for Hydroxy Gas Production for Metal Cutting Applications. The current technique for metal cutting mainly uses oxygen-acetylene flames, which means for the large number of Australian remote communities oxygen and acetylene bottles have to be transported from major cities. This incurs significant transport costs and associated environmental emissions and presents major safety concerns. Hydroxy flames using electrolysis of water can alleviate these problems and, by utilising renewable electricity, the new technology to be developed in this research will transform tens of thousands of Australian metal workshops to be more environmentally friendly, safer and more cost-effective, thus contributing to the development of an environmentally sustainable Australia. Read moreRead less
Application of bioreactors for culture of differentiated cells and solid-phase tissues. The aim of this project is to develop methods for producing three-dimensional human cartilage outside of the body. Tissue-engineered cartilage has a range of applications, including in toxicity testing, for production of therapeutics, and as surgical transplant devices. Bioreactors will be used to culture cartilage under controlled conditions for development of living tissues with properties as close as possi ....Application of bioreactors for culture of differentiated cells and solid-phase tissues. The aim of this project is to develop methods for producing three-dimensional human cartilage outside of the body. Tissue-engineered cartilage has a range of applications, including in toxicity testing, for production of therapeutics, and as surgical transplant devices. Bioreactors will be used to culture cartilage under controlled conditions for development of living tissues with properties as close as possible to those of native articular cartilage. Novel culture strategies will be used to enhance the availability of growth factors and provide adequate oxygen and nutrient exchange. These techniques have the potential to yield significant improvements in the quality of engineered cartilage.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0237922
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
High Resolution Cryogenic Field Emission Environmental Scanning Electron Microscope Facility. A high resolution variable pressure scanning electron microscope will replace aging, heavily utilised facilities. It will be accessed by existing large and diverse user groups in a mature and internationally-recognised Centre. The novel combination of a cryogenic stage and the electrostatic beam blanking modification will support continuance of the local, world-leading research and application of new ....High Resolution Cryogenic Field Emission Environmental Scanning Electron Microscope Facility. A high resolution variable pressure scanning electron microscope will replace aging, heavily utilised facilities. It will be accessed by existing large and diverse user groups in a mature and internationally-recognised Centre. The novel combination of a cryogenic stage and the electrostatic beam blanking modification will support continuance of the local, world-leading research and application of new imaging techniques, particularly in the materials and mineral sciences. Both new nanotechnology and existing globally-significant industries will utilise the unique aspects of this instrument for product refinement and maintenance of commercial leadership, in partnership with local Universities and Government agencies.Read moreRead less
Role of Reactive Particles in Explosive Emulsions. Concentrated water-in oil explosive emulsions are widely used in the minerals industry because they are cheap, easily detonated and relatively safe to handle. Their explosive energy can be significantly increased when reactive particles are introduced into the emulsion matrix. To do this, the interaction between the solid, oil, and water phases needs to be optimised. This investigation will increase our basic understanding of the physical and ch ....Role of Reactive Particles in Explosive Emulsions. Concentrated water-in oil explosive emulsions are widely used in the minerals industry because they are cheap, easily detonated and relatively safe to handle. Their explosive energy can be significantly increased when reactive particles are introduced into the emulsion matrix. To do this, the interaction between the solid, oil, and water phases needs to be optimised. This investigation will increase our basic understanding of the physical and chemical interactions that occur between the particle and the oil-water interface, and develop a more efficient explosive that can be produced continuously on a commercial scale.Read moreRead less
Microfluidic Studies of Stimuli-Responsive Emulsions. Breakthrough 'stimuli-responsive interface technology' has been developed in Australia to allow better control over emulsions, which are oil-in-water mixtures used widely in everyday products such as medicines. This project will increase our understanding of this new technology, by examining how the chemistry of the molecules at the interface interacts with fluid behaviour when the emulsion is made. The research will employ miniature lab-on-a ....Microfluidic Studies of Stimuli-Responsive Emulsions. Breakthrough 'stimuli-responsive interface technology' has been developed in Australia to allow better control over emulsions, which are oil-in-water mixtures used widely in everyday products such as medicines. This project will increase our understanding of this new technology, by examining how the chemistry of the molecules at the interface interacts with fluid behaviour when the emulsion is made. The research will employ miniature lab-on-a-chip systems, to give engineers and scientists design rules for this new technology, opening the way to new products that will improve our everyday lives. One immediate product to be researched is 'precision' double emulsions, which show unique properties for the delivery of chemotherapy medicines.Read moreRead less
Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. ....Benign fabrication of microfluidic hydrogel for improved artificial vasculature in bone implants. We will create a benign technology for synthesising microfluidic hydrogels to generate artificial vascultures in bone implants. It is a critical step to enable the use of tissue-engineered vital organs, such as bone, heart and kidney in patients with end-stage organ failure. Thicker scaffolds will be possible, as the vasculature will provide nutrients and oxygen for cells to grow into 3D scaffolds. It will promote capacity of Australia for manufacturing global biomaterial products for tissue engineering. We will also develop in-situ imaging analytical protocols for the rapid analysis of broad arrays of functional molecules, with significant bearing on BioMEMS design to develop methods for diagnosis of fatal diseases.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989675
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in ....Interface-specific facility for quantifying adsorption and structures at particulate interfaces. The facility will be used by the collaborating universities to investigate adsorption and interface properties with great precision, and to develop new and improved technologies for coal and mineral processing, saline water utilisation, water desalination, energy production and environment protection. In particular, the project will investigate innovative ways of using ion-interface interactions in saline water for cleaning coal and recovering value minerals by flotation, and for improving dissolved air flotation used in water treatment and desalination to produce drinking water. The project will further investigate novel ways of capturing CO2, storing natural gases and hydrogen, and tailoring nutrient nano-crystals for foliar delivery.Read moreRead less