ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green che ....ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green chemical industries by utilising abundant sunlight, seawater, and waste feedstocks. This should provide significant benefits, through industry collaborations, our new world-leading capacity will train a next generation of game changers to empower emerging carbon industries to solve grand socio-economic challenges, ultimately meeting zero-carbon emissions targets.Read moreRead less
Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a rema ....Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a remarkable energy density, high stability and low cost. This should provide significant benefits, such as improving the capacity and robustness of low-cost hydrogen storage and transportation, reducing energy costs and making hydrogen energy a more accessible and sustainable clean energy source for Australia.Read moreRead less
Engineered materials for future energy technologies. The development of new technologies to be applied in fuel generation, energy conversion and environmental remediation will have wide national and international impact. The cross-disciplinary and cross-institution research program proposed will draw on expertise within Australia and in Europe for the fabrication of materials for next generation energy devices. In the future, there is the potential that these materials could be fabricated within ....Engineered materials for future energy technologies. The development of new technologies to be applied in fuel generation, energy conversion and environmental remediation will have wide national and international impact. The cross-disciplinary and cross-institution research program proposed will draw on expertise within Australia and in Europe for the fabrication of materials for next generation energy devices. In the future, there is the potential that these materials could be fabricated within Australia and therefore lead to employment nationally, and income generated through the export of advanced catalysts, solar cells and sequestration materials.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE130101264
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Carbon nanotube-based supercapacitors: breaking the energy density limit. Novel electrodes will be nano-architectured by using ultralong single-walled carbon nanotube arrays and transition metal oxides to produce next-generation supercapacitors. The outcomes will lead to unprecedented energy densities in energy storage devices for sustainable future energy solutions.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560683
Funder
Australian Research Council
Funding Amount
$321,953.00
Summary
A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the ....A furnace stack for advanced photovoltaic, photonic and microfabrication applications. Advanced silicon photovoltaic, photonic, optoelectronic and micro-electromechanical devices require state of the art processing equipment for the deposition of thin dielectric films and for controlled doping of the devices. Key techniques include the deposition of stoichiometric and silicon rich silicon nitride and silicon dioxide films, and the controlled wafer doping with boron and phosphorus. A state of the art furnace stack is to be procured which will satisfy these requirements on industrially relevant wafer sizes up to 150mm. The equipment will support a broad range of research projects in the above fields, ranging from fundamental investigations to applied research carried out in collaboration with industry partners.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0775548
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation fo ....Advanced characterisation facilities for functional nanostructured materials. A critical factor that enhances frontier research is a set of advanced core research experimental facilities for material characterisation purposes. The proposed equipment aims to: (1) provide research facilities for advanced nanomaterial research; (2) improve national competitiveness and growth in a knowledge-based economy; and (3) foster local talented researchers in order to meet the strategic needs of the nation for a sustainable environment. These activities will revitalise Australia's leading role in creating new technologies with particular relevance to using advanced nanostructures for the production of clean air and water, and sustainable energy alternatives.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140100805
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Radioisotope-powered Parallel Electron Lithography for High-throughput Nano-manufacturing. This project aims to realise rapid fabrication of controllable nano-devices over large areas with high throughput and low cost. The lack of large-size (greater than four inch) mask and ultra-low dose resist are the fundamental challenges for high-throughput radioisotope-powered parallel electron nano-lithography (RIPEL) systems. This project aims to realise a large-size RIPEL mask by using the ultra-light ....Radioisotope-powered Parallel Electron Lithography for High-throughput Nano-manufacturing. This project aims to realise rapid fabrication of controllable nano-devices over large areas with high throughput and low cost. The lack of large-size (greater than four inch) mask and ultra-low dose resist are the fundamental challenges for high-throughput radioisotope-powered parallel electron nano-lithography (RIPEL) systems. This project aims to realise a large-size RIPEL mask by using the ultra-light supporting material aerographite that has a state-of-the-art ratio value of Young's modulus to cubic density. It will also develop a new inorganic nanoparticle resist with ultra-low dose. These building blocks will enhance RIPEL's throughput by four orders of magnitude. The project will contribute to making processors or solid state storage cheaper and more efficient.Read moreRead less
Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s str ....Nanofabrication of Metamaterials for Next Generation Optical Devices. The dream of invisibility cloaks dates back to ancient times but recent advances in nanotechnology have made this a reality through the use of metamaterials. Metamaterials are artificially-made materials that have optical properties not found in nature. This field is still in its infancy and significant challenges remain and need to be solved before practical applications can be realised. This project builds on Australia’s strategic investment in nanofabrication capabilities to fabricate functional metamaterials and uncover the underlying physical phenomena. It will revolutionise the field of nanophotonics for a variety of novel applications ranging from defence, renewable energy, imaging, sensing to optical communications.Read moreRead less
Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltai ....Swift heavy ion induced nano-porous antimony-based semiconductors. This project aims to study the fabrication and application of nano-porous antimony based semiconductors prepared by high-energy ion irradiation. Using a unique combination of synchrotron and laboratory- based analytical techniques as well as computer simulations, the project expects to identify the physical mechanisms for porous structure formation and exploit the materials for application in thermoelectric and thermo-photovoltaic devices. Expected outcomes of the project include fabrication processes compatible with current device fabrication methodologies that should enable rapid integration of the materials into advanced device applications. Significant benefits should result from novel applications of the technologies such as energy harvesting and sensor devices.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE150100752
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
Rational Design of Hematite Photoanodes for Solar Hydrogen Generation. Hematite (iron oxide) is a promising electrode material for photoelectrochemical hydrogen generation from water. It has low cost, good long-term stability and absorbs light efficiently. However, its use is limited by its poor electrical conductivity. This project aims to develop a novel host-guest nanostructure that exploits the beneficial light-absorption properties of hematite (the guest) but shifts the charge transport fun ....Rational Design of Hematite Photoanodes for Solar Hydrogen Generation. Hematite (iron oxide) is a promising electrode material for photoelectrochemical hydrogen generation from water. It has low cost, good long-term stability and absorbs light efficiently. However, its use is limited by its poor electrical conductivity. This project aims to develop a novel host-guest nanostructure that exploits the beneficial light-absorption properties of hematite (the guest) but shifts the charge transport function to a nanostructured transparent conductive oxide host. The project aims to produce nanostructured hematite electrodes for efficient hydrogen production from water and sunlight, thus making a significant contribution to the goal of commercially-viable storage of solar energy in the form of hydrogen.Read moreRead less