Integration of Solar, Wind and Storage Systems into Distribution Grids for Network Support. This project will contribute to the development and utilisation of renewable energy technologies for a sustainable future and facilitate their integration into electricity grids for network support. Innovative methodologies and technologies will be developed to reduce network problems associated with the integration of a large number of small-scale renewable energy resources into distribution grids. This ....Integration of Solar, Wind and Storage Systems into Distribution Grids for Network Support. This project will contribute to the development and utilisation of renewable energy technologies for a sustainable future and facilitate their integration into electricity grids for network support. Innovative methodologies and technologies will be developed to reduce network problems associated with the integration of a large number of small-scale renewable energy resources into distribution grids. This project will also develop assessment tools to examine the impact of renewable energy penetration on power quality aspects, network stability and protection performance. This research will provide remedies for potential problems introduced by their integration and improve voltage support in the electricity networks. Read moreRead less
New Methods to Harvest Light: Towards Better Dye-Sensitized Solar Cells. Dye-sensitized solar cell (DSC) technology has emerged as a complementary energy source to silicon photovoltaic technology. The efficiency of the DSC relies heavily on sensitizing molecules to absorb solar photons and then transfer electrons to a semi-conducting particle. This project will investigate new sensitizing methods using a combination of different dyes which work cooperatively to absorb a large part of the solar ....New Methods to Harvest Light: Towards Better Dye-Sensitized Solar Cells. Dye-sensitized solar cell (DSC) technology has emerged as a complementary energy source to silicon photovoltaic technology. The efficiency of the DSC relies heavily on sensitizing molecules to absorb solar photons and then transfer electrons to a semi-conducting particle. This project will investigate new sensitizing methods using a combination of different dyes which work cooperatively to absorb a large part of the solar spectrum and efficiently inject electrons into a semi-conducting particles. The development and understanding of these new methods to sensitize the dye-sensitized solar cell should lead to new and better solar cells.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668257
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
Combinatorial Deposition and Characterisation Facility for New Alloy Thin Film Materials. Australia's competitive edge in materials research is key to maintaining our economic prosperity. Infrastructure that enables our researchers to synthesize novel materials with precise control over composition and structure is crucial to maintaining our strengths in this field. The proposed infrastructure will accelerate progress on the preparation and characterisation of new alloy and nanostructured materi ....Combinatorial Deposition and Characterisation Facility for New Alloy Thin Film Materials. Australia's competitive edge in materials research is key to maintaining our economic prosperity. Infrastructure that enables our researchers to synthesize novel materials with precise control over composition and structure is crucial to maintaining our strengths in this field. The proposed infrastructure will accelerate progress on the preparation and characterisation of new alloy and nanostructured materials and will pay dividends by providing early access to the best materials. This will give our energy technology, biomedical engineering, tooling, electronics and mining industries a competitive edge. Access to this new generation equipment will enhance our pool of highly skilled materials technologists.Read moreRead less
In situ measurements of the electrostatic properties inside photosynthetic reaction centres: correlation with the energy conversion function of the protein. The photochemical reaction centre is a key protein complex involved in energy conversion. It converts solar energy into chemical energy as a transmembrane charge separation. Coupling of electron and proton transfer is catalysed at the level of a ubiquinone cofactor. In order to understand how the redox properties of this cofactor are fine tu ....In situ measurements of the electrostatic properties inside photosynthetic reaction centres: correlation with the energy conversion function of the protein. The photochemical reaction centre is a key protein complex involved in energy conversion. It converts solar energy into chemical energy as a transmembrane charge separation. Coupling of electron and proton transfer is catalysed at the level of a ubiquinone cofactor. In order to understand how the redox properties of this cofactor are fine tuned by the protein environment, we plan to probe the ubiquinone site using a voltage-sensitive fluorescent dye. This exciting multidisciplinary project will contribute to the understanding of how protein matrices influence and govern the midpoint redox potential of their cofactors and the environments of theirRead moreRead less
Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer sola ....Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer solar cells in order to maximise the efficiency of the cells and build prototype nanoscale polymer devices. This will lead to the improvement in devices delivering sustainable energy production - a technology which has the promise of producing energy cheaply from sunlight.Read moreRead less
Electronically Conducting Nanofibres and Assemblies. With the use of new techniques that have just emerged in the last two years and are receiving rapidly growing interest throughout the world, this project will bring to Australia a new nanofabrication platform for making a variety of complex nanostructures. Fundamental researches on these complex nanostructures will greatly advance nanoscience. New nanotechnologies will be developed to address some world-wide challenging problems, e.g. energy ....Electronically Conducting Nanofibres and Assemblies. With the use of new techniques that have just emerged in the last two years and are receiving rapidly growing interest throughout the world, this project will bring to Australia a new nanofabrication platform for making a variety of complex nanostructures. Fundamental researches on these complex nanostructures will greatly advance nanoscience. New nanotechnologies will be developed to address some world-wide challenging problems, e.g. energy conversion and storage, chemical/biological sensing and other micro- and nanoelectronic devices. This project will bring both breakthrough science and frontier technologies for building and transforming Australian industries and help place Australia at the forefront of nanotechnology. Read moreRead less
Surface Processing of Photo-Sensitive Semiconducting Oxides for Solar-Hydrogen. Aim: To enhance the performance of titania-based semiconducting photo-electrodes for the generation of hydrogen from water using sunlight. Means: Engineering of the surface and near-surface layers so as to increase photo-sensitivity and reactivity with water. Significance: Success will provide the key functional component of photo-electrochemical cells for the mass production of renewable and clean hydrogen. In ....Surface Processing of Photo-Sensitive Semiconducting Oxides for Solar-Hydrogen. Aim: To enhance the performance of titania-based semiconducting photo-electrodes for the generation of hydrogen from water using sunlight. Means: Engineering of the surface and near-surface layers so as to increase photo-sensitivity and reactivity with water. Significance: Success will provide the key functional component of photo-electrochemical cells for the mass production of renewable and clean hydrogen. Innovation: For the first time, the properties controlling photo-sensitivity (defect disorder; charge transport; and chemically-induced, local, surface electric fields) will be modified. Outcomes: Technologies for the production of fuel (hydrogen) using renewable energy (solar energy) and a renewable resource (water).
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Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures wi ....Molecular Electronics Principles and Applications. This project will establish basic conceptual models and computational methods to understand the nature of conduction, memory storage, and solar to electrical energy conversion processes in molecular devices on the 1-nanometer scale. Fundamental research of chemical processes, device interfaces, characterization techniques, and natural photosynthesis will result in widely applicable advances in nanotechnology. Additionally, novel architectures will be developed for disruptive new technologies in molecular memory and logic design, as well as in the design of biomimetic solar cells. These developments could lead to new Australian electronics industries and an order of magnitude reduction in the production cost of solar electricity.Read moreRead less
Next generation evaporated and laser diode processed thin-film silicon-on-glass solar cells. The project targets a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight by depositing cells onto glass as it comes from a glass factory. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cel ....Next generation evaporated and laser diode processed thin-film silicon-on-glass solar cells. The project targets a new generation of low-cost silicon solar cell that will significantly reduce the costs of generating electricity from sunlight by depositing cells onto glass as it comes from a glass factory. Solar cells are presently the world's most rapidly growing energy source, with Australians and Australian companies already major players in the associated rapidly expanding industry. Solar cells represent the cleanest and most acceptable technology yet suggested for supplying the world's future energy needs. A cleaner future environment than otherwise likely is another expected outcome as is the creation of major new opportunities for Australian industry.Read moreRead less
High efficiency thin-film gallium arsenide solar cells. Recent developments in GaAs-based solar cells have led to efficiencies above 30%. Widespread adoption of GaAs-based solar cells for space applications has also brought about large reductions in material costs. However, GaAs cells are still much more expensive than silicon cells. This application addresses the development of a manufacturable technique for lifting off thin films of GaAs. This approach allows a significantly reduced cost due ....High efficiency thin-film gallium arsenide solar cells. Recent developments in GaAs-based solar cells have led to efficiencies above 30%. Widespread adoption of GaAs-based solar cells for space applications has also brought about large reductions in material costs. However, GaAs cells are still much more expensive than silicon cells. This application addresses the development of a manufacturable technique for lifting off thin films of GaAs. This approach allows a significantly reduced cost due to reduced materials usage, while maintaining high efficiency. Light-trapping for lifted-off cells will also be developed, which will allow the theoretical limit to performance to be approached, and fundamental processes in GaAs to be investigated.
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