Design of hollow nanoparticles of titania for the sustainable production of hydrogen from water using sunlight. Hydrogen is a clean and non-polluting fuel that is the natural and sustainable replacement for greenhouse gas emitting fossil fuels. Because of its abundant sunlight and vast titanium reserves (the world's largest) Australia is especially well-placed to develop the technology of producing hydrogen directly from water and sunlight using a titanium dioxide photo-anode. This research, whi ....Design of hollow nanoparticles of titania for the sustainable production of hydrogen from water using sunlight. Hydrogen is a clean and non-polluting fuel that is the natural and sustainable replacement for greenhouse gas emitting fossil fuels. Because of its abundant sunlight and vast titanium reserves (the world's largest) Australia is especially well-placed to develop the technology of producing hydrogen directly from water and sunlight using a titanium dioxide photo-anode. This research, which consists of computational and experimental parts, is focused on laying the scientific foundation for that technology to be commercially viable. The national and community benefits are the availability of an inexpensive, limitless and clean fuel, reduction in reliance on energy imports, reduction in greenhouse gas emissions and resultant global warming.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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P-Type Titanium Dioxide for Hydrogen Generation from Water using Solar Energy. This project aims to develop a completely new processing technology for photo-sensitive oxide materials based on titanium dioxide for the conversion of renewable energy (solar energy) into chemical energy (hydrogen) or electrical energy (photovoltaic). When commercialised, the resultant technology will allow Australia to achieve the following: a) reduction in air pollution, b) reduction in greenhouse gas emissions, c) ....P-Type Titanium Dioxide for Hydrogen Generation from Water using Solar Energy. This project aims to develop a completely new processing technology for photo-sensitive oxide materials based on titanium dioxide for the conversion of renewable energy (solar energy) into chemical energy (hydrogen) or electrical energy (photovoltaic). When commercialised, the resultant technology will allow Australia to achieve the following: a) reduction in air pollution, b) reduction in greenhouse gas emissions, c) reduction in reliance on foreign energy sources, d) development of a range of ancillary technologies and infrastructure, and e) export of solar energy in the form of solar-hydrogen. This project addresses National Priorities #1 and #3.Read moreRead less
Advanced Nanostructured Ceramic Composites for Ultracapacitors. The global climate changes and the related disastrous events such as heat flows, bushfires, and flooding will endanger the Australian population and our natural environment. The implementation of effective devices and technologies to reduce our carbon footprint is a priority task. The project addresses the issue by development of new ultracapacitor materials for next generation green energy storage devices through engineering and im ....Advanced Nanostructured Ceramic Composites for Ultracapacitors. The global climate changes and the related disastrous events such as heat flows, bushfires, and flooding will endanger the Australian population and our natural environment. The implementation of effective devices and technologies to reduce our carbon footprint is a priority task. The project addresses the issue by development of new ultracapacitor materials for next generation green energy storage devices through engineering and implementation of advanced nanoceramics and nanocomposites created by innovative nanotechnologies. The project will also contribute to other national research priorities such as materials and frontier technologies, reduction of atmospheric pollution, and decrease in the energy dependence of our country on oil.Read moreRead less
PROCESSING OF REDUCED-BAND-GAP TITANIA FOR SOLAR-HYDROGEN. The present project involves the development of materials and devices for solar-hydrogen using photo-assisted water decomposition. The research focusses on the processing of titanium dioxide (titania) with substantially enhanced photo-sensitivity and, consequently, increased efficiency of the conversion of solar energy into chemical energy (hydrogen) through imposition of the optimal Ti/O ratio. Significance: processing technology of tit ....PROCESSING OF REDUCED-BAND-GAP TITANIA FOR SOLAR-HYDROGEN. The present project involves the development of materials and devices for solar-hydrogen using photo-assisted water decomposition. The research focusses on the processing of titanium dioxide (titania) with substantially enhanced photo-sensitivity and, consequently, increased efficiency of the conversion of solar energy into chemical energy (hydrogen) through imposition of the optimal Ti/O ratio. Significance: processing technology of titania for photo-electrochemical devices for hydrogen generation and water decontamination. Innovation: processing of titania with reduced band-gap to be achieved through optimised oxygen nonstoichiometry. Outcome: processing technology of titania with outstanding photo-sensitivity.Read moreRead less
TITANIA-BASED MATERIALS WITH ENHANCED PHOTO-SENSITIVITY FOR SOLAR-HYDROGEN. Aims: Enhancement of the photo-sensitivity of titania photo-electrodes will be achieved through the effect of aliovalent ions in the titania lattice, leading to, at a high density of states, the imposition of mid-gap bands. This will result in the reduction of the effective band gap required for ionisation. Significance: The practical application of titania for the photolysis of water using solar energy at efficiencies s ....TITANIA-BASED MATERIALS WITH ENHANCED PHOTO-SENSITIVITY FOR SOLAR-HYDROGEN. Aims: Enhancement of the photo-sensitivity of titania photo-electrodes will be achieved through the effect of aliovalent ions in the titania lattice, leading to, at a high density of states, the imposition of mid-gap bands. This will result in the reduction of the effective band gap required for ionisation. Significance: The practical application of titania for the photolysis of water using solar energy at efficiencies sufficiently high for commercialisation (greater than 10%). Innovation: Examination for the first time of the impact of the electronic structure on the photo-sensitivity of oxide materials, including titania single crystals and polycrystals.Read moreRead less
Flexible dye-sensitised solar cells on polymer substrates. The expected outcomes of the project are the preparation and development of flexible solar cells. The resulting portable and compact solar cells could be incorporated in fabrics opening the solar cell market to the clothing industry. The products and mechanisms developed are envisaged to be amenable to large scale-up in industry. Hence, at a future date, there is the potential to fabricate the cells in Australia and then export the mater ....Flexible dye-sensitised solar cells on polymer substrates. The expected outcomes of the project are the preparation and development of flexible solar cells. The resulting portable and compact solar cells could be incorporated in fabrics opening the solar cell market to the clothing industry. The products and mechanisms developed are envisaged to be amenable to large scale-up in industry. Hence, at a future date, there is the potential to fabricate the cells in Australia and then export the materials and technology. This will benefit the Australian economy through employment of Australians and income generated through exports.Read moreRead less
Controlled synthesis of well-aligned single crystalline one-dimensional semiconducting nanomaterials for energy application. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including advanced materials, nanotechnology, and sustainable energy. The novel synthetic methods and the targeting material system could lead to advanced materials for energy application. The outcomes o ....Controlled synthesis of well-aligned single crystalline one-dimensional semiconducting nanomaterials for energy application. This proposal is at the forefront of a number of important fields, and therefore the outcomes are expected to be of great interest to a broad spectrum of industry sectors, including advanced materials, nanotechnology, and sustainable energy. The novel synthetic methods and the targeting material system could lead to advanced materials for energy application. The outcomes of this project will place Australian researchers among the pioneering groups in this area and will benefit several major technology-related fields including materials manufacture technology and sustainable energy.Read moreRead less
Computational design of titanium dioxide-based ceramics for the renewable energy technology platform: Solar-Hydrogen. Hydrogen is a clean non-polluting fuel. Production of hydrogen (Solar-Hydrogen) directly from water and sunlight is a very appealing renewable energy technology. The key requirement to allow this technology to be adopted is finding an electrically suitable material. This research program takes an innovative approach by combining state of the art computational techniques to engine ....Computational design of titanium dioxide-based ceramics for the renewable energy technology platform: Solar-Hydrogen. Hydrogen is a clean non-polluting fuel. Production of hydrogen (Solar-Hydrogen) directly from water and sunlight is a very appealing renewable energy technology. The key requirement to allow this technology to be adopted is finding an electrically suitable material. This research program takes an innovative approach by combining state of the art computational techniques to engineer advanced ceramics having sophisticated electrical signatures. These ceramics will be synthesized in a partner experimental program to gauge their efficiencies for hydrogen production. The program will provide the foundation for a renewable energy technology that will provide clean energy and energy independence for Australia.Read moreRead less