Efficient One-Dimensional Photocatalysts from Titanate Nanofibres and Nanotubes. This project will deliver important fundamental knowledge for the development of high-value products of titania, and thus will contribute directly to the priority goal of transforming the existing titania industry through value adding and export on the international market. This research will lead to new industries and will create employment opportunities for Australians. It will also serve to train young scientists ....Efficient One-Dimensional Photocatalysts from Titanate Nanofibres and Nanotubes. This project will deliver important fundamental knowledge for the development of high-value products of titania, and thus will contribute directly to the priority goal of transforming the existing titania industry through value adding and export on the international market. This research will lead to new industries and will create employment opportunities for Australians. It will also serve to train young scientists with a real appreciation of materials research and engineering, contributing to the overall competitiveness and productivity of Australian R&D. This project would lead to advances in important fields of clean energy, environment remediation and advanced materials processing in Australia.Read moreRead less
Reactions of Nanoparticles of Metal Oxides and Hydrous Oxides and their Applications in Photocatalysts and Electrode Materials. Australia is a world-leading producer of raw materials of many metallic elements, most of which are exported at low-values. This project will yield important knowledge in new synthetic techniques for making nanostructures of metal oxides. These tiny particles already have a large worldwide market, but the discovery of particles with superior properties or new applicatio ....Reactions of Nanoparticles of Metal Oxides and Hydrous Oxides and their Applications in Photocatalysts and Electrode Materials. Australia is a world-leading producer of raw materials of many metallic elements, most of which are exported at low-values. This project will yield important knowledge in new synthetic techniques for making nanostructures of metal oxides. These tiny particles already have a large worldwide market, but the discovery of particles with superior properties or new applications could lead to new industries and high-value exports. This project aims to devise novel photocatalysts for solar energy conversion and environmental protection, and electrode materials for lithium batteries. It will contribute to the overall competitiveness and productivity of Australian R&D by advancing scientific knowledge and training young researchers.Read moreRead less
Supramolecular assembly in photovoltaic electrode design: Studies of ordered porphyrin/acceptor complexes on polythiophene electrodes. This research outlines an improved way to develop dye-sensitised photovoltaic solar cells for the conversion of sunlight into electricity, by increasing the molecular order of the cell components using host, guest interrelationships. As such, it addresses a problem of international concern 'How to reduce greenhouse gas emissions and stop global warming?' since s ....Supramolecular assembly in photovoltaic electrode design: Studies of ordered porphyrin/acceptor complexes on polythiophene electrodes. This research outlines an improved way to develop dye-sensitised photovoltaic solar cells for the conversion of sunlight into electricity, by increasing the molecular order of the cell components using host, guest interrelationships. As such, it addresses a problem of international concern 'How to reduce greenhouse gas emissions and stop global warming?' since solar cells do not produce carbon dioxide. To achieve our goals we draw on the skills of a team of experts from Australia (synthetic organic chemists), New Zealand (polymer and surface chemists) and Italy (photochemist and photophysicist). Such research is very appropriate for regional Australia, especially Central Queensland.Read moreRead less
Development of an Adjustable Porphyrin-based Molecular Platform for Nanotechnology Applications. Nanotechnology, the art of molecular control, is often heralded as the next industrial revolution. For this to be realised, the construction of useful devices will require precise control at the molecular level. Our control is realised through a process called self-assembly which means that the once the components of the device are correctly designed, the device will simply be able to put itself tog ....Development of an Adjustable Porphyrin-based Molecular Platform for Nanotechnology Applications. Nanotechnology, the art of molecular control, is often heralded as the next industrial revolution. For this to be realised, the construction of useful devices will require precise control at the molecular level. Our control is realised through a process called self-assembly which means that the once the components of the device are correctly designed, the device will simply be able to put itself together. This research will use nature's light harvesting elements, namely porphyrins, and our ability to precisely control their position with respect to each other to build new, more efficient solar cells.Read moreRead less
Solution Processable, High Dimensional Dendrimers for Plastic Electronics. Microelectronics are present in our everyday life, from numerous chips in our vehicles to our mobile telephones; and the list is almost infinite. The electronics used today are limited to rigid surfaces, and are incompatible for the next generation of technology such as rollable displays and radio frequency identification cards. This proposal describes the development of a new class of high performance flexible electronic ....Solution Processable, High Dimensional Dendrimers for Plastic Electronics. Microelectronics are present in our everyday life, from numerous chips in our vehicles to our mobile telephones; and the list is almost infinite. The electronics used today are limited to rigid surfaces, and are incompatible for the next generation of technology such as rollable displays and radio frequency identification cards. This proposal describes the development of a new class of high performance flexible electronic inks that could be used in the next generation of microelectronics. There is a huge commercial interest in these electronic ink materials and this market is projected to be $7.7 billion by 2012. The proposed electronic inks address issues with current materials such as processability, performance and reproducibility.Read moreRead less
Modifying Structure and Properties of Carbon Nanotubes for Device Applications (MWN). The focus of this project is to develop new heteroatom-doped carbon nanotube materials for use in conjugated-polymer composite photovoltaic cells. Synthesis of boron and of nitrogen doped carbon nanotubes (CNTs) by the US researchers will be complemented by ion-implantation post-synthesis of CNTs by the Australian team, to gain a thorough and detailed understanding of how the CNTs can act effectively as both an ....Modifying Structure and Properties of Carbon Nanotubes for Device Applications (MWN). The focus of this project is to develop new heteroatom-doped carbon nanotube materials for use in conjugated-polymer composite photovoltaic cells. Synthesis of boron and of nitrogen doped carbon nanotubes (CNTs) by the US researchers will be complemented by ion-implantation post-synthesis of CNTs by the Australian team, to gain a thorough and detailed understanding of how the CNTs can act effectively as both an electron acceptor and charge transport medium in a conjugated polymer. Outcomes will include fundamental advances in our understanding of charge transport in the composite devices and prototype organic photovoltaic devices of improved efficiency.Read moreRead less
Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class ....Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class of visible-light active photocatalysts that underpin the development of hydrogen generation, low cost solar cells and water purification using sunlight. Such technologies will transform the Australian energy and environmental industries and speed up the transition from a fossil fuel economy to a renewable energy economy.Read moreRead less
Designing New Visible-light Active Photocatalysts for Efficient CO2 Reduction. The increasing concern over Climate Change has triggered great efforts in developing new CO2 capture technologies. The outcomes of this program will lead to a new class of photocatalysts that underpin the development of economical CO2 reduction for clean fuel production using sunlight. Such technologies will speed up the transition of Australian environmental and energy industries from fossil fuel economy to renewable ....Designing New Visible-light Active Photocatalysts for Efficient CO2 Reduction. The increasing concern over Climate Change has triggered great efforts in developing new CO2 capture technologies. The outcomes of this program will lead to a new class of photocatalysts that underpin the development of economical CO2 reduction for clean fuel production using sunlight. Such technologies will speed up the transition of Australian environmental and energy industries from fossil fuel economy to renewable energy economy. The research program will contribute significantly to knowledge advancement in nanomaterials, surface chemistry, and photochemistry, and falls in the National Research Priority Area of 'Environmentally Sustainable Australia' addressing the key goals of Climate Change and low emission energy supply.Read moreRead less
Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain thei ....Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain their behaviour, and use this knowledge to create bio-compatible hi-tech materials and devices. We anticipate significant benefits from the perspectives of basic science and utilisation of biomaterials for new green technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0667984
Funder
Australian Research Council
Funding Amount
$210,000.00
Summary
Near Excitation Raman Micro Spectrometer. The unique properties of nanomaterials have recently been fully realized, and their use has resulted in new technologies, transforming industrial processes. Our research teams at Griffith, Monash and Queensland University of Technology develop optimal, nanostructured materials for technological applications. To maintain a competitive edge in this research, we require a near excitation Raman spectrometer. Used in-situ, it rapidly yields structural infor ....Near Excitation Raman Micro Spectrometer. The unique properties of nanomaterials have recently been fully realized, and their use has resulted in new technologies, transforming industrial processes. Our research teams at Griffith, Monash and Queensland University of Technology develop optimal, nanostructured materials for technological applications. To maintain a competitive edge in this research, we require a near excitation Raman spectrometer. Used in-situ, it rapidly yields structural information on the materials, enabling their formation and function to be better understood. This information will allow enhanced design and synthesis of nanomaterials, producing advanced products and processes for the energy, biotechnology, environmental and mining fields.Read moreRead less