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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
Engineered Nanotube Membranes for Molecular Separation and Biosensing. This broad research effort on the development of nanotube technology will provide potential applications not just in separation and biosensors but also in nanotechnology, biotechnology, drug delivery, energy storage, and catalysis. Development of advanced separation technologies and ultra sensitive biosensing devices based on functionalised gold nanotube membranes and low-cost fabrications are an important direction for Austr ....Engineered Nanotube Membranes for Molecular Separation and Biosensing. This broad research effort on the development of nanotube technology will provide potential applications not just in separation and biosensors but also in nanotechnology, biotechnology, drug delivery, energy storage, and catalysis. Development of advanced separation technologies and ultra sensitive biosensing devices based on functionalised gold nanotube membranes and low-cost fabrications are an important direction for Australian innovation in these fields. They will bring competitive advantages for further developments and applications for molecular separation and biomedical diagnostics. These research outcomes will enhance Australia's capacity in frontier technology and build strength in new analytical and separation technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453771
Funder
Australian Research Council
Funding Amount
$148,246.00
Summary
Electrochemical Electron Spin Resonance Spectrometer. Electron Spin Resonance Spectroscopy (ESR), is a technique used to determine the presence of free unpaired electrons in a sample. Detection and life time studies of radical species is critical to understanding the mechanisms involved in chemical reaction, sample degradation, performance upon exposure to light and oxidation or reduction processes. Combining ESR with an electrochemical interface permits in-situ studies on how electrons are inje ....Electrochemical Electron Spin Resonance Spectrometer. Electron Spin Resonance Spectroscopy (ESR), is a technique used to determine the presence of free unpaired electrons in a sample. Detection and life time studies of radical species is critical to understanding the mechanisms involved in chemical reaction, sample degradation, performance upon exposure to light and oxidation or reduction processes. Combining ESR with an electrochemical interface permits in-situ studies on how electrons are injected or removed from a sample, providing fundamental information on the processes occurring within the sample. Applications will be in the area of electrofunctional materials, complex biomolecular reactions, organic photovoltaics and new materials for nerve cell regeneration.Read moreRead less
Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Au ....Novel Scanning Electrochemical Microscopy applications in molecular, supramolecular electrochemistry and biological systems. Improved understanding of chemical reactivity in natural and artificial molecular systems and acquisition of a wider perspective of electron transfer processes are two important challenges in chemistry and biology. Through this well defined research project, the CI, jointly with the host facility, has the skills to achieve valuable new insights. This project will expand Australia's knowledge base and research capability and open new scenarios for frontier technologies and advanced materials. This project will introduce the SECM methods into Australia. The foreseen benefits include technology exchange and contribution to fundamental and applied science.Read moreRead less
The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized ele ....The role of water uptake in novel all solid-state polymeric ion sensors. This research will enable the development of robust all solid-state polymeric ion sensors based on unplasticized copolymers. Significantly, the physical and chemical robustness of these copolymer ion sensors will allow their widespread use in new and exciting analytical applications, e.g., in-situ analysis of environmental samples in submersible instruments, clinical analysis of whole blood, in-vivo use of miniaturized electrodes in biological media, especially single cells and minute samples in biology and forensic science, etc. Extensive use of neutron characterization techniques aligns strongly this project with the new OPAL reactor to be commissioned in 2007.Read moreRead less
Redox processes in Bayer liquors. Alumina, and the aluminium produced from it, are amongst Australia's most important mineral commodities, earning about $8 billion p.a. in exports. However, ongoing technological improvements are needed for Australian producers to remain globally competitive. This project addresses a key problem in alumina production - the behaviour of organic impurities - which will help to increase industrial productivity and reduce energy consumption. Insights gained from this ....Redox processes in Bayer liquors. Alumina, and the aluminium produced from it, are amongst Australia's most important mineral commodities, earning about $8 billion p.a. in exports. However, ongoing technological improvements are needed for Australian producers to remain globally competitive. This project addresses a key problem in alumina production - the behaviour of organic impurities - which will help to increase industrial productivity and reduce energy consumption. Insights gained from this research will also minimize the environmental and occupational health impacts of various process emissions, making the industry more sustainable.Read moreRead less
Organic electrofunctinal materials: Novel conducting Polymer and Carbon nanotube systems. Inherently conducting polymers and carbon nanotubes will be modified to enhance their ability to function as electrodes used in areas such as sensors, actuators(artificial muscles), energy conversion (Photovoltaics) and storage(batteries, supercapacitors).
The modified materials and systems containing them will be amenable to fabrication into ordered structures, or integration with hosts such as fabrics. ....Organic electrofunctinal materials: Novel conducting Polymer and Carbon nanotube systems. Inherently conducting polymers and carbon nanotubes will be modified to enhance their ability to function as electrodes used in areas such as sensors, actuators(artificial muscles), energy conversion (Photovoltaics) and storage(batteries, supercapacitors).
The modified materials and systems containing them will be amenable to fabrication into ordered structures, or integration with hosts such as fabrics. This latter feature is particularly exciting in that it will accelerate developments in the area of intelligent textiles and fabrics with sensing, actuating and energy conversion/storage capabilities.Read moreRead less
Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are relat ....Electrochemically Driven Molybdoenzyme Catalysis. Enzymes that catalyse oxidation and reduction reactions need to exchange electrons with their substrate and this supply of electrons needs to be sustained. Artificially reconstituted systems can be developed where the enzyme is coupled with an electrode and the current (electrons) exchanged during the reaction are measured directly. In this project we will reveal whether some unusual and unexplained electrochemical phenomena seen before are related to the properties of the enzymes themselves or the ways in which their experiments have been conducted.Read moreRead less
Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercia ....Electrochemically, photochemically and magnetically tuneable organic semi-conducting electrodes for probing biologically important redox chemistry and catalysis. Newly developed tuneable, semi-conductor electrode materials will facilitate substantial advances in electrochemistry. The almost unprecedented levels of flexibility with respect to metal and organic constituents will facilitate insights into biologically important electron transfer and coupled catalytic processes and promote commercial opportunities for sensor development. Electrochemistry represents an enabling discipline in science. The project offers the opportunity for high quality multi-disciplinary doctoral training, integration of skills of scientists from different backgrounds and opportunities to work in world-class national and international infrastructure in the areas of chemistry, biological chemistry and materials science.Read moreRead less
Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portab ....Novel Fuel-Cell Structures based on Electroactive Polymers. The Discovery Project will tackle some of the challenging issues regarding the conversion of our society into a post-petroleum era through: Development and understanding of a new class of organic catalysts for efficient low temperature fuel-cells; Developing cheap and effective, ultra-thin, ion-conducting membranes for fuel-cells based on new plasma-polymers; and Integrating the components into fuel-cells suitable for stationary, portable and automotive applications. These outcomes will contribute to national research priorities: Frontier Technologies for building and transforming Australian Industries, and An Environmentally Sustainable Australia.
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