Advanced Ionic Materials for Organic Photovoltaics. Australia will greatly benefit from the development of improved solar energy technology, as a means of addressing the issue of climate change as a result of continued fossil fuel use. Solar power is also advantageous as it also allows electricity to be generated locally where it is needed, which is particularly important for the many remote areas of Australia. The climate in Australia is ideally suited for the electricity production through pho ....Advanced Ionic Materials for Organic Photovoltaics. Australia will greatly benefit from the development of improved solar energy technology, as a means of addressing the issue of climate change as a result of continued fossil fuel use. Solar power is also advantageous as it also allows electricity to be generated locally where it is needed, which is particularly important for the many remote areas of Australia. The climate in Australia is ideally suited for the electricity production through photovoltaics, and this project will focus on improving the performance of these devices to enable their widespread use. Read moreRead less
Energy transforming polymers: from single molecules to devices. Climate control and the rapidly increasing demand for energy is driving the search for alternative sustainable energy sources. Flexible plastics will be a primary component of the new generation of solar harvesting and energy conversion materials. The objective of this project is to gain an understanding of the way polymers interact with light and can convert absorbed solar energy into electrical power and other useful forms of ene ....Energy transforming polymers: from single molecules to devices. Climate control and the rapidly increasing demand for energy is driving the search for alternative sustainable energy sources. Flexible plastics will be a primary component of the new generation of solar harvesting and energy conversion materials. The objective of this project is to gain an understanding of the way polymers interact with light and can convert absorbed solar energy into electrical power and other useful forms of energy. The outcomes of the project will allow the improved design of plastics for applications in solar energy conversion.Read moreRead less
New Materials for Energy Capture and Conversion: Ionic Liquid-derived Conducting Polymers. Inherently conducting polymers (ICPs) have applications in a wide range of electrochemical devices including actuators, for artificial muscles, and photovoltaic cells for harnessing solar energy. Use of an ionic liquid as the electrolyte within these devices greatly increases the stability and cyclability of the ICP. Our preliminary work shows that an ionic liquid solvent in the synthesis of ICPs results i ....New Materials for Energy Capture and Conversion: Ionic Liquid-derived Conducting Polymers. Inherently conducting polymers (ICPs) have applications in a wide range of electrochemical devices including actuators, for artificial muscles, and photovoltaic cells for harnessing solar energy. Use of an ionic liquid as the electrolyte within these devices greatly increases the stability and cyclability of the ICP. Our preliminary work shows that an ionic liquid solvent in the synthesis of ICPs results in materials with dramatically different morphologies and improved electronic properties. Ionic liquids will be used to prepare ICPs with enhanced electrical and mechanical properties and prototype photovoltaic and actuator devices will be developed based on these new materials.Read moreRead less
Organic Optoelectronic Materials: Next Generation Semiconductors. Designed conjugated organic and polymeric materials will be prepared and evaluated as the active layer in optoelectronic devices, particularly light emitting displays (LEDs), field effect transistors (FETs) and solar cells. Improved materials with stable blue emission will be developed. Advanced organometallic conjugated polymers will harness the lost triplet energy as phosphorescence in LEDs and so raise potential device effici ....Organic Optoelectronic Materials: Next Generation Semiconductors. Designed conjugated organic and polymeric materials will be prepared and evaluated as the active layer in optoelectronic devices, particularly light emitting displays (LEDs), field effect transistors (FETs) and solar cells. Improved materials with stable blue emission will be developed. Advanced organometallic conjugated polymers will harness the lost triplet energy as phosphorescence in LEDs and so raise potential device efficiency in the vicinity of 100%. Active layer materials in FETs will have improved supramolecular order and processibility to improve charge mobility, while the photovoltaic materials will be developed to show non-dispersive hole transport properties. The patterned deposition of materials for plastic electronics will be developed using a revolutionary deposition technique involving supercritical carbon dioxide.Read moreRead less