Dendritic Organic Semiconductors. This Federation Fellowship, along with the creation of a Centre for Organic Semiconductor Research at The University of Queensland will enable Australian science to have a high profile in organic semiconductors. This is an important scientific and technological goal and the research programme will provide expertise for industry in Australia as well as potentially creating technologies for new industry. It will also provide a focus for other academic institutions ....Dendritic Organic Semiconductors. This Federation Fellowship, along with the creation of a Centre for Organic Semiconductor Research at The University of Queensland will enable Australian science to have a high profile in organic semiconductors. This is an important scientific and technological goal and the research programme will provide expertise for industry in Australia as well as potentially creating technologies for new industry. It will also provide a focus for other academic institutions in Australia by bringing together people with the requisite expertise in materials preparation, characterisation, modelling, photophysics, and device physics and engineering. Read moreRead less
Probing the Interface Between Polymeric Photonic Materials and Biology. This application provides a basis for Professor A. B. Holmes to develop a collaboration between the University of Melbourne (within the Bio21 Institute initiative) and CSIRO Division of Molecular Science to prepare novel plastics for electronics applications (lap top displays, transistors and solar cells) and to make specialised macromolecules for studying the way in which biological molecules may be made to recognise other ....Probing the Interface Between Polymeric Photonic Materials and Biology. This application provides a basis for Professor A. B. Holmes to develop a collaboration between the University of Melbourne (within the Bio21 Institute initiative) and CSIRO Division of Molecular Science to prepare novel plastics for electronics applications (lap top displays, transistors and solar cells) and to make specialised macromolecules for studying the way in which biological molecules may be made to recognise other molecules and thus change their function. It is envisaged that the multidisciplinary research collaboration will lead to commercial opportunities in "plastic electronics" and in human health such as the control of cancer and infectious diseases.Read moreRead less
The time scales of geochemical cycles and earth processes. Precise information on timescales and rates of change is fundamental to understanding natural processes and the development and testing of quantitative physical models in the Earth Sciences. Uranium decay-series isotope studies are revolutionising this field by providing time information in the range 10^2-10^4 years, similar to that of many important Earth processes. This project will establish a world-class Australian Uranium-series res ....The time scales of geochemical cycles and earth processes. Precise information on timescales and rates of change is fundamental to understanding natural processes and the development and testing of quantitative physical models in the Earth Sciences. Uranium decay-series isotope studies are revolutionising this field by providing time information in the range 10^2-10^4 years, similar to that of many important Earth processes. This project will establish a world-class Australian Uranium-series research group to investigate the processes of magma formation and transport, continental growth, rates of erosion and recycling. These methodologies can also constrain processes governing water flow and reservoirs, mineral resources, volcanic eruptions, carbon cycles and other environmentally important processes/systems/cycles.Read moreRead less
Origin and Evolution of the Earth's Chemical Reservoirs. The scientific aims of this project are to understand the processes by which the Earth separated into its chemically-distinct layers (core, mantle, crust, atmosphere, oceans) and to determine the nature of the continuing interactions between the surface environment in which we live and the deep interior. Experimental study of these processes will involve establishment of a world-class facility for materials synthesis at high pressures and ....Origin and Evolution of the Earth's Chemical Reservoirs. The scientific aims of this project are to understand the processes by which the Earth separated into its chemically-distinct layers (core, mantle, crust, atmosphere, oceans) and to determine the nature of the continuing interactions between the surface environment in which we live and the deep interior. Experimental study of these processes will involve establishment of a world-class facility for materials synthesis at high pressures and temperatures. This facility will provide the means to simulate the processes occurring within the Earth and will enable synthesis of new high density materials of technological interest.Read moreRead less
Environmental change, carbon cycling and human impact in tropical Australia. This fellowhip will provide the fundamental science outputs required to understand the complex linkages between terrestrial ecosystems, environmental change and human impact in the tropics - in Australia and globally - thereby assisting in
(i) predicting the response of tropical ecosystems to future environmental change and respond to the impacts of tropical climate variability
(ii) developing and validating method ....Environmental change, carbon cycling and human impact in tropical Australia. This fellowhip will provide the fundamental science outputs required to understand the complex linkages between terrestrial ecosystems, environmental change and human impact in the tropics - in Australia and globally - thereby assisting in
(i) predicting the response of tropical ecosystems to future environmental change and respond to the impacts of tropical climate variability
(ii) developing and validating methodologies for improved carbon sequestration, verifiable carbon accounting and emissions trading
(iii) achieving sustainability in the utilization of the natural resource base of tropical Australia by optimizing the balance between wealth creation and environmental impact
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