• Energy Research
• Australian Research Council (ARC) close
• OA Publications Mandate: No close
• 2012 close

The national benefits of the project lie directly in assisting Australia achieve significant emissions reductions (at least 60% by 2050) as part of the global effort to avoid dangerous climate change. This needs to be done in an effective, efficient and equitable manner that takes into account other national policy goals including those of the energy sector. There are clear benefits in developing a framework that can assist in creating a policy mix that explicitly deals with the complementarities and trade-offs that arise in the interaction of the various policy instruments employed to achieve these multiple goals.

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.

This project aims to develop new design principles for silicon-based photovoltaics (PVs) through a comprehensive study of atomic-scale structures and phenomena in PV materials. The development of more efficient photovoltaic materials is of major global importance, given the pressing need for clean and renewable sources of energy. Australia has international leadership in developing solar cell technologies, and the ideal natural environment to exploit these technologies. The fundamental insights derived in this project, such as detailed 3D maps of dopant distributions at the atomic scale, will bolster Australia's international reputation in the field and provide better control in the design of PV devices.

This project will improve national capability to optimise power production from wind turbine farms in complex terrain by improving the understanding of the flow regime. By better understanding separated regions and the turbulent structures within these regions power production can be optimised and fatigue risks associated with turbine positioning in complex sites can be reduced. This will improve confidence in wind farm site assessment techniques and consequently reduce economic risks associated with current wind farm viability assessments. By increasing national capacity to generate clean energy stationary energy emissions can be reduced. This project will also deliver high calibre graduates that will be potential future industry leaders.

At a fundamental research level, Australia's active participation in this area of national priority and research strength will be advanced through our published research, which will increase our understanding of wind turbine wakes and their effects in wind farms. This understanding will then be used to produce improved methods of predicting wind turbine performance. Such methods are needed by wind energy designers to produce better wind farms. It will also be used to recommend how to improve the aerodynamic design of turbine components, such as the blades and hub. Numerical tools will be developed for industry use, and training will be provided to personnel, thereby increasing the capabilities of Australia's growing wind energy industry.