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Generating multi-component scaffolding to influence the differentiation of embryonic stem cells. Nervous system diseases are debilitating and will develop in over 50 per cent of people at some time in their life. This project will develop strategies so that stem cells can be utilised to encourage brain repair for the treatment of Parkinson's disease. The technology developed will also be of benefit for the treatment of other nervous system disorders.
Nanophotonics for strong absorption in extremely thin solar cells: moving beyond silicon. This project will lead to the development of extremely thin solar cells made of novel low-cost materials, which would likely reduce the cost of photovoltaic technology. If the cost of photovoltaics was sufficiently low then it could have a major impact on reducing greenhouse gas emissions and pollution in Australia and worldwide.
Transparent metal oxides, a window of opportunity for silicon solar cells. This project aims to develop novel silicon heterojunction solar cells based on transparent conductive metal oxides (TCOs). Thin layers of zinc, gallium and molybdenum oxides present negligible absorption losses, which leads to a high output current. The project will optimise them as surface passivating layers, to achieve a high output voltage. TCOs can also provide good lateral conductivity, to boost the fill factor. The ....Transparent metal oxides, a window of opportunity for silicon solar cells. This project aims to develop novel silicon heterojunction solar cells based on transparent conductive metal oxides (TCOs). Thin layers of zinc, gallium and molybdenum oxides present negligible absorption losses, which leads to a high output current. The project will optimise them as surface passivating layers, to achieve a high output voltage. TCOs can also provide good lateral conductivity, to boost the fill factor. The research proposes to create insight into the physical mechanisms of selective contacts for electrons and holes, paving the way for a range of innovative solar cell concepts. Transparent metal oxides open new windows of opportunity to increase the conversion efficiency of silicon solar cells using simpler fabrication processes.Read moreRead less
Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technolo ....Doped metal perovskites for electrocatalysis. This project aims to discover and design perovskite metal-oxide electrocatalyst materials and develop electrocatalytic methods for efficiently driving the oxygen evolution reaction and the oxygen reduction reaction. These are the two most crucial reactions in sustainable energy cycles involving water, hydrogen and oxygen. The project’s anticipated advances in electrocatalysis efficiency for these two reactions will benefit sustainable energy technologies such as fuel cells, metal air batteries and water splitting.Read moreRead less
Nanowire quantum well infrared photodetectors. This project aims to demonstrate semiconductor nanowire based quantum well infrared (IR) photodetectors for applications in chemical analysis, remote sensing, thermal imaging, environmental monitoring, space ranging and communications. By utilising one-dimensional nanowire detector architecture, the project expects that improved sensitivity, functionality and reduced cost can be achieved surpassing the performance of current IR technologies. This pr ....Nanowire quantum well infrared photodetectors. This project aims to demonstrate semiconductor nanowire based quantum well infrared (IR) photodetectors for applications in chemical analysis, remote sensing, thermal imaging, environmental monitoring, space ranging and communications. By utilising one-dimensional nanowire detector architecture, the project expects that improved sensitivity, functionality and reduced cost can be achieved surpassing the performance of current IR technologies. This project will pave the way for a new research and development platform for next generation large scale, low cost, high performance IR systems with commercialisation opportunities accessible to both high-end defence sectors and broader civilian industries.Read moreRead less
Fundamental electronic transport in emerging one-dimensional nanoelectronic devices. This project aims to understand the mechanisms limiting electronic transport in one-dimensional nanoelectronic devices and structures at temperatures relevant for practical device operation. One-dimensional nanoelectronic devices will be the building blocks of future technological innovation. This project will use a characterisation approach, numerical modelling and simulation, which promise to deliver knowledge ....Fundamental electronic transport in emerging one-dimensional nanoelectronic devices. This project aims to understand the mechanisms limiting electronic transport in one-dimensional nanoelectronic devices and structures at temperatures relevant for practical device operation. One-dimensional nanoelectronic devices will be the building blocks of future technological innovation. This project will use a characterisation approach, numerical modelling and simulation, which promise to deliver knowledge and analysis tools for ongoing innovation and optimisation in semiconductor nanoelectronics.Read moreRead less
III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for formi ....III-V semiconductor nanowire solar cells without p-n junctions. This project proposes a new class of nanowire solar cells that do not rely on conventional electrical (p-n) junction for photo-generated charge carrier separation. Instead the band structure of the semiconductors is engineered to form a misalignment which leads to the spatial separation of carriers. This approach is expected to fundamentally change the design of solar cells, eliminating the technologically challenging need for forming good electrical junctions, while retaining all advantages inherent to III-V semiconductor nanowire solar cells. More importantly, the device concept proposed is expected to have implications for a wider class of solar cells based on exotic/novel materials or nanostructures where achieving both n- and p-doping may be challenging.Read moreRead less
Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technolo ....Towards high performance compound semiconductor nanowire array solar cells. Semiconductor nanowires have great potential for photovoltaic applications due to their unique structural, electrical and optical properties. This project aims to establish a new research program to integrate highly sophisticated theoretical modelling, material growth and nanofabrication capabilities to develop high performance III-V compound semiconductor nanowire array solar cells. New concepts, strategies and technologies developed by this project will not only advance the fundamental understanding of many intriguing physics in nanowire materials and devices, but also pave the way towards high efficiency photovoltaics to address the world’s energy-related issues. Read moreRead less
III-V Semiconductor Nanowire Solar Cells. III-V semiconductors, proven as excellent photovoltaic materials, combined with unique properties of nanowires will be investigated as new materials for third generation high efficiency solar cells. It will lead to fundamental understanding of photovoltaic mechanisms in nanowires and demonstration of nanowire solar cells for future applications.
Nitride-based Compound Semiconductors for Solar Water Splitting. Global warming warrants urgent investment in clean and sustainable energy generation. This project aims to investigate the use of nitride semiconductors, a commonly used material for LEDs, and solar energy to generate hydrogen by splitting water molecules. These semiconductors have excellent light absorption efficiency and can be designed to better match the solar spectrum. The project will explore the underlying mechanism of light ....Nitride-based Compound Semiconductors for Solar Water Splitting. Global warming warrants urgent investment in clean and sustainable energy generation. This project aims to investigate the use of nitride semiconductors, a commonly used material for LEDs, and solar energy to generate hydrogen by splitting water molecules. These semiconductors have excellent light absorption efficiency and can be designed to better match the solar spectrum. The project will explore the underlying mechanism of light interaction with the semiconductor through band bending and surface engineering, and determine how this interaction affects the dissociation of water molecules. The concepts demonstrated in the project are expected to pave the way for further development of this technology for future applications. Read moreRead less