Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit thr ....Efficient PV-Thermal Micro-concentrator. Australia must reduce its dependence on carbon sources for electricity, heating, and cooling. The PV-thermal hybrid micro-concentrator development will deliver a light-weight, low-profile, cost-effective system that can be installed in almost any situation, with versatile output that can deliver electricity at grid parity as well as providing water heating, space heating, industrial process heat, and solar cooling capabilities. The nation will benefit through enhanced energy independence, international research recognition, and reduced greenhouse gas emissions. Further, successful commercialisation of this technology will enhance Australia's research standing and provide a good royalty income that will fund future research and development.Read moreRead less
Advanced Sliver Solar Cells. The expected outcome of the proposed research is the development of second generation Sliver solar cell technology, encouraging large commercial impact, which would be of substantial benefit to Australia in terms of export income and employment. Origin Energy has committed >$60 million to the development and commercialisation of the first generation Sliver cell technology. Substantial further commercial investment is expected during scale-up for full scale manufactur ....Advanced Sliver Solar Cells. The expected outcome of the proposed research is the development of second generation Sliver solar cell technology, encouraging large commercial impact, which would be of substantial benefit to Australia in terms of export income and employment. Origin Energy has committed >$60 million to the development and commercialisation of the first generation Sliver cell technology. Substantial further commercial investment is expected during scale-up for full scale manufacturing.
Successful implementation of technology developed during the research will result in the displacement of fossil fuel technologies and corresponding greenhouse gas emissions reduction, assisting Government in its objective to make major cuts to greenhouse gas emissions.
Read moreRead less
Engineering stable, efficient perovskite solar cells. This project aims to address and resolve a critical issue facing perovskite solar cells which have enormous potential as a future technology for the large-scale generation of cheap, clean electricity: their instability under actual operating conditions. The project is expected to make significant fundamental advances in compositional, structural and interface engineering. This project will benefit the environment by paving the way for the wi ....Engineering stable, efficient perovskite solar cells. This project aims to address and resolve a critical issue facing perovskite solar cells which have enormous potential as a future technology for the large-scale generation of cheap, clean electricity: their instability under actual operating conditions. The project is expected to make significant fundamental advances in compositional, structural and interface engineering. This project will benefit the environment by paving the way for the widespread adoption of cheaper and more efficient solar cells.Read moreRead less
Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem d ....Perovskite-silicon tandem solar cells: a pathway to 30 per cent efficiency. This project aims to develop a new type of solar cell that is much more efficient than today’s commercial silicon solar cells. Increasing cell efficiency is one of the most effective ways to reduce the cost of solar electricity, but silicon cells are approaching practical and theoretical limits. This project expects to boost the efficiency of silicon solar cells by adding a low-cost solar cell on top to create a tandem device. The expected outcome is a solar cell that can convert more than 30 per cent of incident sunlight into electricity, compared to 20-25 per cent for current cells. Developing cheap, high efficiency solar cells should further reduce the cost of solar electricity, and accelerate the uptake of clean energy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100233
Funder
Australian Research Council
Funding Amount
$250,000.00
Summary
Characterisation of infrared imaging technologies. This project aims to establish a facility for two-dimensional (2D) infrared sensor array testing and prototyping. Systematic characterisation and prototyping of 2D imaging arrays is vital in showcasing and realising Australia's innovation and research investment in photodetector technologies. This facility will enable research on 2D imaging arrays, such as pixel yield and cross-talk, device reliability physics, failure mechanisms, noise and long ....Characterisation of infrared imaging technologies. This project aims to establish a facility for two-dimensional (2D) infrared sensor array testing and prototyping. Systematic characterisation and prototyping of 2D imaging arrays is vital in showcasing and realising Australia's innovation and research investment in photodetector technologies. This facility will enable research on 2D imaging arrays, such as pixel yield and cross-talk, device reliability physics, failure mechanisms, noise and long-term stability. The facility will demonstrate Australia's innovative imaging technologies, applicable in science, industry, defence and security, attracting interest from both Australian and international industries.Read moreRead less
The science and engineering of defects and impurities in photovoltaic silicon. This project will create the knowledge and techniques that are essential to make low-cost, impure silicon suitable for producing highly efficient solar cells. This will help to drive down the cost of solar electricity, since the silicon material itself is a significant component of the overall cost of most photovoltaic modules.
Discovery Early Career Researcher Award - Grant ID: DE160101368
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Silicon 2.0: The nature of grown-in defects in very high-purity silicon. This project aims to produce technologies to maximise the electronic quality of silicon and mitigate the negative impacts of defects on high-efficiency solar cells. The intended outcomes are the development of novel solar cell processes to produce defect-free silicon and new characterisation techniques to image defects in silicon wafers. This would allow high efficiency solar cells to overcome their current limits and unloc ....Silicon 2.0: The nature of grown-in defects in very high-purity silicon. This project aims to produce technologies to maximise the electronic quality of silicon and mitigate the negative impacts of defects on high-efficiency solar cells. The intended outcomes are the development of novel solar cell processes to produce defect-free silicon and new characterisation techniques to image defects in silicon wafers. This would allow high efficiency solar cells to overcome their current limits and unlock the potential of current processes to produce solar cells with efficiency above 26 per cent, providing more efficient and affordable solar electricity.Read moreRead less
Nanophotonic tandem designs for high efficiency solar cells. This project will develop high-efficiency tandem solar cells that combine established silicon cell technology with novel low-cost thin-film solar cells. It will incorporate nanostructured layers between the cells that selectively trap different wavelengths of light, maximising light absorption in the top cell. This will make it possible to use a very thin top cell, reducing the requirements on electronic quality of the material. This p ....Nanophotonic tandem designs for high efficiency solar cells. This project will develop high-efficiency tandem solar cells that combine established silicon cell technology with novel low-cost thin-film solar cells. It will incorporate nanostructured layers between the cells that selectively trap different wavelengths of light, maximising light absorption in the top cell. This will make it possible to use a very thin top cell, reducing the requirements on electronic quality of the material. This project will also develop self-assembly techniques to enable the new nanostructures to be fabricated quickly and cheaply but with a high degree of control. Such cells will allow open the door to higher efficiencies, and lower costs, than is achievable with conventional solar cells.Read moreRead less
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