Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer sola ....Scanning Probe Microscopy for Fabrication and Analysis of Polymer Photovoltaics. Australian economic growth will depend increasingly on the provision of devices using materials designed at the molecular level. Scanning probe microscopy, which uses tips placed very close to surfaces to analyse or modify the surfaces with molecular precision, is an indispensible tool in designing such materials. In this project, scanning probe microscopy will be used to analyse and build structures on polymer solar cells in order to maximise the efficiency of the cells and build prototype nanoscale polymer devices. This will lead to the improvement in devices delivering sustainable energy production - a technology which has the promise of producing energy cheaply from sunlight.Read moreRead less
Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain thei ....Biomolecular optoelectronic materials and devices. The melanins are the molecules in our skin, eyes and hair that provide colour and protection from the sun. In addition to being important bio-molecules, they have properties which make them useful for high tech applications especially in electronics and optoelectronics. Unfortunately, our current understanding of these fascinating materials is poor. In our project we aim to solve this limiting problem. We will develop new science to explain their behaviour, and use this knowledge to create bio-compatible hi-tech materials and devices. We anticipate significant benefits from the perspectives of basic science and utilisation of biomaterials for new green technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0883019
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Organic Solar Cells Fabrication and Characterisation Facility. This application aims to provide key support to ongoing research projects in the area of organic solar cells, which will result in (1) an increase in quality and quantity of research publications and patents (2) a vital support that will establish the grounds for future industries in Australia and (3) a national contribution to the global fight against climate change.
Enhancing the Understanding and Performance of Passivating TiO2 Coatings for Photovoltaic Devices. Titanium dioxide (TiO2) has been widely used as an antireflection coating in the silicon (Si) photovoltaics industry as it exhibits excellent optical properties and low deposition cost. However, recently manufacturers have been turning to alternatives such as hydrogenated silicon nitride coatings that exhibit greatly improved electronic properties, but cost 4 - 10 times more to deposit. This proj ....Enhancing the Understanding and Performance of Passivating TiO2 Coatings for Photovoltaic Devices. Titanium dioxide (TiO2) has been widely used as an antireflection coating in the silicon (Si) photovoltaics industry as it exhibits excellent optical properties and low deposition cost. However, recently manufacturers have been turning to alternatives such as hydrogenated silicon nitride coatings that exhibit greatly improved electronic properties, but cost 4 - 10 times more to deposit. This project seeks to understand the fundamental limitations behind the poor surface passivation afforded by TiO2 to a Si wafer, and subsequently develop a passivating TiO2 coating that can reduce the cost of electricity generated by Si solar cells.Read moreRead less
Photoactive Semiconducting Biopolymers. The basic aims of this project are to elucidate, manipulate, and utilise the unique chemical and physical properties of a class of biopolymers called the melanins. These materials are the only known solid state semiconducting biopolymers, and are non-toxic, biocompatible, and biodegradable. Their use as active components in biomimetic soft electonic, optoelectronic or photovoltaic devices, has not hitherto been demonstrated. It is anticipated that the k ....Photoactive Semiconducting Biopolymers. The basic aims of this project are to elucidate, manipulate, and utilise the unique chemical and physical properties of a class of biopolymers called the melanins. These materials are the only known solid state semiconducting biopolymers, and are non-toxic, biocompatible, and biodegradable. Their use as active components in biomimetic soft electonic, optoelectronic or photovoltaic devices, has not hitherto been demonstrated. It is anticipated that the key outcomes from the project will be a demonstration of biopolymer-based photoelectrochemical and solid-state p-i-n solar cells, and an improved understanding of the physics and chemistry of these important biological macromolecules.Read moreRead less
Spray-on Hydrogenated Films for Solar Cells. A successful project will contribute to a reduction in the cost of photovoltaic solar energy. This goal might be reached directly, via the development of spray-on hydrogenated films, or indirectly, through an improved knowledge of hydrogen passivation. Either way, the project will provide Australian Partner Investigator, Spark Solar, with a manufacturing edge over its global competitors. In so doing, it will support the burgeoning photovoltaic industr ....Spray-on Hydrogenated Films for Solar Cells. A successful project will contribute to a reduction in the cost of photovoltaic solar energy. This goal might be reached directly, via the development of spray-on hydrogenated films, or indirectly, through an improved knowledge of hydrogen passivation. Either way, the project will provide Australian Partner Investigator, Spark Solar, with a manufacturing edge over its global competitors. In so doing, it will support the burgeoning photovoltaic industry in Australia, providing jobs in manufacturing and research, and increasing the viability of photovoltaic energy as an alternative to fossil fuels. The project will also help keep Australia at the forefront of advances in photovoltaics and semiconductors.Read moreRead less
Macromolecular Materials for Organic Solar Cells. The world is in the midst of a climate crisis driven by mankind's insatiable demand for fossil-fuel energy. Renewable technologies such as solar and wind will undoubtedly form part of our future energy mix. Solar cells in particular have great potential- especially in sunny countries like Australia. The uptake of solar cell technology is hampered by their current high cost and long payback time. This project concerns the development of new solar ....Macromolecular Materials for Organic Solar Cells. The world is in the midst of a climate crisis driven by mankind's insatiable demand for fossil-fuel energy. Renewable technologies such as solar and wind will undoubtedly form part of our future energy mix. Solar cells in particular have great potential- especially in sunny countries like Australia. The uptake of solar cell technology is hampered by their current high cost and long payback time. This project concerns the development of new solar cells based upon novel organic materials called dendrimers. These materials can be solution processed and will dramatically reduce cost and payback time in next generation devices.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0238960
Funder
Australian Research Council
Funding Amount
$940,000.00
Summary
High Performance Semiconductor Micromachining Facility. The purpose of this project is to make available to the Australian semiconductor research community a facility to undertake specialist deposition and etching tasks needed for fabrication of next generation solar cells, microelectronics, optronics, and micro-electromechanical systems. The facility will have the flexibility to allow independent control of major process parameters, allowing development of new fabrication technologies which wi ....High Performance Semiconductor Micromachining Facility. The purpose of this project is to make available to the Australian semiconductor research community a facility to undertake specialist deposition and etching tasks needed for fabrication of next generation solar cells, microelectronics, optronics, and micro-electromechanical systems. The facility will have the flexibility to allow independent control of major process parameters, allowing development of new fabrication technologies which will be generic to a wide range of semiconductor materials. In particular, the facility will be unique in its ability to perform processes at low temperatures, and under conditions that allow optimisation of the deposition and etching processes, without compromising the performance of delicate devices or exceeding the maximum process temperature limitations found in many mainstream semiconductor materials technologies.Read moreRead less
Towards a ten percent efficient organic solar cell. Organic photovoltaic (OPV) cells have the potential to reduce costs of electricity production significantly below those using traditional solar cells. Successful development of a 10% efficient organic solar cell of improved durability would not only increase the use of this environmentally sustainable energy source but also increase Australian manufacturing opportunities. Solar photovoltaics has been identified as one of the most desirable futu ....Towards a ten percent efficient organic solar cell. Organic photovoltaic (OPV) cells have the potential to reduce costs of electricity production significantly below those using traditional solar cells. Successful development of a 10% efficient organic solar cell of improved durability would not only increase the use of this environmentally sustainable energy source but also increase Australian manufacturing opportunities. Solar photovoltaics has been identified as one of the most desirable future energy options with the potential to displace fossil fuels and result in better utilisation of hydroelectricity resources. However, significant cost reduction as targeted by this project is required to exploit the full potential of this environmentally benign technology.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