Using anisotropic thermal expansion in organic semiconductor thin films. This project aims to capitalise upon the recent discovery of negative thermal expansion in high-performance organic semiconductor films. Certain molecules’ chemical structures have a planar conjugated core and flexible sidechains. When highly anisotropic thermal expansion occurs, the sidechains take up most of the thermal expansion. When a negative thermal expansion occurs, the pi-pi stacking distance decreases upon anneali ....Using anisotropic thermal expansion in organic semiconductor thin films. This project aims to capitalise upon the recent discovery of negative thermal expansion in high-performance organic semiconductor films. Certain molecules’ chemical structures have a planar conjugated core and flexible sidechains. When highly anisotropic thermal expansion occurs, the sidechains take up most of the thermal expansion. When a negative thermal expansion occurs, the pi-pi stacking distance decreases upon annealing. This effect has been linked with higher charge mobilities, and a tighter molecular packing is locked in upon cooling. The potential applications of these high performance organic semiconductors includes chemical/biosensors, electronic paper, and radio frequency identification cards.Read moreRead less
Environmentally benign polymer solar cells. The project aims to prepare polymer solar cells, by developing water-compatible conjugated materials for the active layer. This technology would be cost-efficient and not use environmentally harmful solvents. The project would achieve aqueous compatibility of these hydrophobic molecules through substitution and careful positioning of functional groups. Fabrication processes will be optimised to incorporate these materials into solar cells, with a focus ....Environmentally benign polymer solar cells. The project aims to prepare polymer solar cells, by developing water-compatible conjugated materials for the active layer. This technology would be cost-efficient and not use environmentally harmful solvents. The project would achieve aqueous compatibility of these hydrophobic molecules through substitution and careful positioning of functional groups. Fabrication processes will be optimised to incorporate these materials into solar cells, with a focus on controlling the morphology of the active material. Determining the relationships between conjugated molecular design and cell performance should provide a new direction in solar-cell technology.Read moreRead less
Develop materials for stable and efficient printed polymer solar cells. The project aims to develop strategies to overcome current limitations of polymer solar cells by enhancing the thermal stability of these devices. This project expects to generate new knowledge in the area of stable and high-performance polymer solar cells, that can be manufactured by the printing industry in Australia. The expected outcome of this project includes new high performing materials, processing and additive strat ....Develop materials for stable and efficient printed polymer solar cells. The project aims to develop strategies to overcome current limitations of polymer solar cells by enhancing the thermal stability of these devices. This project expects to generate new knowledge in the area of stable and high-performance polymer solar cells, that can be manufactured by the printing industry in Australia. The expected outcome of this project includes new high performing materials, processing and additive strategies to overcome the key challenge to commercialising polymer solar cells. A significant benefit is their printability, providing the opportunity to establish a sovereign capability to manufacture low cost energy production systems in Australia.
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Industrial Transformation Research Hubs - Grant ID: IH130100016
Funder
Australian Research Council
Funding Amount
$1,633,554.00
Summary
ARC Research Hub for BioProcessing Advanced Manufacturing. ARC Research Hub for BioProcessing Advanced Manufacturing. The aim of the Research Hub is to develop functional materials to maximize the value of forest resources; and green chemistry and energy solutions for bioprocessing industries. Lignocellulosic streams will be converted into a complement of marketable materials, chemicals and energy products. Examples include new polymers and composites, smart packaging, chemical intermediates, fu ....ARC Research Hub for BioProcessing Advanced Manufacturing. ARC Research Hub for BioProcessing Advanced Manufacturing. The aim of the Research Hub is to develop functional materials to maximize the value of forest resources; and green chemistry and energy solutions for bioprocessing industries. Lignocellulosic streams will be converted into a complement of marketable materials, chemicals and energy products. Examples include new polymers and composites, smart packaging, chemical intermediates, fuel, green energy and nanocellulose and cellulosic fibre applications. These will drive advances in chemical engineering, materials and green chemistry for the full conversion of lignocellulosics. The Hub will complement research developments with short courses and a problem-based Masters in BioProcess Engineering to keep industry workers up to date with evolving science and technology.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH170100020
Funder
Australian Research Council
Funding Amount
$2,641,142.00
Summary
ARC Research Hub for Processing Lignocellulosics into High Value Products. The ARC Research Hub for Processing Lignocellulosics into High Value Products aims to convert renewable and readily-available biomass material and waste streams from the Australian Pulp, Paper and Forest Industry into new, high-value products that are in high demand in existing and developing markets. The Research Hub will translate leading scientific discoveries in biomass conversion into the manufacture of advanced mate ....ARC Research Hub for Processing Lignocellulosics into High Value Products. The ARC Research Hub for Processing Lignocellulosics into High Value Products aims to convert renewable and readily-available biomass material and waste streams from the Australian Pulp, Paper and Forest Industry into new, high-value products that are in high demand in existing and developing markets. The Research Hub will translate leading scientific discoveries in biomass conversion into the manufacture of advanced materials that can be used in the industries of the future. Research aims to identify new applications and products. They will be derived from lignocellulose through the advent of new smart paper packaging, green chemical and materials with unique properties. Benefits will flow to the pharmaceutical, chemicals, plastics and food packaging industries.Read moreRead less
Active channel organic transistors. The objective of our project is to create the next generation of electronic transistors based upon organic semiconductors. Specifically, the project will create devices for use in applications such as low power lighting, chemical sensing and lasers.
Australian Laureate Fellowships - Grant ID: FL160100067
Funder
Australian Research Council
Funding Amount
$2,888,048.00
Summary
Transformational lighting: changing the way we live. Transformational lighting: changing the way we live. This Fellowship aims to advance the science of ultrathin efficient lighting technologies based on low embedded energy organic light-emitting diodes (OLED). By creating innovative semiconductor materials and diode architectures that optimise each step in light generation—from charge injection, transport and capture to light emission—the project aims to deliver transformative OLED lighting tha ....Transformational lighting: changing the way we live. Transformational lighting: changing the way we live. This Fellowship aims to advance the science of ultrathin efficient lighting technologies based on low embedded energy organic light-emitting diodes (OLED). By creating innovative semiconductor materials and diode architectures that optimise each step in light generation—from charge injection, transport and capture to light emission—the project aims to deliver transformative OLED lighting that is more efficient than standard fluorescents by 50%. The intended outcomes of the project are design rules for OLED componentry, including thin, flexible architectures for deployment in a range of environments. The project would prototype the new technology at scale, demonstrating a large-area lighting module with power efficiency of 150 lm/W.Read moreRead less
Unravelling structure-function relationships in high mobility donor-acceptor co-polymers. This project seeks to understand the high-performance of a new generation of semiconducting plastics. This research will enable the development of low-cost printed electronics such as flexible displays and sensors.
Advanced Ionic Materials for Organic Photovoltaics. 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 pho ....Advanced Ionic Materials for Organic Photovoltaics. 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. Read moreRead less
Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical f ....Stretchable Organic Transistors for Wearable Electronics and Robotics. The project aims to address the challenges of fabricating stretchable organic transistors for applications in wearable electronics and robotics through the development of new semiconducting polymers with stretchability and integrating them into novel, stretchable organic transistor configurations. The project will take a molecular engineering approach to the complex needs of this challenge by combining appropriate chemical functionality which provides high charge carrier mobility with judiciously placed flexible spacers and side chains to provide mechanical dexterity. These novel polymers will be integrated into transistor structures and their fabricated arrays deposited on stretchable substrates will be used for a real world applications.Read moreRead less