Australian Laureate Fellowships - Grant ID: FL170100014
Funder
Australian Research Council
Funding Amount
$3,275,680.00
Summary
Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromo ....Light-Induced chemical modularity: a new frontier in macromolecular design. This project aims to develop powerful light-driven chemistries for the modular construction of advanced macromolecular materials. The expected outcome is a versatile, light-based precision macromolecular synthetic technology platform, enabling critical advances in soft matter material design and synthesis, ranging from selectivity control of chemical reactions and information-coded and biomimetic light-responsive macromolecules to advanced functional photoresists for 3D laser lithography as well as materials that self-report structural transformations by light or are reprogrammable in their properties by photonic fields. Harnessing the power of light as a precision tool for the construction of advanced macromolecular materials will provide technology outcomes for Australian manufacturing industries from electronics to health. This includes laser-driven 3D printing technology at the nano-level, light-adaptive smart reprogrammable coatings and materials, synthetic proteins responsive to light as well as tailor-made single cell niches.Read moreRead less
High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED ....High performance inks for solution based organic light emitting diodes manufacturing. This project aims to introduce an advanced solution processing and printing technique for organic light emitting diode (OLED) fabrication based on a set of innovative macromolecular chemistries. These proceed either photochemically or thermally, exploiting precision macromolecular designs of the polymer precursor materials, which contain advanced emitter systems developed by Cynora. Solution fabrication of OLED is a challenging, yet ultimately powerful, process with key advantages over current vacuum processing systems, especially with regard to production flexibility, cost and OLED size. The project will provide a functioning technology platform for solution OLED fabrication.Read moreRead less
The crucial role of organic-inorganic interfaces in the performance of organic optoelectronic devices. Organic electronic devices such as organic light emitting diodes and organic solar cells are expected to lead to substantial benefits over conventional electronic components. However, there is increasing evidence that the interface between the organic layers and the inorganic electrodes (or active components in hybrid devices) could be sub-optimal in terms of critical properties such as electro ....The crucial role of organic-inorganic interfaces in the performance of organic optoelectronic devices. Organic electronic devices such as organic light emitting diodes and organic solar cells are expected to lead to substantial benefits over conventional electronic components. However, there is increasing evidence that the interface between the organic layers and the inorganic electrodes (or active components in hybrid devices) could be sub-optimal in terms of critical properties such as electron transfer and stability. The aim of this project is to understand the structure and properties of such interfaces and to probe their behaviour at elevated temperatures. The results will pave the way for organic electronic devices to become a commercial reality.Read moreRead less
Janus particles and nanorattles: new materials for paint technology. This project will pave the way for self cleaning paints that achieve opacity with greatly reduced titanium dioxide levels. Painted surfaces will maintain their clean and new look for longer and a clean town look will be much more readily maintained. More efficient use of titanium dioxide will reduce the need for sand mining and reduce the cost of quality paint.
Functional molecular nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards more efficient energy systems and smarter technologies. Through the strategic assembly of new classes of molecular nanomaterials, this project will lead to important fundamental advances in nanoscience and will underpin a range of new high-level technologies.
Smart materials from semi-soft particles. This project will combine precision polymer chemistry to material science to develop structured nanoparticles for applications in photonics and shape memory materials.
Sulfoxide Polymers - A New Paradigm in Polymer Design. Low fouling polymers are important for moderating interactions of molecules and particles with cells. In pharmaceutical sciences they are essential tools for extending the pharmacokinetics of dissolved drugs. However, the widely-used low-fouling polymer, poly(ethylene glycol) (PEG) has been recently reported to induce formation of anti-PEG antibodies. Polymeric alternatives to PEG are thus desperately needed. We introduce in this project sup ....Sulfoxide Polymers - A New Paradigm in Polymer Design. Low fouling polymers are important for moderating interactions of molecules and particles with cells. In pharmaceutical sciences they are essential tools for extending the pharmacokinetics of dissolved drugs. However, the widely-used low-fouling polymer, poly(ethylene glycol) (PEG) has been recently reported to induce formation of anti-PEG antibodies. Polymeric alternatives to PEG are thus desperately needed. We introduce in this project super-hydrophilic polymers incorporating sulfoxide groups, mimics of the polar solvent DMSO. The project aims to explore how polymer architecture can enhance biocompatibility and reduce biofouling. The outcome will be a new class of low-fouling polymeric materials with broad application in the biosciences.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100109
Funder
Australian Research Council
Funding Amount
$530,000.00
Summary
Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-t ....Small molecule X-ray molecular structure elucidation facility. X-ray diffraction plays a key role in identification and molecular characterisation. X-ray techniques are the single most widely used analytical resource in structure determination and provide invaluable information for scientists working in the fields of synthesis, nanotechnology, polymer chemistry, and protein chemistry, amongst many others. The facility brings together a multidisciplinary team of scientists and provides state-of-the-art research and training facilities for these techniques.Read moreRead less
Phase Change Materials for Wind and Solar Energy Storage. This project aims to develop and demonstrate new phase change materials to advance the technology of thermal energy storage. The project will focus on new materials that store thermal energy in the temperature range between 100 - 220°C that is optimal for distributed storage of solar and wind energy. The utility and economics of renewable energy sources are strongly limited by their intermittent nature and inexpensive means of storage are ....Phase Change Materials for Wind and Solar Energy Storage. This project aims to develop and demonstrate new phase change materials to advance the technology of thermal energy storage. The project will focus on new materials that store thermal energy in the temperature range between 100 - 220°C that is optimal for distributed storage of solar and wind energy. The utility and economics of renewable energy sources are strongly limited by their intermittent nature and inexpensive means of storage are urgently required. Expected outcomes of this project include a practical technology, which can be implemented at household and industry level, providing cheap energy from zero-carbon sources. The project aims to provide significant benefits to energy users and support further development of renewables.Read moreRead less
Designing disorder into ionic materials for clean energy applications. . This project aims to develop new materials designed to possess optimum properties for targeted clean energy technologies. By the design of specific ion chemistries, we aim to produce materials that absorb large amounts of thermal energy, as needed in energy storage and refrigeration applications. Their large internal free volume will offer unique properties for energy-consuming gas separation applications. Expected outcomes ....Designing disorder into ionic materials for clean energy applications. . This project aims to develop new materials designed to possess optimum properties for targeted clean energy technologies. By the design of specific ion chemistries, we aim to produce materials that absorb large amounts of thermal energy, as needed in energy storage and refrigeration applications. Their large internal free volume will offer unique properties for energy-consuming gas separation applications. Expected outcomes from the project include (i) fundamental understanding of ion design, (ii) a suite of new materials with advantageous properties for energy application. The expected benefits include advancement of technologies that support renewable energy storage and a reduction in energy costs and harmful emissions from refrigeration.Read moreRead less