Microspheres from (Sun)Light – A Sustainable Materials Platform. This project will break new ground in light-induced step-growth precipitation polymerisation techniques for polymer particle formation that do not require any initiator, surfactants, additives or heating, thus constituting an environmentally friendly process. The project will establish the underpinning photochemical particle formation processes and establish a broad monomer base for the production of particles with a wide property ....Microspheres from (Sun)Light – A Sustainable Materials Platform. This project will break new ground in light-induced step-growth precipitation polymerisation techniques for polymer particle formation that do not require any initiator, surfactants, additives or heating, thus constituting an environmentally friendly process. The project will establish the underpinning photochemical particle formation processes and establish a broad monomer base for the production of particles with a wide property profile, including particles with tailored surface properties and the ability to degrade upon a defined trigger signal. Scaling the particles' synthesis, including using Australian sunlight, will enable multi-gram production allowing real-world applications.Read moreRead less
Mid-Career Industry Fellowships - Grant ID: IM230100090
Funder
Australian Research Council
Funding Amount
$1,053,046.00
Summary
Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outco ....Multi material 3D Printing. This project aims to further develop a new 3D printing technique commercialised by an Australian start-up company. Current electronics manufacturing is extremely capital intensive, slow and restrictive in 3D design. The 3D printing method proposed in this application will disrupt the current advanced manufacturing eco system; creating unique methods to unlock advances in diverse markets for example, photovoltaics, printed circuit boards and sensors. The expected outcomes of this project are to create new commercial opportunities for the next generation of 3D printed electronics. This will provide significant benefits, creating unique capability to manufacture devices in 3D - faster, cheaper and with reduced reliance on global supply chains.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL220100016
Funder
Australian Research Council
Funding Amount
$2,738,854.00
Summary
Light-Driven Manufacturing for (Re)Programmable Materials. This Laureate Fellowship aims to develop a suite of chemical reactions independently activated by specific colours of light for the precise synthesis of functional macromolecules and the fabrication of (re)programmable polymeric materials. The outcome of this Laureate will be the direct production of advanced 3D printed objects with tuneable properties and functions by exploiting different wavelengths of light. This research unlocks the ....Light-Driven Manufacturing for (Re)Programmable Materials. This Laureate Fellowship aims to develop a suite of chemical reactions independently activated by specific colours of light for the precise synthesis of functional macromolecules and the fabrication of (re)programmable polymeric materials. The outcome of this Laureate will be the direct production of advanced 3D printed objects with tuneable properties and functions by exploiting different wavelengths of light. This research unlocks the structural precision of Nature and the next-generation capabilities of reshapability. These innovative tools will revolutionise 3D printing methods, which will create a new era of advanced manufacturing.Read moreRead less
Sustainable Reversible Polymerisation. This project aims to address the problem of the current lack of efficient chemical recyclability of polymers. For the majority of polymers, no methods exist so far that are scalable and economic at the same time. To reach this aim, we will utilise a mixture of clever chemical concepts with continuous flow engineering. This project expects to generate new knowledge in the area of depolymerisation and chemical recycling methods. The expected outcome of this p ....Sustainable Reversible Polymerisation. This project aims to address the problem of the current lack of efficient chemical recyclability of polymers. For the majority of polymers, no methods exist so far that are scalable and economic at the same time. To reach this aim, we will utilise a mixture of clever chemical concepts with continuous flow engineering. This project expects to generate new knowledge in the area of depolymerisation and chemical recycling methods. The expected outcome of this project is a scalable process and its practical demonstration for full chemical recycling of various polymers used in everyday applications. This will provide a benefit to society as it allows to tackle plastic pollution problems, and creates avenues to green methods in plastic recycling.
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Data Driven Polymer Synthesis. This project aims at full digitalization of the synthesis of high-added-value materials via combination of chemistry with data science and by constructing a fully automated robotic synthesis machine. The project expects to provide the data basis for advanced artificial intelligence application and its implementation. If successful, this will enable the prediction and automatic optimization of chemical reactions, providing rapid and more precise development of new m ....Data Driven Polymer Synthesis. This project aims at full digitalization of the synthesis of high-added-value materials via combination of chemistry with data science and by constructing a fully automated robotic synthesis machine. The project expects to provide the data basis for advanced artificial intelligence application and its implementation. If successful, this will enable the prediction and automatic optimization of chemical reactions, providing rapid and more precise development of new materials. This project will provide the benefit of significantly increasing the ability of Australian industry to use novel digital chemistry tools and to create revenue by faster product development, aiding in securing the over 60 000 jobs in this industry in Australia.Read moreRead less
A platform technology for developing mesoporous polymer particles. This project aims to apply polymerisation-induced self-assembly process to develop triggerable mesoporous polymer particles as advanced functional materials for various applications. By combining this scalable process and automated synthesis technique, mesoporous polymer particles that can disassemble in response to external triggers, such as light, redox conditions and enzymes, will be developed. The knowledge gained from this r ....A platform technology for developing mesoporous polymer particles. This project aims to apply polymerisation-induced self-assembly process to develop triggerable mesoporous polymer particles as advanced functional materials for various applications. By combining this scalable process and automated synthesis technique, mesoporous polymer particles that can disassemble in response to external triggers, such as light, redox conditions and enzymes, will be developed. The knowledge gained from this research will allow researchers to fully understand the formation and evolution mechanism of inverse bicontinuous structures observed in nature and produced in synthetic labs. Importantly, the applications of these novel stimuli-responsive particles as nano-carriers and templating scaffolds will be investigated.Read moreRead less