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Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at ....Sequence-defined polymers and green chemistry. This project aims to synthesise polymers that have precise chemical structure and mimic the biological activities of natural biopolymers like peptides and proteins. Monomer sequence regulation in these natural biopolymers is important in biology and necessary for crucial features of life, such as molecular recognition, self-replication and catalysis. Current artificial techniques for biopolymer synthesis are time consuming and present low yields at high costs. This project expects its new materials will increase manufacturing sustainability, chemical diversity and industrial viability; produce health benefits for Australia by improving chemotherapy and diagnosis for diseases; and benefit the Australian economy.Read moreRead less
Understanding and controlling the stereochemistry of free-radical polymerisation. The stereochemistry of a molecule, which relates to the relative spatial arrangement of its atoms, can have a profound effect on its physical and chemical properties. This project will use a computer-guided experimental approach to design new methods for controlling the stereochemistry of the polymers formed in free-radical polymerisation.
Transformer 3D Nanostructures: Stimuli Responsive Polymers. This research program will develop smart nanostructures that will be capable of producing high value added products using cheap polymer materials but achieving a much greater design capacity for end-use functions. The knowledge gained from this project will have potential applications in many areas where nanomaterials and polymers are used, including high strength coatings, conducting coatings for the electronic industry, drug and vacci ....Transformer 3D Nanostructures: Stimuli Responsive Polymers. This research program will develop smart nanostructures that will be capable of producing high value added products using cheap polymer materials but achieving a much greater design capacity for end-use functions. The knowledge gained from this project will have potential applications in many areas where nanomaterials and polymers are used, including high strength coatings, conducting coatings for the electronic industry, drug and vaccine delivery devices, tissue scaffolds, nanosensors, and gene delivery. These polymer techniques will enable Australian Industry to significantly improve product performance by providing advanced features and capabilities previously unavailable.Read moreRead less
Vesicles stabilised by compressed carbon dioxide as nanoreactors and templates for radical polymerisation. A new environmentally friendly method for synthesis of surfactant vesicles involving stabilisation using low pressure carbon dioxide will be applied to the synthesis of hollow polymeric nanoparticles and polymer of well-defined structure. The resulting polymeric structures will have applications in drug delivery and nano-engineered materials.
Stereolithographic Additive Manufacturing of Semicrystalline Thermoplastics. This project aims to advance the development of high-throughput stereolithographic additive manufacturing of thermoplastic polymers and composites by employing a multi-colour irradiation schemes in conjunction with photopolymerisable, ring-opening monomer resin formulations. The fundamental scientific understanding, engineering expertise, and concomitant technology advances generated by this project are anticipated to e ....Stereolithographic Additive Manufacturing of Semicrystalline Thermoplastics. This project aims to advance the development of high-throughput stereolithographic additive manufacturing of thermoplastic polymers and composites by employing a multi-colour irradiation schemes in conjunction with photopolymerisable, ring-opening monomer resin formulations. The fundamental scientific understanding, engineering expertise, and concomitant technology advances generated by this project are anticipated to enable additive manufacturing to transition from the rapid prototyping of individual, unique items to the high volume production of robust, reprocessable plastic parts. By obviating the large capital expense of conventional fabrication, this developed technology should provide a path to reinvigorate Australian manufacturing.Read moreRead less
Naturally derived photoinitiators for biocompatible 3D printing. This project aims to develop an environmentally-friendly approach to naturally derived photoinitiators which are applicable to 3D printing through low-energy, visible light-induced polymerisation, and explore their application in the fabrication of biocompatible polymeric materials. Traditional polymer manufacturing processes such as thermopolymerisation employ hazardous chemicals which present health and environmental risks. This ....Naturally derived photoinitiators for biocompatible 3D printing. This project aims to develop an environmentally-friendly approach to naturally derived photoinitiators which are applicable to 3D printing through low-energy, visible light-induced polymerisation, and explore their application in the fabrication of biocompatible polymeric materials. Traditional polymer manufacturing processes such as thermopolymerisation employ hazardous chemicals which present health and environmental risks. This project expects to expand fundamental scientific knowledge of photochemistry, polymer chemistry and biology through the development of a novel, economical, clean, commercially-relevant platform (3D printing) for the fabrication of polymeric materials.Read moreRead less
Smart polymer-DNA hybrids as recognition sites for advanced DNA nanotechnology applications. This project aims to design and synthesise a new family of DNA-conjugated chain transfer agents for the positional control of DNA in a broad range of 2D and 3D 'smart' polymer-DNA hybrid materials. These bioconjugated materials will be investigated to understand the fundamental self-assembly processes which underpin emerging dynamic DNA nanotechnologies. This timely research will revolutionise the use of ....Smart polymer-DNA hybrids as recognition sites for advanced DNA nanotechnology applications. This project aims to design and synthesise a new family of DNA-conjugated chain transfer agents for the positional control of DNA in a broad range of 2D and 3D 'smart' polymer-DNA hybrid materials. These bioconjugated materials will be investigated to understand the fundamental self-assembly processes which underpin emerging dynamic DNA nanotechnologies. This timely research will revolutionise the use of biologically inspired intelligent metamaterials for use in medical diagnostics, DNA computing and DNA nanomachines.Read moreRead less
Solar-Driven C-H Functionalization Reactions. This project aims to investigate the functionalization reaction of unreactive C-H bonds using light as the source of energy. Light is a transformative change to synthesis as thermal activation is exchanged to solar activation. The latter gives access to excited state chemistry and enables reaction steps that are thermally inaccessible. It is a key strategy to leverage synthesis to the demands of the 21st century and to minimise its ecologic footprint ....Solar-Driven C-H Functionalization Reactions. This project aims to investigate the functionalization reaction of unreactive C-H bonds using light as the source of energy. Light is a transformative change to synthesis as thermal activation is exchanged to solar activation. The latter gives access to excited state chemistry and enables reaction steps that are thermally inaccessible. It is a key strategy to leverage synthesis to the demands of the 21st century and to minimise its ecologic footprint. At the same time this strategy provides a lever to profoundly impact and drive new concepts in synthesis. Significant benefits are expected, such as increase in fundamental knowledge on photochemical processes, but also the access to new materials for applications as drugs or OLEDs.Read moreRead less
Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional ....Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional materials, mechanism, catalytic engineering, and sustainable separation processes. This project will provide significant benefits in renovating smart nanomaterials in advanced manufacturing and clean environmental technologies, promoting Australia’s economic development and environment protection.Read moreRead less
Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computa ....Computer-Aided Design of High-Performance Photocatalysts for Solar Hydrogen Production Based on Red Titanium Dioxide. Large-scale generation of energy by solar conversion is critical for future sustainability. This project aims to develop high performance materials to efficiently convert solar energy to hydrogen - a clean fuel. Starting from the newly developed material red titanium dioxide, novel strategies for improved photocatalytic materials will be proposed and evaluated by advanced computational approaches. Key issues for solar-to-hydrogen conversion will be clarified. The materials, knowledge and strategies achieved by this project will dramatically enhance current solar technology and in particular will advance the development of low-cost hydrogen production from water. Read moreRead less