Advanced Materials from Automated Synthesis of Sequence-Defined Polymers. The project aims to develop industrially scalable and environmentally friendly methods for synthesis of sequence-defined multiblock copolymers (polymer chains containing segments of different polymer types) using automated synthesis methods. The materials to be explored will be largely based on renewable biomass-derived monomeric building blocks. Such polymers are able to undergo microphase separation into spatially period ....Advanced Materials from Automated Synthesis of Sequence-Defined Polymers. The project aims to develop industrially scalable and environmentally friendly methods for synthesis of sequence-defined multiblock copolymers (polymer chains containing segments of different polymer types) using automated synthesis methods. The materials to be explored will be largely based on renewable biomass-derived monomeric building blocks. Such polymers are able to undergo microphase separation into spatially periodic compositional patterns, thereby providing access to a vast range of nano-engineered materials. This would enable design and synthesis of new advanced materials, making use of renewable resources and supporting the circular economy, with diverse potential applications ranging from nanomedicine to materials science.Read moreRead less
Faster, greener, stronger: a new approach to synthesis of polymer materials. The project will investigate new approaches towards polymer material synthesis in the complete absence of hazardous solvents, with the aim of creating materials that have superior physical or chemical properties compared to those prepared using existing methods. This project is significant for driving advances in material design and characterization using simple starting materials and environmentally sustainable conditi ....Faster, greener, stronger: a new approach to synthesis of polymer materials. The project will investigate new approaches towards polymer material synthesis in the complete absence of hazardous solvents, with the aim of creating materials that have superior physical or chemical properties compared to those prepared using existing methods. This project is significant for driving advances in material design and characterization using simple starting materials and environmentally sustainable conditions. Expected outcomes include the production of unique nanomaterials, hydrogels and polymer monoliths with targeted applications, in addition to advances in 3D printing. This project will significantly benefit the sustainable material manufacturing industry into the future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100616
Funder
Australian Research Council
Funding Amount
$421,574.00
Summary
Development of high-performance flame-retardant one-component epoxy resins. This project will create a new class of phosphorus/imidazole oligomers for single-component epoxy resins with superior storage stability, fire retardancy and mechanical properties. By establishing a fundamental understanding of the structure-composition-property relationships of one-component epoxy resins, it will address two major challenges - high reactivity and short shelf life, and poor flame retardancy and mechanica ....Development of high-performance flame-retardant one-component epoxy resins. This project will create a new class of phosphorus/imidazole oligomers for single-component epoxy resins with superior storage stability, fire retardancy and mechanical properties. By establishing a fundamental understanding of the structure-composition-property relationships of one-component epoxy resins, it will address two major challenges - high reactivity and short shelf life, and poor flame retardancy and mechanical properties, which limit practical applications. This project will develop environmentally benign, flame-retardant oligomers, reducing fire hazards, protecting lives, property and the environment, by replacing current flammable epoxy resins used in electrical, construction and transportation.Read moreRead less
Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fi ....Fire-Retardant Composite Resins for Bushfire-Safe Wind Farm Infrastructures. This project aims to develop advanced fire-retardant composite resins for manufacturing bushfire-safe wind farm infrastructures. The innovation of the project is the development of a new class of low-cost, novel, highly effective fire retardants and their value-added fire-retardant composite resins with well-preserved physical properties. This will be achieved by understanding the composition-property relationship of fire retardants and optimising their synthetic parameters. The project will help position Australia’s advanced composite manufacturing at the forefront of technology. It will also accelerate Australia’s energy transition to renewables by enabling bushfire-safe wind farm infrastructure.Read moreRead less
Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installation ....Lightweight Photovoltaic Modules for Low-Load Capacity Building Roofs. This project aims to develop lightweight and reliable high efficiency photovoltaic modules that expand solar energy installations onto low-load capacity building roofs. New lightweight materials will be developed for packaging with multi-functionalities such as fast heat dissipation. This project will produce economical prototypes and enable and
facilitate cost reduction of crystalline silicon photovoltaic module installations on lightweight buildings, overcoming current constraints of heavy glass modules and making more solar energy exploited in both Australia’s urban and rural areas. This will get steps closer to zero emission buildings, by providing renewable energy alternative to conventional fossil fuel-based power generation.Read moreRead less
Orthogonal Sensing Strategies for Soft Sensors to Discern Multiple Stimuli . The project seeks to create new orthogonal sensing technologies that enable a single soft sensor to detect multiple mechanical and thermal stimuli, overcoming the challenge of cross-talk between stimuli. The project expects to generate new knowledge of orthogonal sensing mechanisms and the effects of microstructure designs. The expected outcomes include novel soft sensors capable of accurately detecting pressure, stretc ....Orthogonal Sensing Strategies for Soft Sensors to Discern Multiple Stimuli . The project seeks to create new orthogonal sensing technologies that enable a single soft sensor to detect multiple mechanical and thermal stimuli, overcoming the challenge of cross-talk between stimuli. The project expects to generate new knowledge of orthogonal sensing mechanisms and the effects of microstructure designs. The expected outcomes include novel soft sensors capable of accurately detecting pressure, stretch, shear, and temperature simultaneously. The new technologies are expected to support Australian companies in developing, producing and exporting sensors for soft robots and wearable devices for health monitoring, an area recognized as a key priority by the Federal Government’s Industry Growth Centres.Read moreRead less
Bioinspired Ceramifiable Fire-Retardant Composite Coatings. This project aims to design bioinspired, adhesive, ceramifiable fire-retardant coatings through understanding their composition-property relationship and fire-retardant mechanism. The fire-retardant coatings are then applied to typical polymer foams to create fire-safe building thermal insulation materials. This project will generate new knowledge in materials science that helps to expedite next-generation advanced fire-retardant coatin ....Bioinspired Ceramifiable Fire-Retardant Composite Coatings. This project aims to design bioinspired, adhesive, ceramifiable fire-retardant coatings through understanding their composition-property relationship and fire-retardant mechanism. The fire-retardant coatings are then applied to typical polymer foams to create fire-safe building thermal insulation materials. This project will generate new knowledge in materials science that helps to expedite next-generation advanced fire-retardant coatings for a variety of flammable substrates. Expected outcomes of this project are cost-effective fire-retardant coatings and fire-safe, inexpensive thermal insulation materials. This project will bring significant economic benefits to Australia and help to create fire-resilient and energy-efficient buildings.Read moreRead less
Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engin ....Smart materials for atmospheric water management and water harvesting. Fresh water is a scarce resource in many parts of the globe but uncomfortably over-supplied in other regions. Dehumidifying machines, such as air conditioners, are extensively used in humid climates to enhance human comfort, but with great energy costs. Likewise, the production of potable water in remote dry regions is energy intensive. We propose novel hyper-absorbent desiccating polymers combined into sorption-powered engines inspired by nastic movements in plants to develop extremely efficient dehumidifiers and water harvesting machines. These polymer actuators can help address the auto-acceleration of climate change caused by the increasing use of air conditioners and provide cheap, clean water for remote communities.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100917
Funder
Australian Research Council
Funding Amount
$457,647.00
Summary
Manufacturing Nanostructured Metallic Materials via 3D Printed Polymers. This project aims to develop additive manufacturing processes capable of rapidly producing nanostructured polymer and metallic materials with tuneable physical and chemical properties. This project expects to develop new knowledge and chemical processes, allowing the rational design of functional materials with applications in catalysis, energy storage, and chemical separations. Expected outcomes include more energy efficie ....Manufacturing Nanostructured Metallic Materials via 3D Printed Polymers. This project aims to develop additive manufacturing processes capable of rapidly producing nanostructured polymer and metallic materials with tuneable physical and chemical properties. This project expects to develop new knowledge and chemical processes, allowing the rational design of functional materials with applications in catalysis, energy storage, and chemical separations. Expected outcomes include more energy efficient and environmentally benign methods for functional materials synthesis, and increased understanding of structure-property-performance relationships in nanostructured materials. This should provide benefits to Australia by providing cost-effective routes for materials used in energy, health, and water.Read moreRead less