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
Intracellular manufacturing - high performance biomaterials from methane. The aim of this project is to produce high performance biodegradable polymers directly from methane. The key innovation is employing cutting-edge community genomic and transcriptomic approaches to characterise intracellular production lines in order to tailor polyhydroxybutyrate-co-valerate (PHBV) copolymer microstructures. This is a truly multidisciplinary project bringing together engineers, polymer scientists and molecu ....Intracellular manufacturing - high performance biomaterials from methane. The aim of this project is to produce high performance biodegradable polymers directly from methane. The key innovation is employing cutting-edge community genomic and transcriptomic approaches to characterise intracellular production lines in order to tailor polyhydroxybutyrate-co-valerate (PHBV) copolymer microstructures. This is a truly multidisciplinary project bringing together engineers, polymer scientists and molecular biologists. It is expected that a direct outcome of the project will be the first PHBV copolymer from methane. As such, the project aims to develop technology for the production of tough, flexible and affordable biopolymers and, at the same time, provide an opportunity to add value to methane.Read moreRead less
Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membran ....Non-polyamide-based polymer membranes for efficient water processing. This project aims to develop an innovative, two-dimensional nanosheet scaffold polymerisation technique for the fabrication of advanced membranes. Membrane technology plays a key role in wastewater treatment and water desalination and purification. However, current membranes are not stable in an oxidation environment such as chlorine, which leads to significant membrane replacement costs. Through the development of new membrane fabrication technology the project aims to produce non-polyamide-based polymer membranes with outstanding oxidation tolerance and separation properties. This will potentially simplify membrane processes, and improve water processing efficiency in wastewater treatment for power generation, and clean drinking water production.
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Development of Fire Retardant Thermal Insulation Materials for Buildings. This Fellowship proposal aims to develop next-generation fire-retardant rigid polymer foams (RPF)-based thermal insulation materials for buildings. Through investigating fire-retardancy, mechanical and ageing properties, we will fundamentally understand the structure/composition - performance relationships of as-designed nanostructured fire-retardant polymer coatings and will achieve robust, durable and fire-retardant coat ....Development of Fire Retardant Thermal Insulation Materials for Buildings. This Fellowship proposal aims to develop next-generation fire-retardant rigid polymer foams (RPF)-based thermal insulation materials for buildings. Through investigating fire-retardancy, mechanical and ageing properties, we will fundamentally understand the structure/composition - performance relationships of as-designed nanostructured fire-retardant polymer coatings and will achieve robust, durable and fire-retardant coatings. This project will then apply the fire-retardant coatings to the RPF to create the target fire-retardant thermal insulation materials. New knowledge and patentable technologies to be generated will bring significant benefits to Australia by reducing energy costs and economic losses associated with building fires.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100583
Funder
Australian Research Council
Funding Amount
$445,000.00
Summary
Engineering of biocatalysis in metal-organic frameworks for CO2 conversion. Transforming the greenhouse gas carbon dioxide (CO2) into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to architect a biocascade system in metal-organic frameworks (MOFs) for artificial CO2 conversion. Learned from the living organisms, a whole biocatalysis unit including enzymes and cofactors will be encased and protected in an artificial porous ....Engineering of biocatalysis in metal-organic frameworks for CO2 conversion. Transforming the greenhouse gas carbon dioxide (CO2) into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to architect a biocascade system in metal-organic frameworks (MOFs) for artificial CO2 conversion. Learned from the living organisms, a whole biocatalysis unit including enzymes and cofactors will be encased and protected in an artificial porous polymeric MOF coating. This approach is expected to deliver robust biocatalysts with high reaction-activity and chemo-selectivity in converting CO2 into methanol under the industrial operating condition, involving thermal, pH, and chemical stressors. This advancement will contribute to a carbon-neutral industry and society.Read moreRead less
Scale-up of catalytic furandicarboxylic acid production at room temperature. This project will use new knowledge acquired from our laboratory-scale discoveries to develop a new process feasible for industrial-scale production of 2,5-furandicarboxylic acid (FDCA). The method makes FDCA, a platform chemical for future chemical industry, from a completely renewable source derived from plant sugars, 5-hydroxymethyl-furfural. This is an essential process for production of biodegradable plastic from s ....Scale-up of catalytic furandicarboxylic acid production at room temperature. This project will use new knowledge acquired from our laboratory-scale discoveries to develop a new process feasible for industrial-scale production of 2,5-furandicarboxylic acid (FDCA). The method makes FDCA, a platform chemical for future chemical industry, from a completely renewable source derived from plant sugars, 5-hydroxymethyl-furfural. This is an essential process for production of biodegradable plastic from sugar that has not been commercialised. This technology will realise sizeable industrial-scale production of FDCA at low costs and without heating. The production development of this valuable commodity from renewable plant sugars will provide high-quality postgraduate training in future green chemical production methods.Read moreRead less