Discovery Early Career Researcher Award - Grant ID: DE190101618
Funder
Australian Research Council
Funding Amount
$389,000.00
Summary
Tailoring multifunctional single site catalysts for carbon dioxide conversion. This project aims to develop multifunctional single site catalysts and collaborative surface sites to complete multi-step reactions using carbon dioxide (CO2) hydrogenation to higher alcohols with enhanced selectivity for large-chain alcohols. CO2 is an abundant and renewable carbon source for use as a feedstock, and closing the carbon cycle in an energy efficient manner has the potential for significant environmental ....Tailoring multifunctional single site catalysts for carbon dioxide conversion. This project aims to develop multifunctional single site catalysts and collaborative surface sites to complete multi-step reactions using carbon dioxide (CO2) hydrogenation to higher alcohols with enhanced selectivity for large-chain alcohols. CO2 is an abundant and renewable carbon source for use as a feedstock, and closing the carbon cycle in an energy efficient manner has the potential for significant environmental benefits. The project is expected to advance the knowledge in rational design of new catalysts for CO2 conversion and understanding the catalyst structure-property induced reaction mechanism. This will result in an improved understanding of the reaction kinetics of utilising CO2 as a feedstock.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
Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectros ....Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectroscopic studies combined with theoretical calculations will be used to elucidate the underlying reaction mechanisms of the synergistic effects of photon and thermal reduction of carbon dioxide . The success of the proposed project will allow the reduction of carbon dioxide, generate a cheap energy source in the form of environmentally benign hydrocarbons and close the carbon loop. Read moreRead less
Scaling-up microfluidic drying as an efficient route to manufacture uniform and functional particles as high-value products. This project aims to scale-up microfluidic spray drying and demonstrate the method as a viable option to manufacture monodisperse microparticles as bioactive carriers or microencapsulates, with better functional properties and uniformity. It aims to transform the manufacturing of high-value products for pharmaceuticals, functional foods and biotechnology applications and l ....Scaling-up microfluidic drying as an efficient route to manufacture uniform and functional particles as high-value products. This project aims to scale-up microfluidic spray drying and demonstrate the method as a viable option to manufacture monodisperse microparticles as bioactive carriers or microencapsulates, with better functional properties and uniformity. It aims to transform the manufacturing of high-value products for pharmaceuticals, functional foods and biotechnology applications and lift productivity by managing innovation for Australia’s industries.Read moreRead less
Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite ....Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite materials. Benefits from this project may include oxygen concentrators that are more portable and have longer battery life, both with industrial and medical applications.Read moreRead less
Pore Engineering of Chromatography Membranes for Bioseparation. Protein separation and purification is an essential unit operation in manufacturing processes of therapeutic proteins. The project aims to advance the practical applications of chromatography membrane, an emerging technology for protein separation and purification, by tailoring membrane pore geometry and surface functionality to achieve enhanced separation performance. The project expects to generate advanced knowledge and technique ....Pore Engineering of Chromatography Membranes for Bioseparation. Protein separation and purification is an essential unit operation in manufacturing processes of therapeutic proteins. The project aims to advance the practical applications of chromatography membrane, an emerging technology for protein separation and purification, by tailoring membrane pore geometry and surface functionality to achieve enhanced separation performance. The project expects to generate advanced knowledge and techniques in the fields of reactive polymer synthesis, functional membrane fabrication and application in bioseparation. The innovative membranes developed in the project are able to improve the production capacity of therapeutic protein manufacturing processes, providing significant economic benefits to Australia.Read moreRead less
Carbon Molecular Sieve Membranes for Organic Solvent Separation. Directly addressing the pressing challenge of organic solvent separation faced by numerous industries, the project aims to develop molecular sieve membranes with outstanding selectivity and solvent tolerance by constructing zeolite-carbon mixed matrix membrane via incorporating zeolite nanosheets into carbon materials. The project expects to generate advanced knowledge of nanosheet synthesis, membrane fabrication and selective mole ....Carbon Molecular Sieve Membranes for Organic Solvent Separation. Directly addressing the pressing challenge of organic solvent separation faced by numerous industries, the project aims to develop molecular sieve membranes with outstanding selectivity and solvent tolerance by constructing zeolite-carbon mixed matrix membrane via incorporating zeolite nanosheets into carbon materials. The project expects to generate advanced knowledge of nanosheet synthesis, membrane fabrication and selective molecule transport. The membranes developed in the project have great potentials for improving the production capacity and sustainability of Australian industries, e.g., pharmaceutical manufacturing, bioethanol production and petroleum refining, providing significant economic and environmental benefits to Australia.Read moreRead less
High value micron-sized particles from a novel antisolvent vapour spray drying system. Convective antisolvent precipitation is a novel route in producing particles from spray drying by adding an anti-solvent to the drying medium. This project will allow conventional spray dryers to produce more sophisticated ultrafine and encapsulated particles for use in food, pharmaceuticals and other high value applications.
All-solid-state Z-scheme photocatalysts for water treatment. The project aims to develop high-performance Z-scheme photocatalysts by using two-dimensional (2D) semiconductors as building blocks for low-cost, highly-efficient pathogen inactivation and emerging pollutant degradation in stormwater treatment. The project expects to generate new fundamental knowledge in the area of photocatalyst design and Z-scheme photocatalytic system, and advance the application of photocatalytic oxidation in wate ....All-solid-state Z-scheme photocatalysts for water treatment. The project aims to develop high-performance Z-scheme photocatalysts by using two-dimensional (2D) semiconductors as building blocks for low-cost, highly-efficient pathogen inactivation and emerging pollutant degradation in stormwater treatment. The project expects to generate new fundamental knowledge in the area of photocatalyst design and Z-scheme photocatalytic system, and advance the application of photocatalytic oxidation in water treatment. The expected outcomes of the project include novel 2D Z-scheme photocatalysts and enhanced capacity in stormwater management.Read moreRead less
Improving the scale-up of spray drying for bioactive extracts and fibres. The project will develop new processing techniques that will contribute to better functional foods and bioactive products from fruit and vegetable wastes. The total national crop of fruit and vegetables produces over 3 million tonnes of wastes, where the bioactive materials in the wastes have a potential value of $3 billion/year.