High purity formaldehyde production from carbon oxides. This project aims to investigate the detailed reaction mechanism of a green chemistry route of producing formaldehyde by reducing carbon monoxide and carbon dioxide in liquid phase. Formaldehyde is a widely used feedstock for chemical industries, but is not considered a green chemical because it is produced using natural gas as the feed, which loses over 61 per cent of energy. This project will maximise the yield and purity of the product, ....High purity formaldehyde production from carbon oxides. This project aims to investigate the detailed reaction mechanism of a green chemistry route of producing formaldehyde by reducing carbon monoxide and carbon dioxide in liquid phase. Formaldehyde is a widely used feedstock for chemical industries, but is not considered a green chemical because it is produced using natural gas as the feed, which loses over 61 per cent of energy. This project will maximise the yield and purity of the product, making it commercially viable. This project’s method for producing formaldehyde is expected to reduce the capital cost and energy losses.Read moreRead less
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
Heterogeneous hydrophilic catalysts for green oxidation in bio-refining. The project aims to address one significant global challenge of developing green processes for producing high value chemicals from biomass, to enhance the environmental performance and cost-efficiency of bio-refining. This project aims to develop a new class of heterogeneous nanocatalysts with hydrophilic Co (salen) complexes for biomass oxidation in water rather than toxic solvent. This project will use this to devise prac ....Heterogeneous hydrophilic catalysts for green oxidation in bio-refining. The project aims to address one significant global challenge of developing green processes for producing high value chemicals from biomass, to enhance the environmental performance and cost-efficiency of bio-refining. This project aims to develop a new class of heterogeneous nanocatalysts with hydrophilic Co (salen) complexes for biomass oxidation in water rather than toxic solvent. This project will use this to devise practical routes for the production of targeted industrial components for flavours, fragrances, fine chemicals, and petrochemicals. The development of heterogeneous hydrophilic catalysts by which they will oxidise hydrophilic biomasses in a continuous flow system will dramatically improve the sustainability of the chemical industry.Read moreRead less
A novel route to produce olefin feedstock for Australia. This project aims to develop a new process to produce longer chain hydrocarbons usable in Australia's olefin and polymer industries. Besides their use as a fuel, hydrocarbons are major industrial chemicals used for the production of polymeric materials and as refrigerants. Olefins are precursors to polymers and conventionally are produced from saturated hydrocarbons through the process of steam cracking. The major precursors for monomers a ....A novel route to produce olefin feedstock for Australia. This project aims to develop a new process to produce longer chain hydrocarbons usable in Australia's olefin and polymer industries. Besides their use as a fuel, hydrocarbons are major industrial chemicals used for the production of polymeric materials and as refrigerants. Olefins are precursors to polymers and conventionally are produced from saturated hydrocarbons through the process of steam cracking. The major precursors for monomers are present in significant quantities in only a few natural gas sources and these sources also undergo significant seasonal variation and are costly. The project aims to develop new catalysts and process conditions to convert low-value feedstock hydrocarbons into feedstock for conventional steam crackers.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120100329
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Photocatalytic reduction of carbon dioxide with water into hydrocarbon fuels and chemicals. This project aims to develop a highly efficient photocatalytic process for converting CO2 into hydrocarbon fuels and high value-added chemicals. This new technology can reduce CO2 concentrations in the environment and provide a feasible mean to produce non-fossil fuels and industrial chemicals that society has to depend upon.