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
Particle motion and particle-convective heat transfer near the walls of fluidized beds. Background: Fluidized bed technology has important industrial applications ranging from petrol production to mineral processing for metal production. Such processes take advantage of the high rates of heat transfer in gas-fluidized beds.
Objective of project: To improve understanding and modelling of heat transfer in gas fluidized beds through the application of state-of-the-art experimental (Positron Emiss ....Particle motion and particle-convective heat transfer near the walls of fluidized beds. Background: Fluidized bed technology has important industrial applications ranging from petrol production to mineral processing for metal production. Such processes take advantage of the high rates of heat transfer in gas-fluidized beds.
Objective of project: To improve understanding and modelling of heat transfer in gas fluidized beds through the application of state-of-the-art experimental (Positron Emission Particle Tracking) and modelling (Discrete Element Method simulation) techniques.
Expected outcomes of project: New knowledge of the mechanisms of fluidized bed heat transfer. Improved the prediction of heat transfer coefficients with consequent improvements in the design and operation of fluidized bed processes.
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Advanced chemical recycling of mixed plastics for monomer recovery. This project aims to develop innovative catalytic routes to the chemical recycling of mixed plastics for recovery of their molecular building blocks. Plastic pollution poses a significant threat to the Australian ecosystem. Efficient recycling technologies are urgently needed as Australia only recycles ~4% of its 3.4 million tons of mixed waste plastics. This project expects to design highly efficient catalysts for the stepwise ....Advanced chemical recycling of mixed plastics for monomer recovery. This project aims to develop innovative catalytic routes to the chemical recycling of mixed plastics for recovery of their molecular building blocks. Plastic pollution poses a significant threat to the Australian ecosystem. Efficient recycling technologies are urgently needed as Australia only recycles ~4% of its 3.4 million tons of mixed waste plastics. This project expects to design highly efficient catalysts for the stepwise breakdown of mixed polyolefin plastics into monomers for the subsequent manufacturing of virgin plastics in a circular economy, and to elucidate fundamental underpinning reaction mechanisms. Outcomes will stimulate the Australian waste plastic recycling industry, and minimise plastic accumulation in the environment.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100135
Funder
Australian Research Council
Funding Amount
$438,400.00
Summary
Superhydrophobic thermally rearranged membranes for low-energy separation. This project aims to develop thermally rearranged membranes with superhydrophobicity using novel polymer chemistry and nanofibre morphology. Both water flowrate in membrane distillation and gas flowrate in carbon dioxide stripping from solvents will be increased by minimising the water vapor condensation between the nanofibers; resolving shortcomings in current energy-intensive filtration systems. This project will provid ....Superhydrophobic thermally rearranged membranes for low-energy separation. This project aims to develop thermally rearranged membranes with superhydrophobicity using novel polymer chemistry and nanofibre morphology. Both water flowrate in membrane distillation and gas flowrate in carbon dioxide stripping from solvents will be increased by minimising the water vapor condensation between the nanofibers; resolving shortcomings in current energy-intensive filtration systems. This project will provide significant benefits to Australian communities by advancing cost-effective and energy-efficient potable water production and carbon dioxide separation processes for sustainable development. The advanced materials developed can be manufactured locally and will enhance our national capability in modern manufacturing.Read moreRead less