Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cuttin ....Sustainable surfactants from Australian oilseeds. This project aims to develop a new generation of sustainable surfactants utilising Australian-grown oilseed feedstocks. These molecules are designed to replace current materials made from petroleum and palm oil, to fulfil a key role as the next generation of bio-resourced detergents and emulsifiers. The work seek to develop a library of new molecules to better understand the relationship between molecular structure and performance, through cutting edge lab testing and utilising national infrastructure, guiding the use of new components in formulating new products. It is anticipated that the surfactants generated will find uses in household cleaning and personal care products, providing high value chemicals from key Australian crops.Read moreRead less
Nanoscale Dynamics and Structure of SAILs at Electrodes. This project will produce new, high performance, surface active ionic liquids. Surface active ionic liquids are pure salts in which one of the ions is based on a surfactant molecule. Surface active ionic liquids are much more effective than conventional electrolytes for some applications, but only at elevated temperature; at low temperature, ion dynamics are too slow. We will use cutting edge techniques to probe ion dynamics in surface act ....Nanoscale Dynamics and Structure of SAILs at Electrodes. This project will produce new, high performance, surface active ionic liquids. Surface active ionic liquids are pure salts in which one of the ions is based on a surfactant molecule. Surface active ionic liquids are much more effective than conventional electrolytes for some applications, but only at elevated temperature; at low temperature, ion dynamics are too slow. We will use cutting edge techniques to probe ion dynamics in surface active ionic liquids in the bulk and at electrode surfaces, and use this to elucidate rules for the rational design of new surface active ionic liquids with fast dynamics at low temperature, towards their use at room temperature in diverse areas; this project will target capacitors and gas sensors. Read moreRead less
Special Research Initiatives - Grant ID: SR180100016
Funder
Australian Research Council
Funding Amount
$880,187.00
Summary
A skid-based transportable plant for PFAS contaminated site remediation. This project aims to develop a self contained skid-based transportable process for onsite destruction of per- and poly-fluroalkyl substances (PFAS) toxins at contaminated sites. The new technologies developed will span a range of application areas, although remediation of sites contaminated with PFAS by ongoing or legacy use of fire-fighting foams is a key target for this project. The process is expected to enable remediati ....A skid-based transportable plant for PFAS contaminated site remediation. This project aims to develop a self contained skid-based transportable process for onsite destruction of per- and poly-fluroalkyl substances (PFAS) toxins at contaminated sites. The new technologies developed will span a range of application areas, although remediation of sites contaminated with PFAS by ongoing or legacy use of fire-fighting foams is a key target for this project. The process is expected to enable remediation of these sites by completely converting all toxins into safe products such as carbon dioxide and harmless salts. This project will deliver significant benefits, as the process is easily scalable and is intended to form the basis of a new or expanded remediation industry in Australia, resulting in manufacturing growth, job opportunities and significant impacts in terms of environmental safety and quality.Read moreRead less
Special Research Initiatives - Grant ID: SR180200046
Funder
Australian Research Council
Funding Amount
$758,233.00
Summary
Plasma Bubble Column for one step remediation of PFAS. This project aims to develop a new class of plasma water treatment reactors by combining the effectiveness of atmospheric air plasma with the effective mixing of bubble columns. Non-thermal plasmas have been demonstrated to degrade PFAS at the laboratory scale, but key questions remain on the mechanisms of action and process scaling. This project brings together expertise on plasma engineering, bubble column reactors, modelling and industria ....Plasma Bubble Column for one step remediation of PFAS. This project aims to develop a new class of plasma water treatment reactors by combining the effectiveness of atmospheric air plasma with the effective mixing of bubble columns. Non-thermal plasmas have been demonstrated to degrade PFAS at the laboratory scale, but key questions remain on the mechanisms of action and process scaling. This project brings together expertise on plasma engineering, bubble column reactors, modelling and industrial scaling to address these issues. The expected outcomes of this project are the development and demonstration of a modular, re-deployable plasma bubble column reactor for the one step destruction of PFAS. The benefits of this project are a new low cost method to remediate PFAS contamination.Read moreRead less
Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential ap ....Gas-enriched slippery surfaces. This project will exploit novel experimental and simulations approaches to investigate gas enrichment at liquid-liquid interfaces, and its effect on interfacial slip. The outcomes of the project will be a deeper understanding of oil-water interfaces capturing the presence of interfacial gas layers, slippery surfaces with superior drag reducing and fouling reducing properties, and control over nanobubble formation under flow. The new surfaces will have potential application in improving the energy efficiency of microfluidic and multiphase flow. Benefits are expected in terms of reduced emissions, fuel cost and pollution related to transport of goods by sea, and extraction of oil from rocks.Read moreRead less
On-water electrochemistry: redox catalysis at the water surface. From plastics to pharamaceuticals, chemists rely extensively on expensive and environmentally damaging solvents and reactants. In water, greener and cheaper electricity-driven reactions currently suffer from low velocity and poor selectivity. The project aims to develop the science of on-water electrochemistry, to make electricity-driven organic reactions in water viable. Demonstrating that for electrochemical reactions, rates and ....On-water electrochemistry: redox catalysis at the water surface. From plastics to pharamaceuticals, chemists rely extensively on expensive and environmentally damaging solvents and reactants. In water, greener and cheaper electricity-driven reactions currently suffer from low velocity and poor selectivity. The project aims to develop the science of on-water electrochemistry, to make electricity-driven organic reactions in water viable. Demonstrating that for electrochemical reactions, rates and selectivities increase on water’s surface rather than in its bulk will remove fundamental constraints on the viability of aqueous electro-synthesis – moving beyond current reactor designs to transform our view of electrochemistry and improve the sustainability of the chemical industry.Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100245
Funder
Australian Research Council
Funding Amount
$460,237.00
Summary
Transforming wastewater services in regional Australia. Wastewater treatment in regional Australia faces challenges of odour control, poor pollutant and pathogen removal, and greenhouse gas emissions. This project aims to innovatively use iron salts to realise highly efficient wastewater treatment in regional areas. With Partner, Western Australia Water Corporation, this project expects to leverage a recent breakthrough discovery on iron chemistry to co-develop and field test a solar system that ....Transforming wastewater services in regional Australia. Wastewater treatment in regional Australia faces challenges of odour control, poor pollutant and pathogen removal, and greenhouse gas emissions. This project aims to innovatively use iron salts to realise highly efficient wastewater treatment in regional areas. With Partner, Western Australia Water Corporation, this project expects to leverage a recent breakthrough discovery on iron chemistry to co-develop and field test a solar system that doses wastewater with iron, to overcome four challenges and a supply chain issue simultaneously. Expected outcomes include industry capacity to adopt and commercialise a novel technology with important global relevance. Outcomes should reduce the inequity of wastewater services in regional Australia.Read moreRead less
Atomic-Scale Engineering of Bioactive Organic Molecules on Surfaces. Advances in scanning probe microscopy (SPM) have enabled the precise engineering of matter at surfaces. The ability to image and track changes at surfaces is simply staggering, but the frontier of molecules with pharmaceutical and agrichemical importance remains unexplored. This interdisciplinary project aims to synthesise fundamental molecules and reveal molecular rearrangement pathways utilising SPM. Expected outcomes of this ....Atomic-Scale Engineering of Bioactive Organic Molecules on Surfaces. Advances in scanning probe microscopy (SPM) have enabled the precise engineering of matter at surfaces. The ability to image and track changes at surfaces is simply staggering, but the frontier of molecules with pharmaceutical and agrichemical importance remains unexplored. This interdisciplinary project aims to synthesise fundamental molecules and reveal molecular rearrangement pathways utilising SPM. Expected outcomes of this project include new methods to couple molecules otherwise unobtainable by traditional means and fundamental knowledge of molecular manipulation and chemical structure. This aims to provide significant benefits, such as the translation of new chemical principles to academic and industrial laboratories.Read moreRead less
Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, ....Biomimetic surface coatings for drag and fouling reduction. This project aims to provide new insights into liquid flow and adsorption at liquid/solid and liquid/liquid interfaces, by using a combination of theoretical predictions, nanoscale techniques and nanofabrication approaches. Expected outcomes are the development of liquid-repellent slippery surface coatings that reduce hydrodynamic drag and inhibit marine fouling. This will benefit the fields of advanced manufacturing and smart coatings, and will underpin a wide range of energy efficient processes and products. Slippery coatings will solve urgent environmental problems of social value by improving the energy and chemical efficiency in fluid flow, heat transfer, secondary oil recovery, microfluidics, and anti-fouling.Read moreRead less
Deciphering lipid-RNA nanocarrier structure upon RNA complexation. This project aims to decipher the nanostructure evolution, at a millisecond timescale, of lipid self-assembly upon coupling with RNAs and track the nanocarrier structural changes induced by biologically relevant acidic environments. This project will generate new knowledge of the interplay between the self-assembled lipid-RNA nanostructures and cellular objects for successful payload release. The expected outcome of this project ....Deciphering lipid-RNA nanocarrier structure upon RNA complexation. This project aims to decipher the nanostructure evolution, at a millisecond timescale, of lipid self-assembly upon coupling with RNAs and track the nanocarrier structural changes induced by biologically relevant acidic environments. This project will generate new knowledge of the interplay between the self-assembled lipid-RNA nanostructures and cellular objects for successful payload release. The expected outcome of this project is identification of the fundamental mechanisms of lipid-RNA molecular self-assembly and intracellular nucleic acid delivery. This should provide significant advances in the field of lipid nanoparticle engineering for the delivery of RNA therapeutics. Read moreRead less