Functional mesostructured materials in ionic liquids. Polymers, surfactants and nanoparticles are the building blocks from which smart soft matter is assembled. This project will replace conventional molecular solvents with ionic liquids, allowing us to precisely control molecular assembly through intermolecular forces and facilitate the production of new functional soft materials.
A new explanation for the hydrophobic effect. The hydrophobic effect is a fundamental natural phenomenon: why do oil and water spontaneously separate and not mix? The project team proposes a new and novel explanation for this effect, based on known properties of water. The project team's theory explains hydrophobic effects in physics, chemistry and biology.
Breaking emulsions. Droplet coalescence is the key to breaking emulsions, that is, separating oil from water. This process underpins the recovery of crude oil and the remediation of industrial and environmental waste-waters. Through a unique and novel experimental program that simultaneously tracks drop trajectories up to the millimetre scale and drop deformations in the nanometre scale, this project aims to fill a fundamental gap in our understanding of such coalescence events. A complete theor ....Breaking emulsions. Droplet coalescence is the key to breaking emulsions, that is, separating oil from water. This process underpins the recovery of crude oil and the remediation of industrial and environmental waste-waters. Through a unique and novel experimental program that simultaneously tracks drop trajectories up to the millimetre scale and drop deformations in the nanometre scale, this project aims to fill a fundamental gap in our understanding of such coalescence events. A complete theoretical model of coalescence will result, forming a predictive framework for separating emulsions to recover pure oil and water, and laying the foundation for using compound drops to tune the optical properties of surface for speciality applications.Read moreRead less
Theoretical foundations of dynamic surface forces. Australian scientists are current world leaders in developing novel materials for biomedical and industrial applications. This project will create the key theoretical framework to interpret experimental measurements and will be vital in ensuring that our scientific endeavour in novel materials maintains its current world leadership position.
Algorithms for multi-scale problems in science and engineering. This project aims to develop theoretical formulations and algorithms for modelling fundamental problems in molecular electrostatics, dispersion force theory, acoustics and electromagnetic scattering in applications where current approaches may be useless. Many engineering applications, from microelectronics to bioengineering devices, need to operate across dimensions from a few millimetres down to a million times smaller. This large ....Algorithms for multi-scale problems in science and engineering. This project aims to develop theoretical formulations and algorithms for modelling fundamental problems in molecular electrostatics, dispersion force theory, acoustics and electromagnetic scattering in applications where current approaches may be useless. Many engineering applications, from microelectronics to bioengineering devices, need to operate across dimensions from a few millimetres down to a million times smaller. This large range of length scales means traditional modelling tools and computational techniques will rapidly become intractable. This project will meet this need to strengthen the Australian technological skill base and contribute to innovations in areas ranging from bioengineering to nanotechnology.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100090
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important ....Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important systems. As such this facility will underpin the research of a number of groups across three institutions over the next decade and promote collaboration between scientists with a range of complementary expertise in fields where surface science is important from biology to ionic liquids.Read moreRead less
Green working liquids for an energy efficient future. Ionic liquids (ILs) have enormous potential as advanced materials due to their unusual properties. This project will develop ILs for use as energy efficient lubricants, electrochemical solvents and heat transfer fluids. These technologies will decrease Australia's energy consumption, reduce carbon dioxide emissions, and stimulate economic growth.
Molecular scale engineering of solid/ionic liquid interfaces. Ionic liquids have enormous potential as advanced materials due to their unusual properties. This project will develop ways to use ionic liquids as lubricants, in electrochemical devices like capacitors, and in the electro-refining of metals. The technologies developed will decrease Australia's energy consumption and stimulate economic growth.
Hofmeister at work. Implementation of a paradigm shift in physical chemistry. Standard tools of measurement in environmental, industrial, colloid, nano and biosciences rest on classical theories which have been shown to be badly flawed. The faults have been remedied to give a new, predictive and usable foundation that amounts to a paradigm shift of immediate importance to many applications.
Modelling of soft multi-scale systems. This project develops realistic physical models and efficient computational methods as the platform technology for giving highly accurate predictions of the complex behaviour of soft deformable systems. The outcomes will add to our understanding of the mechano-biology of living cells and artificial soft body tissues, the cellular uptake of nutrients and drugs, the energy-efficient processing of high value pharmaceutical emulsions and the design of functiona ....Modelling of soft multi-scale systems. This project develops realistic physical models and efficient computational methods as the platform technology for giving highly accurate predictions of the complex behaviour of soft deformable systems. The outcomes will add to our understanding of the mechano-biology of living cells and artificial soft body tissues, the cellular uptake of nutrients and drugs, the energy-efficient processing of high value pharmaceutical emulsions and the design of functional polymers and proteins using molecular models. The new knowledge will advance the frontier of material design and characterisation of soft complex materials.Read moreRead less