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
Cementitious gel: the missing link in understanding the ageing of built infrastructure. Exposure of built reinforced concrete infrastructure to coastal environments causes premature ageing, unplanned remediation and reduced safety. Enhanced forecasting, achieved by advanced methods, including Helium Ion Microscopy and modeling interactions between cement gel, chloride and water, will deliver proactive management of ageing assets.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100009
Funder
Australian Research Council
Funding Amount
$1,064,000.00
Summary
Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications. Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications: Ultra-high field magnetic resonance imaging provides unique high contrast images at previously inaccessible levels of resolution (<0.1mm). It non-invasively provides unprecedented information on chemical and biochemical processes including functional biological mechanisms. This infrastructure will be the focal point for ....Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications. Ultra-high resolution magnetic resonance imaging (MRI) system for physical applications: Ultra-high field magnetic resonance imaging provides unique high contrast images at previously inaccessible levels of resolution (<0.1mm). It non-invasively provides unprecedented information on chemical and biochemical processes including functional biological mechanisms. This infrastructure will be the focal point for more than 100 academics and HDR students. It will take Australia to the forefront of magnetic resonance imaging capability as well as providing unique insights into diffusion and electrophoretic problems central to designing next generation energy storage. Outcomes will range from agricultural advances, higher performing batteries, and more effective cancer treatments as well advancing Australia's fundamental scientific capabilities.Read moreRead less
Designer solvents to control reaction outcome. This project aims to control outcomes of chemical reactions using specifically designed ionic liquids as solvents. Ionic liquids are distinct from molecular solvents and are underused due to the limited understanding of their effects on chemical processes. We are developing a predictive framework to explain such effects and this project aims to exploit this new knowledge, using both new and rarely applied ionic liquids to control reaction outcomes. ....Designer solvents to control reaction outcome. This project aims to control outcomes of chemical reactions using specifically designed ionic liquids as solvents. Ionic liquids are distinct from molecular solvents and are underused due to the limited understanding of their effects on chemical processes. We are developing a predictive framework to explain such effects and this project aims to exploit this new knowledge, using both new and rarely applied ionic liquids to control reaction outcomes. The significance lies in the ability to optimise reaction outcomes without the need for solvent screening. The innovation lies in the measurement of microscopic interactions between solvent and reagents, and the use of these interactions to affect a given process.Read moreRead less
Will geopolymer concretes stand the test of time? In developing new 'green' materials to replace traditional, high-carbon dioxide cements and concretes, it is essential to show that the new materials will be at least as durable as the traditional options. This project will enable prediction of the durability of low-carbon dioxide geopolymer concrete, using laboratory tests, cutting-edge structural analysis and computations.
Discovery Early Career Researcher Award - Grant ID: DE130100970
Funder
Australian Research Council
Funding Amount
$370,600.00
Summary
Solar energy conversion: illuminating the origin of long-lived charge-separated states in organic donor/acceptor blends. The origin of exceptionally long-lived charges in organic donor/acceptor solid-state blends will be established. This will substantially enhance the efficiency and commercial viability of applications that rely on these long-lived charge-separated states, such as organic solar cells.
Discovery Early Career Researcher Award - Grant ID: DE140100433
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Optimising light harvesting using quantum transport. Observations of wavelike energy transport in photosynthetic systems have exposed the role of quantum mechanics in natural light harvesting. This project is a study of how light harvesting functions for an incoherent source like sunlight. In sunlight, energy transport occurs at steady state, a dramatically simpler regime than when a coherent source like lasers are used. This project will exploit this simplification to develop new methods for tr ....Optimising light harvesting using quantum transport. Observations of wavelike energy transport in photosynthetic systems have exposed the role of quantum mechanics in natural light harvesting. This project is a study of how light harvesting functions for an incoherent source like sunlight. In sunlight, energy transport occurs at steady state, a dramatically simpler regime than when a coherent source like lasers are used. This project will exploit this simplification to develop new methods for treating light harvesting in sunlight and apply them to a variety of natural and artificial systems. It will clarify how bacteria and plants harvest sunlight and lead to design principles that will enable artificial light harvesting to take advantage of quantum effects.Read moreRead less
Accurate transport theory for nanofluidic separation science. The project will develop and test new methods to predict the distribution of different components of a complex solution flowing through a nanoporous medium. This will lead to new insights into ways of separating or concentrating the components, with applications ranging from lab on a chip devices to desalination.
Predicting concentration-gradient-driven liquid transport in 2D membranes. This project aims to achieve a predictive understanding of liquid transport through two-dimensional (2D) membranes driven by concentration gradients by using a combination of novel theory and computation. Membranes made from 2D nanomaterials hold great promise for many applications from desalination to power generation to chemical sensing, but the concentration-gradient-driven transport processes that underlie these appli ....Predicting concentration-gradient-driven liquid transport in 2D membranes. This project aims to achieve a predictive understanding of liquid transport through two-dimensional (2D) membranes driven by concentration gradients by using a combination of novel theory and computation. Membranes made from 2D nanomaterials hold great promise for many applications from desalination to power generation to chemical sensing, but the concentration-gradient-driven transport processes that underlie these applications are not well understood. The expected outcome of this project is an unprecedented quantitative understanding of the parameters that control these transport processes. This will enable predictive optimisation of 2D membranes, which will reduce the time and cost of membrane development for diverse applications.
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Design of adsorbents for kinetic separation of gases. The purpose of this project is to design, synthesise and test a new family of adsorbents for separation of gas mixtures of environmental and energy significance. The outcome will be a thorough understanding of diffusion in adsorbents and preparation of several candidate adsorbents with superior separation characteristics.