Specific-ion effects in non-aqueous solvents. A test for Hofmeister. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of a ....Specific-ion effects in non-aqueous solvents. A test for Hofmeister. A colloidal solution is a liquid that contains a finely dispersed material. The properties of these solutions are critical in many industrially important practices and in the everyday processes of life. Though not understood, it is observed that the type of salt in solution controls how the colloid behaves. Through a series of very careful experiments we seek to learn precisely how different salts influence the properties of a colloidal solution. This world-leading research will enable us to improve our fundamental understanding of colloids and thereby facilitate advances in topics as diverse as enzymatic action and minerals purification, ensuring Australia remains at the forefront of science in this field.Read moreRead less
Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for re ....Maximizing solid state Nuclear Magnetic Resonance (NMR) with maximum entropy. Nuclear magnetic resonance is an essential technology for the characterisation of important industrial and biomedical molecules, molecular chains and complexes. This project aims to considerably expand the fundamental capability of experimental techniques for the study of materials in the solid state, in particular for a new class of biological nanoparticle. These advances will have important global implications for research into life-saving therapeutic strategies aimed at many pharmaceutical targets embedded in cell membranes, protein misfolding disorders such as Alzheimer's disease and Huntington's disease, as well as development of the next generation of "green" plastics and other advanced polymers.Read moreRead less
Southern Ocean productivity and carbon dioxide (CO2) exchange under current and future climate regimes. This project will contribute to Australian ocean science expertise in key areas of data synthesis, satellite oceanography and the understanding of marine ecosystems' response to climate change. Collaborations will be developed and strengthened among Australian research institutions, and between Australia and the United States. The focus of the research is the Southern Ocean, which impacts glob ....Southern Ocean productivity and carbon dioxide (CO2) exchange under current and future climate regimes. This project will contribute to Australian ocean science expertise in key areas of data synthesis, satellite oceanography and the understanding of marine ecosystems' response to climate change. Collaborations will be developed and strengthened among Australian research institutions, and between Australia and the United States. The focus of the research is the Southern Ocean, which impacts global climate, and on which Australia's southern coastal ecosystems depend. The expertise and techniques developed will have application to other Australian regional seas.Read moreRead less
Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into diseas ....Room-temperature quantum microscopy for advanced nanoscale imaging. Original, inspired and most often cross-disciplinary efforts are the only way to solve some of nature's most obscure mysteries. Successful development of high-resolution quantum microscopy will lead to a range of benefits for the community and the nation; from graduate student training in cutting edge technology, building links between academic, industry and government groups to providing new insights and approaches into disease identification and therapy. This project aims to demonstrate a world-first in imaging sensitivity, and success will directly enhance Australia's global reputation as a leader in innovation and collaboration. Read moreRead less
The Quest for Ultimate Measurement Precision. Precision measurement is the foundation upon which modern technological society is built. The highest quality measurement devices rely on stable clocks for their operation. The group's existing research has been aimed at developing some of the world's most precise measurement tools based on clocks and lasers. In parallel with this, other scientists have developed the means for exquisite control of light on the microscopic scale. By combining these tw ....The Quest for Ultimate Measurement Precision. Precision measurement is the foundation upon which modern technological society is built. The highest quality measurement devices rely on stable clocks for their operation. The group's existing research has been aimed at developing some of the world's most precise measurement tools based on clocks and lasers. In parallel with this, other scientists have developed the means for exquisite control of light on the microscopic scale. By combining these two technologies, both of which lie at the extreme limit of precision, the group will develop a new generation of technology for fundamental science objectives as well as for industrial needs.Read moreRead less
Bulk nanobubbles: from fundamentals to biomedical applications. This project aims to extend optical and acoustic tools to detect bulk nanobubbles, control their size-distributions, and understand how they interact with biomolecules. Liquids containing nanobubbles have numerous applications particularly in biomedicine. Using interdisciplinary approaches, this project expects to gain convincing evidence of the existence of bulk nanobubbles. This is expected to advance existing fundamental knowle ....Bulk nanobubbles: from fundamentals to biomedical applications. This project aims to extend optical and acoustic tools to detect bulk nanobubbles, control their size-distributions, and understand how they interact with biomolecules. Liquids containing nanobubbles have numerous applications particularly in biomedicine. Using interdisciplinary approaches, this project expects to gain convincing evidence of the existence of bulk nanobubbles. This is expected to advance existing fundamental knowledge at the forefront of soft matter research, and give Australia a decisive technological head start in a competitive and lucrative industry through patentable technology.Read moreRead less
Unravelling how liquids wet surfaces with new dynamic measurements. This project aims to transform our understanding of how liquids wet surfaces in order to provide a step-change in advanced material design. This will be achieved by developing a unifying theory of surface wetting by integrating new microscale models of dynamic wetting with new macroscale automated measurement techniques capable of rapidly generating large datasets, to determine precisely how surface chemistry and surface roughne ....Unravelling how liquids wet surfaces with new dynamic measurements. This project aims to transform our understanding of how liquids wet surfaces in order to provide a step-change in advanced material design. This will be achieved by developing a unifying theory of surface wetting by integrating new microscale models of dynamic wetting with new macroscale automated measurement techniques capable of rapidly generating large datasets, to determine precisely how surface chemistry and surface roughness influence wetting. Expected outcomes include predictive models of surface wetting across multiple scales, and robust high-throughput measurement methods informing optimal design of next-generation materials for all applications where liquids and surfaces interact.Read moreRead less
Nonlinear and tunable topological states of light and sound. This project aims to provide deep theoretical insights into the physics of electromagnetic and mechanical topological states by bridging fundamental concepts of optics, optomechanics and nonlinear physics. The rapidly expanding digital world calls for a new generation of photonic devices to transmit and process information without losses. Recently discovered topological phases open unique opportunities to realise topological states of ....Nonlinear and tunable topological states of light and sound. This project aims to provide deep theoretical insights into the physics of electromagnetic and mechanical topological states by bridging fundamental concepts of optics, optomechanics and nonlinear physics. The rapidly expanding digital world calls for a new generation of photonic devices to transmit and process information without losses. Recently discovered topological phases open unique opportunities to realise topological states of light that are inherently immune to scattering losses. This multidisciplinary project aims to bridge fundamental topological physics with nonlinear nanophotonics and optomechanics by developing novel concepts of topological systems, dynamically tunable by nonlinearity. An expected outcome of this project is new approaches to control both light and sound dynamically in complex nanoscale structures, and uncover disorder-immune technologies for applications in on-chip communications and information processing.Read moreRead less
Dynamic multi-modal x-ray imaging. This project aims to create sensitive new methods of x-ray imaging that capture multiple image modalities with a single snapshot. Conventional x-ray imaging is widely used in a range of industries, but captures only a fraction of the rich information that is available in the x-ray wavefield. This project expects to extract additional image modalities to reveal x-ray-transparent features, and detect microscopic textures. By combining these capabilities with the ....Dynamic multi-modal x-ray imaging. This project aims to create sensitive new methods of x-ray imaging that capture multiple image modalities with a single snapshot. Conventional x-ray imaging is widely used in a range of industries, but captures only a fraction of the rich information that is available in the x-ray wavefield. This project expects to extract additional image modalities to reveal x-ray-transparent features, and detect microscopic textures. By combining these capabilities with the ability to capture images of a moving sample, this project will enable innovative biomedical and materials research studies, and develop new imaging technologies for use in security, hospitals and manufacturing. New methods of x-ray imaging will have wide-ranging benefits for society, the economy and healthcare.Read moreRead less
Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and ....Plasmonic nanoparticle catalysis for nitrogen-based synthesis. Light can generate an optical force to capture small objects. This requires intense light – a laser, which limits optical trapping in catalysis applications. This project aims to apply plasmonic nanoparticles with normal-intensity light to take advantage of plasmonic-generated optical forces for catalytic chemical synthesis. The optical trapping/releasing of small molecules is highly selective and responsive to molecule structure and so presents a great opportunity to radically alter chemical synthesis pathways, which will be illustrated with reactions on liquid-solid and gas-solid interfaces. This highly innovative strategy will be used to discover new nitrogen-based syntheses which are both fundamentally and industrially important.Read moreRead less