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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
Next generation supramolecular frameworks. This project aims to prepare new supramolecular frameworks assembled by hydrogen or halogen bonds. It is anticipated that this work will increase fundamental understanding of supramolecular self-assembly processes and the dynamic processes that are possible within these rearrangeable systems. The project aims to prepare a family of related frameworks, which will allow a detailed comparison of the stability, porosity and biotechnological applicability of ....Next generation supramolecular frameworks. This project aims to prepare new supramolecular frameworks assembled by hydrogen or halogen bonds. It is anticipated that this work will increase fundamental understanding of supramolecular self-assembly processes and the dynamic processes that are possible within these rearrangeable systems. The project aims to prepare a family of related frameworks, which will allow a detailed comparison of the stability, porosity and biotechnological applicability of new supramolecular materials. The expected outcomes are the development of lightweight and benign organic systems that will have applications in the removal of toxic organic and heavy metal pollutants from water, and in the encapsulation and stabilisation of catalytically-active enzymes.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
The charXive challenge and the clean coal quest: thermokinetic principles and methods for capturing and sequestering carbon dioxide. Article 6 of the Kyoto Protocol, which Australia signed in 2007, states that a transfer of carbon credits may only take place if the associated activity provides a reduction in emissions by sources or an enhancement of removals by sinks that is additional to any that would otherwise occur. Since biochar production reduces emissions from biomass decay and transfers ....The charXive challenge and the clean coal quest: thermokinetic principles and methods for capturing and sequestering carbon dioxide. Article 6 of the Kyoto Protocol, which Australia signed in 2007, states that a transfer of carbon credits may only take place if the associated activity provides a reduction in emissions by sources or an enhancement of removals by sinks that is additional to any that would otherwise occur. Since biochar production reduces emissions from biomass decay and transfers oxidized carbon from the atmosphere to the inactive black carbon pool this project will contribute to the national effort in additional greenhouse gas abatements. The Australian Government is also committed to clean coal technologies, which are expensive. An economically viable method of capturing carbon emissions from electricity generators will result from this project.Read moreRead less
Plasmonic Photochemistry: A nanoscopic solution to global energy and environmental problems. Harvesting energy from light sources, including our sun, can provide a significant fraction of the world's energy need over the next century. In order to meet this critical demand, it is crucial to devise ways to transform light energy into chemical fuels. This project aims to create novel nanostructures that directly couple light energy into chemical reactions. This will be achieved by the creation of ....Plasmonic Photochemistry: A nanoscopic solution to global energy and environmental problems. Harvesting energy from light sources, including our sun, can provide a significant fraction of the world's energy need over the next century. In order to meet this critical demand, it is crucial to devise ways to transform light energy into chemical fuels. This project aims to create novel nanostructures that directly couple light energy into chemical reactions. This will be achieved by the creation of metallic nanoparticles that can transform light energy into hot electrons: entities that can efficiently drive the production of chemical fuels in a process similar to that of photosynthesis.Read moreRead less
Developing an Essential Research Platform for the Molecular Engineering of Photosystem II. Sunlight reaching the earth is used by plants and algae to drive photosynthesis and to store chemical energy. Possibly the most fundamental contribution photosynthesis makes to earth is to generate gaseous oxygen, the result of solar driven water-splitting chemistry. However, the mechanism behind water-splitting is not exactly known. In this proposal we will construct a new model cyanobacteria host to stu ....Developing an Essential Research Platform for the Molecular Engineering of Photosystem II. Sunlight reaching the earth is used by plants and algae to drive photosynthesis and to store chemical energy. Possibly the most fundamental contribution photosynthesis makes to earth is to generate gaseous oxygen, the result of solar driven water-splitting chemistry. However, the mechanism behind water-splitting is not exactly known. In this proposal we will construct a new model cyanobacteria host to study water splitting. The host organism will be genetically modified to enable mechanistic questions of water oxidation to be tested and will provide new and pure forms of isolated protein. This model organism will provide team of international researchers with a remarkable tool new to study photosynthesis.Read moreRead less
Designing reactivity of homogeneous and heterogeneous water-splitting catalysts using muti-dimensional site-selective spectroscopies. New classes of heterogeneous manganese-calcium water splitting catalysts analogous to the unique biological water splitting cofactor have recently emerged but with far lower catalytic rates than seen for the biological system. These new materials are promising targets for large-scale hydrogen fuel production with low cost, high efficiency and ease of manufacture. ....Designing reactivity of homogeneous and heterogeneous water-splitting catalysts using muti-dimensional site-selective spectroscopies. New classes of heterogeneous manganese-calcium water splitting catalysts analogous to the unique biological water splitting cofactor have recently emerged but with far lower catalytic rates than seen for the biological system. These new materials are promising targets for large-scale hydrogen fuel production with low cost, high efficiency and ease of manufacture. To achieve this, the performance gap between these materials and the homogenous biological catalyst must be bridged. Multi-dimensional site-selective spectroscopies, including magneto/optical resonance methods which are aimed to be developed in this project are expected to provide new, atomic level understanding of properties needed to achieve high catalytic efficiency, thus guiding rational catalyst design.Read moreRead less
Porous Electromaterials for Hydrogen Production and Energy Storage. This project aims to develop nanocomposite electrodes and membranes for efficient production of renewable hydrogen and the next generation of high-energy-density battery technologies. This will be accomplished by the engineering of multi-scale porous materials with tuneable electrical, chemical and morphological properties using earth abundant elements. The intended outcome is the establishment of a scalable methodology for the ....Porous Electromaterials for Hydrogen Production and Energy Storage. This project aims to develop nanocomposite electrodes and membranes for efficient production of renewable hydrogen and the next generation of high-energy-density battery technologies. This will be accomplished by the engineering of multi-scale porous materials with tuneable electrical, chemical and morphological properties using earth abundant elements. The intended outcome is the establishment of a scalable methodology for the structuring and effective integration of microporous materials in highly conductive scaffolds, achieving superior charge and molecular transport, as well as high surface activity. Broad social and economic benefits are anticipated providing new technological solutions for renewable energy storage and fuel production.Read moreRead less
Complementary pairs for next generation self-assembled systems . This project will employ a set of complementary pairings where separate sites fit together at metal ions in a specific fashion orthogonal to other pairings, like two jigsaw pieces, while forming a poor fit with other pairings. These pairings will allow retention and transfer of structural information. In this way, the bulk combination of relatively simple precursors will lead to self-assembled structures with well-defined seque ....Complementary pairs for next generation self-assembled systems . This project will employ a set of complementary pairings where separate sites fit together at metal ions in a specific fashion orthogonal to other pairings, like two jigsaw pieces, while forming a poor fit with other pairings. These pairings will allow retention and transfer of structural information. In this way, the bulk combination of relatively simple precursors will lead to self-assembled structures with well-defined sequence identity. This program will make and use complex abiotic molecules, enhancing outcomes in molecular information storage and transfer, molecular recognition and sensing, chemical transformations, and energy transport events, leading to economic and environmental benefits for Australia in industry and manufacturing.Read moreRead less
Engineered materials for future energy technologies. The development of new technologies to be applied in fuel generation, energy conversion and environmental remediation will have wide national and international impact. The cross-disciplinary and cross-institution research program proposed will draw on expertise within Australia and in Europe for the fabrication of materials for next generation energy devices. In the future, there is the potential that these materials could be fabricated within ....Engineered materials for future energy technologies. The development of new technologies to be applied in fuel generation, energy conversion and environmental remediation will have wide national and international impact. The cross-disciplinary and cross-institution research program proposed will draw on expertise within Australia and in Europe for the fabrication of materials for next generation energy devices. In the future, there is the potential that these materials could be fabricated within Australia and therefore lead to employment nationally, and income generated through the export of advanced catalysts, solar cells and sequestration materials.Read moreRead less