Enhancing Selectivity and Detection in Miniaturised Analytical Separation Systems. Miniaturisation-compatible stationary phases and detection techniques will be developed for microseparation techniques of capillary electrochromatography and chip-based separation systems, and their analytical applications will be investigated. Replaceable stationary phases (RSP) of chromatographic particles suspended in reversible gels will be created by delivering a liquid RSP to the column followed by in situ ....Enhancing Selectivity and Detection in Miniaturised Analytical Separation Systems. Miniaturisation-compatible stationary phases and detection techniques will be developed for microseparation techniques of capillary electrochromatography and chip-based separation systems, and their analytical applications will be investigated. Replaceable stationary phases (RSP) of chromatographic particles suspended in reversible gels will be created by delivering a liquid RSP to the column followed by in situ immobilisation. This approach offers flexibility in optimising a number of parameters of the column and of its use for sample pre-treatment and preconcentration. Pulsed potentiometric detection will be developed for the abovementioned microseparation techniques, combining the advantages of pulsed amperometric techniques with the more universally responding potentiometric detection.Read moreRead less
Gas phase studies of reactive organic radicals: a novel approach using mass spectrometry. Radical reactions play a crucial role in a range of important chemistries, ranging from the formation of photochemical smog to the accumulation of pathogens in the ageing body. Despite their importance, the reactions of many radicals are poorly understood because of current experimental limitations. In this project we propose to develop two new and broadly applicable techniques for probing radical chemistry ....Gas phase studies of reactive organic radicals: a novel approach using mass spectrometry. Radical reactions play a crucial role in a range of important chemistries, ranging from the formation of photochemical smog to the accumulation of pathogens in the ageing body. Despite their importance, the reactions of many radicals are poorly understood because of current experimental limitations. In this project we propose to develop two new and broadly applicable techniques for probing radical chemistry in the gas phase via novel applications of mass spectrometry. Combined with quantum chemical calculations and state-of-the-art thermodynamic measurements these methods will provide a comprehensive understanding of the reactivity of key organic radicals.Read moreRead less
Optical Spectroscopy of Extraterrestrial Molecules. Space is not empty. In the vast regions between stars is a complex soup of molecules. Some of these molecules get incorporated into meteorites and find their way to Earth where they can be identified. Analysis has yielded amino acids; the building blocks of life, but these molecules do not match what we know about the interstellar regions. Interstellar molecules are identified by their spectra, but many features in these spectra are unknown. ....Optical Spectroscopy of Extraterrestrial Molecules. Space is not empty. In the vast regions between stars is a complex soup of molecules. Some of these molecules get incorporated into meteorites and find their way to Earth where they can be identified. Analysis has yielded amino acids; the building blocks of life, but these molecules do not match what we know about the interstellar regions. Interstellar molecules are identified by their spectra, but many features in these spectra are unknown. Could they be caused by the missing molecules? In this project we combine the skills of three spectroscopists, each expert in different areas, in an attempt to make these molecules in the laboratory, measure their spectra and thereby identify these unknown molecules that are in space.Read moreRead less
Gas Phase Dynamics of a Biological Molecular Machine: Fundamentals, Stoichiometries and Stabilities. Over the last twenty years advanced molecular measurement techniques have enabled the characterization of individual biological molecules (proteins and DNA) within different types of cells and diseased tissues. This project uses a new technique that literally "weighs" groups of proteins and/or DNA to help us understand how such large molecules fit together and function within cells (sometimes ref ....Gas Phase Dynamics of a Biological Molecular Machine: Fundamentals, Stoichiometries and Stabilities. Over the last twenty years advanced molecular measurement techniques have enabled the characterization of individual biological molecules (proteins and DNA) within different types of cells and diseased tissues. This project uses a new technique that literally "weighs" groups of proteins and/or DNA to help us understand how such large molecules fit together and function within cells (sometimes referred to as molecular machinery). More detailed knowledge of processes such as those involved in copying DNA when new cells are produced will, in the long term, improve our understanding and treatment of conditions or diseases that result from errors in molecular machinery. Read moreRead less
Towards Microfluidic-Based Advanced Remote Analysis. The research under this project will establish and systematically develop Advanced Remote Analysis as a new inter-disciplinary area and establish a leadership role for Australia. By addressing pressing needs such as monitoring the environment, remote medical diagnostics, advancing Australian science and technology, or monitoring for traces of explosives, this project falls directly into all four of the National Research Priorities with applica ....Towards Microfluidic-Based Advanced Remote Analysis. The research under this project will establish and systematically develop Advanced Remote Analysis as a new inter-disciplinary area and establish a leadership role for Australia. By addressing pressing needs such as monitoring the environment, remote medical diagnostics, advancing Australian science and technology, or monitoring for traces of explosives, this project falls directly into all four of the National Research Priorities with applications addressing corresponding Priority Goals. Other areas benefiting from the outcomes of this project will be remote monitoring of agricultural production including living species, and a number of other industries such as biotechnology, mineral processing, power generation etc.Read moreRead less
Novel approach to study mechanisms of Na+ transport in plants using Lab on a Chip technology. A Lab on a Chip for sodium ion measurements in plants is proposed, offering a long overdue solution to the lack of appropriate techniques to study the mechanisms of sodium iron uptake, transport and compartmentation. Sodium ion transport is a key determinant of salt tolerance, but a good understanding of its transport mechanisms is lacking since no appropriate measurement tools are available. Using the ....Novel approach to study mechanisms of Na+ transport in plants using Lab on a Chip technology. A Lab on a Chip for sodium ion measurements in plants is proposed, offering a long overdue solution to the lack of appropriate techniques to study the mechanisms of sodium iron uptake, transport and compartmentation. Sodium ion transport is a key determinant of salt tolerance, but a good understanding of its transport mechanisms is lacking since no appropriate measurement tools are available. Using the system proposed here, sodium ion is separated from interfering ions, allowing fast and selective measurements. A series of ground breaking studies towards sodium ion uptake, transport and compartmentation in plants will be conducted using this Lab on a Chip.Read moreRead less
A Gas Phase Study of Macromolecular Biological Complexes. Following the completion of the human genome project, increased attention has focussed on the elucidation of structure and function of biopolymers in cells. The project aims to use electrospray ionisation mass spectrometry (a rapidly developing analytical technique) to detail the processes governing the formation of macromolecular complexes (DNA-protein and DNA-metal-protein) in the gas phase. We aim to explore the relevance of gas pha ....A Gas Phase Study of Macromolecular Biological Complexes. Following the completion of the human genome project, increased attention has focussed on the elucidation of structure and function of biopolymers in cells. The project aims to use electrospray ionisation mass spectrometry (a rapidly developing analytical technique) to detail the processes governing the formation of macromolecular complexes (DNA-protein and DNA-metal-protein) in the gas phase. We aim to explore the relevance of gas phase studies of these large macromolecular complexes to interactions between biopolymers in solution and cells. Ultimately, this will aid in the development of improved therapeutics tha t act on DNA and/or DNA-binding proteins and provide new information on biological processes such as replicaton.Read moreRead less
Disposable microdevices for fast ion analysis. The design and fabrication of a microdevice for ion chromatography will introduce Australia to the field of miniaturised total analytical systems (µTAS). The availability of infrastructure, technology and experience in the µTAS area will provide the foundation for specialised commercialisation of sophisticated, chip-based analytical instruments. These instruments have important applications in forensic, clinical and environmental chemistry.
Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid ....Understanding, Control, and Optimisation of Free Volume Mediated Transport in Technologically Important Materials. The understanding gained by this work will enable Australian scientists to outpace their competitors in rational materials design for transport of atoms and molecules in materials while reducing the costly trial and error stage of research. Specific examples studied and new materials investigated have important technological significance from use in flat panel TV screens, to solid state electrolytes for application in a wide range of electrochemical devices. The understanding gained by this work can be applied to a wide range of important materials e.g. separation membranes, nanofilters and catalysts which help address a number of National Research Priorities.Read moreRead less