Studying Molecular Dynamics with Electron and Laser Interactions. We plan to use state-of-the-art experimental techniques and methodologies to probe the dynamics of molecular processes stimulated by either laser or electron interactions. These processes are fundamental to our understanding of both natural phenomena and many devices used in the technology of today and of the future. As a result of this study our insight into the mechanisms underpining these phenomena and devices will be enhanced.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0219618
Funder
Australian Research Council
Funding Amount
$215,000.00
Summary
National Facility for Advanced Molecular Orbital Imaging. We will develop a new two-dimensional multiparameter high-resolution electron momentum spectroscopy (EMS) spectrometer that incorporates multiparameter data acquisition and reduction techniques and combine it with a new time of flight (TOF) ion-analyser in order to perform the first high-resolution EMS with oriented target experiments.
In conjunction with theoretical calculations, the results from these experiments will provide the most ....National Facility for Advanced Molecular Orbital Imaging. We will develop a new two-dimensional multiparameter high-resolution electron momentum spectroscopy (EMS) spectrometer that incorporates multiparameter data acquisition and reduction techniques and combine it with a new time of flight (TOF) ion-analyser in order to perform the first high-resolution EMS with oriented target experiments.
In conjunction with theoretical calculations, the results from these experiments will provide the most advanced evaluation for molecular orbital imaging quality for the chemically significant targets we wish to study. This in turn will lead to the determination of more accurate physico-chemical information, including structure and bonding information, for these targets.Read moreRead less
Cross sections for electron scattering from molecules and radicals of technological and environmental relevance. We will use two state of the art crossed beam spectrometers to measure absolute differential and integral cross sections for low energy electron scattering from molecules and their molecular fragments (radicals). The species to be considered are those of significant industrial (e.g. C2F4, C4F8 and CF2) and environmental (e.g. CO2 and H2O) interest, with the cross sections we will mea ....Cross sections for electron scattering from molecules and radicals of technological and environmental relevance. We will use two state of the art crossed beam spectrometers to measure absolute differential and integral cross sections for low energy electron scattering from molecules and their molecular fragments (radicals). The species to be considered are those of significant industrial (e.g. C2F4, C4F8 and CF2) and environmental (e.g. CO2 and H2O) interest, with the cross sections we will measure being crucial to our modelling both the processes involved in plasma enhanced chemical vapour desposition of semiconductor devices and the spectral emission characteristics of planetary atmospheres. The modelling will be conducted self-consistently with our enhanced statistical equilibrium simulation code, which is unique to Australia.Read moreRead less
Environmental and Technological Applications of Electron-Driven Processes. We plan to use state-of-the-art experimental techniques and methodologies for the measurement of collision cross sections and reaction rates for low energy electron-driven process in molecules and molecular radicals. These processes are fundamental to our understanding of our environment and many devices used in the technology of today and of the future. In particular we will provide accurate cross sections for NOx and SO ....Environmental and Technological Applications of Electron-Driven Processes. We plan to use state-of-the-art experimental techniques and methodologies for the measurement of collision cross sections and reaction rates for low energy electron-driven process in molecules and molecular radicals. These processes are fundamental to our understanding of our environment and many devices used in the technology of today and of the future. In particular we will provide accurate cross sections for NOx and SOx pollutants and H2O, as well for molecules such as C4F8, and its radicals such as CF2, which are used extensively in plasma processing technologies.Read moreRead less
Inter- and Intra-molecular interactions probed by electron momentum spectroscopy. High-resolution electron momentum spectroscopy (EMS) will be used to study bonding (intra-molecular interactions) in complex oriented organic species. This will allow us, in conjunction with density functional theory calculations, to evaluate the basis sets and exchange-correlation (XC) functionals employed in those calculations, thereby potentially enabling quantum chemists to build more physically accurate XC-fu ....Inter- and Intra-molecular interactions probed by electron momentum spectroscopy. High-resolution electron momentum spectroscopy (EMS) will be used to study bonding (intra-molecular interactions) in complex oriented organic species. This will allow us, in conjunction with density functional theory calculations, to evaluate the basis sets and exchange-correlation (XC) functionals employed in those calculations, thereby potentially enabling quantum chemists to build more physically accurate XC-functionals and basis sets. As chemistry largely occurs in solution, the future will increasingly focus on solvated species. Consequently, we are also initiating an EMS study of the electronic wavefunctions of solvated species with our recently developed "clusters" EMS spectrometer. This will provide the first data on the electronic wavefunctions involved in inter-molecular interactions.Read moreRead less
SENSORS FOR AROMATIC MOLECULES BASED ON METAL ION ACTIVATED MOLECULAR RECEPTORS. This project aims to develop highly sensitive chemical sensors for aromatic compounds which will quantify their concentration, in situ, without elaborate sample preparation or instrumentation. The sensors will employ advanced supramolecular chemistry in which the aromatic molecule becomes trapped within a binding cavity in the three dimensional structure of a larger receptor molecule. Coincident with the entrapmen ....SENSORS FOR AROMATIC MOLECULES BASED ON METAL ION ACTIVATED MOLECULAR RECEPTORS. This project aims to develop highly sensitive chemical sensors for aromatic compounds which will quantify their concentration, in situ, without elaborate sample preparation or instrumentation. The sensors will employ advanced supramolecular chemistry in which the aromatic molecule becomes trapped within a binding cavity in the three dimensional structure of a larger receptor molecule. Coincident with the entrapment a change in the fluorescence level of the receptor occurs which signals the presence of the aromatic compound and its concentration. This research will stimulate economic and social benefits through the development of new environmental and medical sensing techniques and analytical diagnostics.Read moreRead less
Multifunctional mixed matrix membranes incorporating aligned carbon nanotubes. The pressure on water supplies in Australia will only increase in coming years meaning that effective and cheap means of recycling water must be found. By developing a carbon nanotube-based water filtration system, we intend to promote the growth of Australia's world-class reputation in water remediation. The technological outcomes from this research will lead to direct economic and environmental benefits for the comm ....Multifunctional mixed matrix membranes incorporating aligned carbon nanotubes. The pressure on water supplies in Australia will only increase in coming years meaning that effective and cheap means of recycling water must be found. By developing a carbon nanotube-based water filtration system, we intend to promote the growth of Australia's world-class reputation in water remediation. The technological outcomes from this research will lead to direct economic and environmental benefits for the community and offer commercial opportunities for industry. Training research scientists of the future forms an integral part of our program as it is crucial to maintain a critical mass in this potentially forthcoming water based economy.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560862
Funder
Australian Research Council
Funding Amount
$546,700.00
Summary
South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions w ....South Australian Facility for Advanced Molecular Imaging. The aim of this project is to establish the South Australian Facility for Advanced Molecular Imaging. The Facility builds on existing expertise and cooperation between the collaborating institutions to expand our capability in advanced analytical confocal microscopy of a wide range of materials from living cells to artificial surfaces. New state-of-the-art microscopes will allow the direct quantitative analysis of molecular interactions with high temporal and spatial resolutions. This will advance: understanding the regulation of cellular signalling, gene expression and growth in normal and pathological conditions; development of biosensor technology; and the application of new biomaterials in medicine and industry.Read moreRead less
New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging populatio ....New clean and green aqueous metathesis. The technique of olefin metathesis has already yielded new pharmaceuticals and materials for use in consumer products and ballistic protection. This project will help move metathesis into the realms of natures aqueous environment, a key advance if metathesis is to reveal its full potential in biological, polymeric, and pharmaceutical applications. We specifically aim to target treatments for cataract (and other conditions associated with an aging population) and also important new biopolymers for use in health technologies of the future.Read moreRead less
Electron transfer in proteins, a study of mechanism and function. Our research will probe the mechanisms by which nature's living systems build, maintain, and reproduce. We present an ability to understand these processes at a detailed molecular level using science and technology at the forefront of multidisciplinary research. The research will provide a foundation for new smart materials, technologies and future industries, and also ways forward for future basic scientific research and endeavo ....Electron transfer in proteins, a study of mechanism and function. Our research will probe the mechanisms by which nature's living systems build, maintain, and reproduce. We present an ability to understand these processes at a detailed molecular level using science and technology at the forefront of multidisciplinary research. The research will provide a foundation for new smart materials, technologies and future industries, and also ways forward for future basic scientific research and endeavor. All this is done with the best international researchers and capabilities within a local environment that will help to train the next generation of Australian scientists.Read moreRead less