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
Electron and Positron Interactions with Bio-Molecules. This program of research will quantify reaction rates and elucidate reaction pathways for a range of important processes in our bodies involving ionising radiation. It will lead to a greatly improved understanding of positron and electron interactions with biological systems, including DNA and its constituent molecules and, through a better understanding of the underlying fundamental interactions, will lay foundations for improvements in te ....Electron and Positron Interactions with Bio-Molecules. This program of research will quantify reaction rates and elucidate reaction pathways for a range of important processes in our bodies involving ionising radiation. It will lead to a greatly improved understanding of positron and electron interactions with biological systems, including DNA and its constituent molecules and, through a better understanding of the underlying fundamental interactions, will lay foundations for improvements in technologies such as PET imaging. 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
Molecular Energies and Non-Bonded Interactions. The development of new techniques that allow non-bonded chemical interactions to be modelled and predicted reliably and accurately will allow researchers in the chemical, and pharmaceutical sciences to predict the physical and chemical behaviour of moderately large molecular systems with an accuracy and efficiency that has not previously been possible. The software that will result will enable cost and time savings in molecular design within the m ....Molecular Energies and Non-Bonded Interactions. The development of new techniques that allow non-bonded chemical interactions to be modelled and predicted reliably and accurately will allow researchers in the chemical, and pharmaceutical sciences to predict the physical and chemical behaviour of moderately large molecular systems with an accuracy and efficiency that has not previously been possible. The software that will result will enable cost and time savings in molecular design within the medical and agricultural contexts.Read moreRead less
Precision Measurement of Highly Excited Atoms and Molecules: From the Infrared to the Vacuum Ultraviolet. Precise measurements of the structure and dynamics of atomic and molecular systems provide important benchmarks against which our fundamental understanding of matter can be tested. Such measurements also provide reference standards, with applications in many subfields (e.g. testing theories that indicate time dependence of the fundamental constants). Determination of the behaviour of simple ....Precision Measurement of Highly Excited Atoms and Molecules: From the Infrared to the Vacuum Ultraviolet. Precise measurements of the structure and dynamics of atomic and molecular systems provide important benchmarks against which our fundamental understanding of matter can be tested. Such measurements also provide reference standards, with applications in many subfields (e.g. testing theories that indicate time dependence of the fundamental constants). Determination of the behaviour of simple molecules such as oxygen and nitrogen is important for understanding the complex processes that shape the atmosphere of the earth and other planets. These experiments will also enable the understanding of other chemical processes, and will build on our strengths in developing precision laser technologies.Read moreRead less
Understanding the chemistry and evolution of planets and their atmospheres: Integrating experiments, observations, and quantum mechanical models. Ongoing changes in the Earth's atmosphere, demonstrate the need to understand photochemical processes and their role in atmospheric evolution. The proposed research will increase our understanding of the evolution of planetary atmospheres, with concomitant insight into the Earth's evolution. This proposal will greatly enhance the visibility of Australi ....Understanding the chemistry and evolution of planets and their atmospheres: Integrating experiments, observations, and quantum mechanical models. Ongoing changes in the Earth's atmosphere, demonstrate the need to understand photochemical processes and their role in atmospheric evolution. The proposed research will increase our understanding of the evolution of planetary atmospheres, with concomitant insight into the Earth's evolution. This proposal will greatly enhance the visibility of Australian research, through formal, direct connections to NASA and ESA (European Space Agency) planetary exploration missions, along with publications in Nature, Science, and/or PNAS (Proceedings of the National Academy of Sciences) that will likely result from the high-profile problems to be studied. Furthermore, as a result of this collaboration, Australian students and postdoctoral researchers will benefit from interactions with top international scientists.Read moreRead less
Electron correlation models using morph operators and hybrid intracules. A new solution to the central problem in quantum chemistry will allow researchers in the chemical, pharmaceutical and materials sciences to predict the chemical behaviour of moderately large molecular systems with an accuracy and efficiency that has not previously been possible. The software that will result will enable cost and time savings in the design of advanced materials in the medical and agricultural contexts.
Reaction transition states of halide-cluster complexes via velocity-map imaging of photoelectrons. This study will investigate the transition point between the reactants and products of a chemical reaction using a novel photoelectron imaging technique, velocity-map imaging. It is this region of chemical reactions that is the least understood. By combining the use of weakly bound negatively charged clusters and laser photodetachment of these clusters, information can be gleaned about these transi ....Reaction transition states of halide-cluster complexes via velocity-map imaging of photoelectrons. This study will investigate the transition point between the reactants and products of a chemical reaction using a novel photoelectron imaging technique, velocity-map imaging. It is this region of chemical reactions that is the least understood. By combining the use of weakly bound negatively charged clusters and laser photodetachment of these clusters, information can be gleaned about these transition states. The technique will be applied to an important class of halide-cluster complexes that form a set of prototypical reactions. These species also play important roles ranging from ozone depletion through to industrial chemistry.Read moreRead less
Imaging chemical reaction dynamics from the transition state to reaction products. Chemical reactions play a key role in many atmospheric, environmental and industrial processes. An understanding of reactions at the molecular level will lead to significant economic benefits, through more efficient reaction control, and through the identification of the key environmental factors which influence why particular reactions proceed. Our study of chemical reaction dynamics has been driven by technolo ....Imaging chemical reaction dynamics from the transition state to reaction products. Chemical reactions play a key role in many atmospheric, environmental and industrial processes. An understanding of reactions at the molecular level will lead to significant economic benefits, through more efficient reaction control, and through the identification of the key environmental factors which influence why particular reactions proceed. Our study of chemical reaction dynamics has been driven by technological advances which enable key stages of a reaction to be imaged and studied at the molecular level. Read moreRead less
Isotopic fractionation in planetary atmospheres. Ongoing changes in the Earth's atmosphere, such as ozone depletion, demonstrate the need to understand atmospheric photochemical processes. Isotopic fractionation is one vehicle for obtaining
detailed insight into these processes. The proposed research will
increase our understanding of fundamental molecular processes and use these new results to improve our knowledge of isotopic fractionation in planetary atmospheres. The resulting models wil ....Isotopic fractionation in planetary atmospheres. Ongoing changes in the Earth's atmosphere, such as ozone depletion, demonstrate the need to understand atmospheric photochemical processes. Isotopic fractionation is one vehicle for obtaining
detailed insight into these processes. The proposed research will
increase our understanding of fundamental molecular processes and use these new results to improve our knowledge of isotopic fractionation in planetary atmospheres. The resulting models will lead to new insight into the Earth's ozone chemistry and the recent evolution of Titan's and Venus' atmospheres, including how much water may have been present on Venus in the recent past. The research program also enables Australian participation in three international spacecraft
missions.
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