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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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
Special Research Initiatives - Grant ID: SR0354591
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Ma ....New Techniques using X-rays, Electrons and Quantum Optics in Physics & Chemistry and key developments for biomedicine & industry. This network will develop theoretical, experimental and computational techniques addressing key issues in physics, chemistry, biology and geosciences. Scope will be wide-ranging and inclusive. We anticipate making major developments in the design and understanding of absolute X-ray Absorption Fine Structure, X-ray, Neutron and Electron Diffraction, Electron Density Mapping, Molecular and Cluster computations and Powder Diffraction for fundamental research, biomedical and industrial applications. These breakthroughs will be invaluable for the development of Australia's major research infrastructure (the synchrotron, electron microscopes, and the research reactor). This will develop Australian expertise and collaboration at the cutting edge of a variety of interdisciplinary fields.Read moreRead less
Quantum Mechanics and Planetary Atmospheres. The project will increase the visibility and status of Australian research, by the participation of researchers and students in a wide international collaboration, covering experiments, theory, and computation, which will solve a fundamental research problem that has previously defied understanding. The resulting nitrogen model will be relevant to the important fields of global and planetary atmospheric change, and will find immediate application in t ....Quantum Mechanics and Planetary Atmospheres. The project will increase the visibility and status of Australian research, by the participation of researchers and students in a wide international collaboration, covering experiments, theory, and computation, which will solve a fundamental research problem that has previously defied understanding. The resulting nitrogen model will be relevant to the important fields of global and planetary atmospheric change, and will find immediate application in the analysis of results from the NASA missions, Voyager, Cassini, and (later) New Horizons. In the experimental part of the project, an Australian-first extreme-ultraviolet laser facility will be developed which will provide research opportunities complementary to the Australian Synchrotron.Read moreRead less
Calibrating Cosmology: The Near-Field Approach to Galaxy Formation. Understanding the formation and evolution of structure in the early Universe continues to elude astronomers. Studying these earliest epochs is the driver for billion-dollar investments like the Next Generation Space Telescope and the Square Kilometre Array (with Australia as a primary partner). Our complementary 'near-field cosmology' project is unique, blending strengths in computational cosmology, stellar nucleosynthesis, and ....Calibrating Cosmology: The Near-Field Approach to Galaxy Formation. Understanding the formation and evolution of structure in the early Universe continues to elude astronomers. Studying these earliest epochs is the driver for billion-dollar investments like the Next Generation Space Telescope and the Square Kilometre Array (with Australia as a primary partner). Our complementary 'near-field cosmology' project is unique, blending strengths in computational cosmology, stellar nucleosynthesis, and optical astronomy, to 'deconstruct' the formation history of the one galaxy with detailed chemical and kinematical information - our own Milky Way. Combining theory and observation, cosmology and nucleosynthesis, we will produce the template for galaxy formation, providing the anchor for 'far-field' cosmology.Read moreRead less
The Chemical Evolution of the Universe. This program will combine data from the innovative Australian Wide Field Spectrograph with data from the Wide Field Camera 3 of the NASA Hubble Space Telescope and with data from the instruments on the Keck and Subaru large ground-based telescopes. We hope to gain an unprecedented understanding of the chemical evolution of the Universe. This project will raise the international profile of innovative Australian instrumentation technologies, and continue o ....The Chemical Evolution of the Universe. This program will combine data from the innovative Australian Wide Field Spectrograph with data from the Wide Field Camera 3 of the NASA Hubble Space Telescope and with data from the instruments on the Keck and Subaru large ground-based telescopes. We hope to gain an unprecedented understanding of the chemical evolution of the Universe. This project will raise the international profile of innovative Australian instrumentation technologies, and continue our program of internationally recognised cutting-edge research. This research will provide several Australian students with training on world-class space and ground-based telescopes, contributing to the scientific knowledge base of Australia.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.
The mathematics of cold quantum matter. Ongoing advances in the experimental realisation of ultracold quantum matter play a leading role in the international effort towards the eventual realisation of quantum technology. This research project aims to build on and develop Australia's mathematical research strengths to explore and describe the enabling physics of cold quantum matter. This approach will further consolidate and enhance Australia's leadership in quantum science. The program of fundam ....The mathematics of cold quantum matter. Ongoing advances in the experimental realisation of ultracold quantum matter play a leading role in the international effort towards the eventual realisation of quantum technology. This research project aims to build on and develop Australia's mathematical research strengths to explore and describe the enabling physics of cold quantum matter. This approach will further consolidate and enhance Australia's leadership in quantum science. The program of fundamental research will also contribute to training mathematically talented students in a rapidly advancing area with the capacity to contribute to a wide range of problems, including the emerging technology of quantum devices.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
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