Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989127
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of ....A High-Throughput Neutron Spectrometer for The Study of Atomic and Molecular Motion at ANSTO. Neutron scattering enables new science across a broad range of disciplines, and for this reason it is undergoing major expansion in the USA, Europe, Japan and Australia. Various diffactometers and spectrometers have recently been built at ANSTO, but an instrumental option for a high-throughput cross-discipline spectroscopy is urgently needed. Fortunately, it is fairly straightforward to add this type of option to an existing spectrometer that will broaden its user-base from specialised applications in physics to more general applications in physics, chemistry, materials-science and biology. This additional option provides a totally new way for Australian scientists to study atomic and molecular motions. Read moreRead less
Swift Heavy Ion Tracks in Semiconductors and Insulators: New Insights using Synchrotron Scattering Experiments. The proposed research will broaden the domestic knowledge base and enhance the national research profile in an important cross-disciplinary and technologically-relevant field with a potential high impact in areas with considerable national activity. It will train young scientists, particularly in the use of two national facilities: the Australian Synchrotron and the ANU Heavy-Ion Accel ....Swift Heavy Ion Tracks in Semiconductors and Insulators: New Insights using Synchrotron Scattering Experiments. The proposed research will broaden the domestic knowledge base and enhance the national research profile in an important cross-disciplinary and technologically-relevant field with a potential high impact in areas with considerable national activity. It will train young scientists, particularly in the use of two national facilities: the Australian Synchrotron and the ANU Heavy-Ion Accelerator facility. Furthermore, domestic capabilities in materials characterization will be bolstered and the collaboration with overseas investigators will facilitate mutually beneficial transfer of expertise. The proposal is consistent with National Research Priority 3 and the Priority Goals: Breakthrough Science and Frontier Technologies. Read moreRead less
Unlocking the potential of quantitative x-ray micro-tomography. This project aims to build on two new ideas in data acquisition and 3D image reconstruction to bring 3D X-ray microscopy or computed tomography (CT) into advanced research use as well as common industrial applications. In the past 10 years, CT has improved our understanding in areas ranging from the evolution of life and osteoporosis to composite material failure and oil recovery. However, the full potential of CT remains unrealised ....Unlocking the potential of quantitative x-ray micro-tomography. This project aims to build on two new ideas in data acquisition and 3D image reconstruction to bring 3D X-ray microscopy or computed tomography (CT) into advanced research use as well as common industrial applications. In the past 10 years, CT has improved our understanding in areas ranging from the evolution of life and osteoporosis to composite material failure and oil recovery. However, the full potential of CT remains unrealised because crucial features in structure and composition are overlooked by simplistic algorithms. Users cannot directly capture quantities of interest such as key compositional variation or defects, and workflows are poorly adapted for large-scale use in industrial fabrication or phenomics. This project aims to address these shortcomings using advanced mathematics and algorithms.Read moreRead less
Nanoscale investigation of fission track formation and stability in geological environments. Fission tracks are used to date and constrain the thermal history of the earth's crust. This project will use innovative experimental techniques to simulate fission track formation under geologically relevant conditions and resolve open questions related to fission-track dating and materials behaviour in high-pressure and high temperature environments.
Investigation of the structure and stability of ion tracks in application-specific materials and environments. This project will use an innovative experimental approach to study the structure and stability of high-energy ion tracks in solids. It will resolve open questions related to applications in geology, nanotechnology, and nuclear physics, and provide new strategies for understanding materials behaviour under extreme experimental conditions.