The fate of dietary selenium in vivo; a direct approach to linking chemical form with biological activity. Dietary selenium supplementation has great potential as a preventative treatment for a range of human health conditions, including cancer, that widely affect the Australian population. However, the adverse effects of such treatments are not fully recognised. This project will increase our knowledge of how selenium compounds are stored and utilised in the body and relate the information to c ....The fate of dietary selenium in vivo; a direct approach to linking chemical form with biological activity. Dietary selenium supplementation has great potential as a preventative treatment for a range of human health conditions, including cancer, that widely affect the Australian population. However, the adverse effects of such treatments are not fully recognised. This project will increase our knowledge of how selenium compounds are stored and utilised in the body and relate the information to clinical observations regarding dietary intake of selenium and other compounds. The new understanding generated will delineate the conditions for safe intake, so that the beneficial effects associated with selenium supplementation may be harnessed more effectively.Read moreRead less
Nanoprobe and Microprobe Spectroscopic Techniques in Drug Design, Probing Mechanisms of Diseases, and Bioinorganic Chemistry. Nanoprobe and microprobe spectroscopic techniques offer unparalleled opportunities to probe the structures and distributions of drugs, carcinogens, and biomolecules in cultured cells and tissues. Such techniques represent new frontiers in understanding in vivo metabolic processes at the molecular level, as well as providing unprecedented information on the metabolism and ....Nanoprobe and Microprobe Spectroscopic Techniques in Drug Design, Probing Mechanisms of Diseases, and Bioinorganic Chemistry. Nanoprobe and microprobe spectroscopic techniques offer unparalleled opportunities to probe the structures and distributions of drugs, carcinogens, and biomolecules in cultured cells and tissues. Such techniques represent new frontiers in understanding in vivo metabolic processes at the molecular level, as well as providing unprecedented information on the metabolism and distributions of pharmaceuticals and toxins involved in the treatment and cause of diseases, such as cancer. This project is aimed at pushing the boundaries of nanoprobe and microprobe (X-ray absorption, SRIXE, PIXE, Raman and two-photon fluorescence) techniques for such applications.Read moreRead less
All-solid-state: new hybrid materials for next-generation lithium batteries. The aim of the project is an economically viable design for “all-solid-state” rechargeable batteries. Eliminating organic liquid electrolytes from lithium-ion batteries will dramatically increase safety, range of operating conditions, lifetimes, and energy density. The key technical challenge is keeping solid-solid interfaces intact over thousands of charge/discharge cycles. We will address this by inserting inorganic i ....All-solid-state: new hybrid materials for next-generation lithium batteries. The aim of the project is an economically viable design for “all-solid-state” rechargeable batteries. Eliminating organic liquid electrolytes from lithium-ion batteries will dramatically increase safety, range of operating conditions, lifetimes, and energy density. The key technical challenge is keeping solid-solid interfaces intact over thousands of charge/discharge cycles. We will address this by inserting inorganic interfacial layers that change smoothly from hard ceramic to flexible glass and back again, through rigorous chemical design and synthetic control. This will reduce the stress that causes mechanical failure, while increasing chemical stability so that the latest generation of high-power electrodes can be brought into service.Read moreRead less
Microprobe and Nanoprobe Studies on Intracellular Disease Processes and Their Treatment. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables a deeper understanding of changes in cells that occur as a function of drug treatments an ....Microprobe and Nanoprobe Studies on Intracellular Disease Processes and Their Treatment. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables a deeper understanding of changes in cells that occur as a function of drug treatments and disease processes. This will provide unprecedented information as to where drugs go and how they are transformed inside cells that, in turn, may revolutionalise the way in which new drugs are designed that have higher specificity and fewer side effects.Read moreRead less
Nanoprobe and Microprobe Structural and Spectroscopic Studies in Biomedical Research. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables multi-layered information on changes in cells that occur as a function of drug treatments a ....Nanoprobe and Microprobe Structural and Spectroscopic Studies in Biomedical Research. Breakthrough microprobe and nanoprobe technologies, involving X-ray, visible and infrared light can focus into different components of mammalian cells in order to interrogate the biochemistry that is occurring therein. Each of the different wavelengths of light provides complementary biochemical information that enables multi-layered information on changes in cells that occur as a function of drug treatments and disease processes. This will provide unprecedented information as to where drugs go and how they are transformed inside cells that, in turn, may revolutionalise the way in which new drugs are designed that have higher specificity and lower side effects.Read moreRead less
Enhancing single-molecule magnets. This project aims to design, synthesise and investigate single-molecule magnets that can function at higher temperatures for use in quantum computing and molecular spintronics. Materials science increasingly benefit from molecular approaches, and lanthanoid-based single-molecule magnets could achieve otherwise inaccessible technological developments such as the development of molecular materials for quantum computing and molecular spintronics. Advances in funda ....Enhancing single-molecule magnets. This project aims to design, synthesise and investigate single-molecule magnets that can function at higher temperatures for use in quantum computing and molecular spintronics. Materials science increasingly benefit from molecular approaches, and lanthanoid-based single-molecule magnets could achieve otherwise inaccessible technological developments such as the development of molecular materials for quantum computing and molecular spintronics. Advances in fundamental chemistry are anticipated, and this project is expected to benefit Australia's participation in related high-end technology industries.Read moreRead less
Scaffolding layered structures to improve insertion electrodes. This project aims to change how positive electrodes are designed and improve battery performance. The positive electrode is arguably the largest bottleneck in battery performance. Modifying layered electrodes to produce better batteries has ramifications ranging from longer-lasting portable power for everyday devices and vehicles to energy storage solutions for intermittent power generation sources (i.e., renewables). This project w ....Scaffolding layered structures to improve insertion electrodes. This project aims to change how positive electrodes are designed and improve battery performance. The positive electrode is arguably the largest bottleneck in battery performance. Modifying layered electrodes to produce better batteries has ramifications ranging from longer-lasting portable power for everyday devices and vehicles to energy storage solutions for intermittent power generation sources (i.e., renewables). This project will develop scaffolded layered crystal structures to improve the ease, speed and amount of ion insertion/extraction. These structures will be incorporated into lithium and sodium ion batteries, resulting in better battery lifetime, energy density and charge/discharge speed (capability). This is expected to improve batteries for the future and decrease reliance on fossil fuels for energy.Read moreRead less
Emergent properties in spin crossover materials. This project aims to develop ‘intelligent’ materials in which emergent properties arise due to the strategic combination of spin switching with other functionalities. Spin crossover is a versatile form of molecular switch which can reversibly change structure, colour and magnetism using convenient external stimuli. In probing new and interesting forms of interplay between technologically relevant properties, this work addresses the science of host ....Emergent properties in spin crossover materials. This project aims to develop ‘intelligent’ materials in which emergent properties arise due to the strategic combination of spin switching with other functionalities. Spin crossover is a versatile form of molecular switch which can reversibly change structure, colour and magnetism using convenient external stimuli. In probing new and interesting forms of interplay between technologically relevant properties, this work addresses the science of host-guest and electronic/magnetic systems and could lead to materials worthy of commercial development to underpin a range of future high-level technologies spanning low energy separations, molecular sensing, data storage, and electronic/magnetic/optical device componentry.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100236
Funder
Australian Research Council
Funding Amount
$180,000.00
Summary
Facilities for spectroscopy and diffraction at high pressures. The provision of infrastructure for the study of novel materials under high pressures will enhance Australia's capability in creating new materials and in creating new devices that meet needs in communication, environment and medicine applications. The new facility will enable researchers to understand the response of structures to extreme pressures and will exploit the unique capabilities of the synchrotron light.
The role of interstitial oxide and superoxide anions in ionic conductors. This project seeks to understand how defects and local disorder can facilitate solid-state ionic conductivity in complex oxides. Particular attention will be paid to the under-explored mechanisms by which excess oxygen can be incorporated in these oxides, as opposed to the conventional scenario in which conduction occurs through vacant sites due to an oxygen deficiency. The project aims to characterise the target oxides at ....The role of interstitial oxide and superoxide anions in ionic conductors. This project seeks to understand how defects and local disorder can facilitate solid-state ionic conductivity in complex oxides. Particular attention will be paid to the under-explored mechanisms by which excess oxygen can be incorporated in these oxides, as opposed to the conventional scenario in which conduction occurs through vacant sites due to an oxygen deficiency. The project aims to characterise the target oxides at various length scales using advanced diffraction, spectroscopy and imaging methods, to obtain a holistic multi-scale picture of their structures. It is expected that this will reveal the structure-property relationships required to rationally design new and improved oxide-ion conductors for applications such as solid oxide fuel cells.Read moreRead less