Benchmarking of advanced scattering probes for materials characterisation. The project seeks to establish the accuracy and validity of different methods of nanoscale structure determination. Nanoscale structure is crucial to the properties of many modern materials with diverse applications: e.g. sensors and actuators in cell phones; smart shock absorbers and fuel injectors in cars; memory devices; drug delivery devices.
Porosity in Si, Ge and the Si(x)Ge(1-x) alloys induced by ion irradiation. Ion beam methods will be used to form porous layers in Si, Ge and their alloys with a range of technological applications. The distributions of pore size and shape will be characterised with laboratory and synchrotron-based analytical techniques including a 3D reconstruction of the irradiation-induced porous structure.
A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outc ....A new in-situ structural measurement capability during nanoindentation. A new in-situ structural measurement capability during nanoindentation. This project aims to develop an in-situ Raman capability to obtain dynamic structural and mechanical behaviour of materials as a function of pressure during nanoindentation; and apply the new capability to directly monitor phase changes in silicon and germanium under pressure and correlate them with the simultaneous electrical responses. Anticipated outcomes are new instrumentation to directly probe the pressure-temperature phase diagram, and measure electrical properties of novel end phases in these semiconductors.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100075
Funder
Australian Research Council
Funding Amount
$580,000.00
Summary
Next Generation Small Angle X-Ray Scattering Facility. Next generation small angle X-ray scattering facility: The ability to determine the nanostructure of bulk materials is of utmost importance in an array of cutting-edge research fields. A state-of-the-art small angle X-ray scattering (SAXS) facility will address this for a wide range of materials covering a diverse range of research topics such as energy storage materials, catalytic species, drug delivery systems, protein structures, biologic ....Next Generation Small Angle X-Ray Scattering Facility. Next generation small angle X-ray scattering facility: The ability to determine the nanostructure of bulk materials is of utmost importance in an array of cutting-edge research fields. A state-of-the-art small angle X-ray scattering (SAXS) facility will address this for a wide range of materials covering a diverse range of research topics such as energy storage materials, catalytic species, drug delivery systems, protein structures, biological membranes, medical diagnostics and therapy, magnetic nanosystems, polymers, novel technologies for the clean utilisation of biomass, and minerals processing. The facility will underpin a range of current and planned multidisciplinary research programs leading to vital nanostructural information and innovative research solutions.Read moreRead less
Nanoparticle inks for electronic applications employing nanostructured thin-films. The development of next-generation technologies requires careful engineering of materials at the nanoscale. Using nanoparticle inks, many of the engineering difficulties which exist at these length scales can be overcome, thus allowing for technologies such as thin-film solar cells to become cheaper and more efficient.