Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100020
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
High bandwidth, high speed, terahertz optical sampling and analysis system. This project aims to promote scientific and technological research by providing access to a wide bandwidth, high speed, high resolution advanced terahertz spectrometer. Terahertz frequencies are the least-explored region of the electromagnetic spectrum and investment here is likely to yield scientific and technological reward. Expected outcomes are new commercial devices and products operating in the terahertz regime. Th ....High bandwidth, high speed, terahertz optical sampling and analysis system. This project aims to promote scientific and technological research by providing access to a wide bandwidth, high speed, high resolution advanced terahertz spectrometer. Terahertz frequencies are the least-explored region of the electromagnetic spectrum and investment here is likely to yield scientific and technological reward. Expected outcomes are new commercial devices and products operating in the terahertz regime. The project’s expected effects include new commercial terahertz products; better monitoring of explosives and toxins; research training and job creation; reduced risk in decision making, especially when monitoring water; and cultural benefits, through applying terahertz methods to artworks.Read moreRead less
Wet Granular Materials: A Three-Dimensional Study Using X-Ray Microtomography. Wet granular materials are of immense economic importance in industries such as mining, agriculture, pharmaceuticals, and food processing. It has been estimated that operations involving the storage, handling and transport of granular materials account for over a third of the capital costs and over half of all the operating costs involved in process industries worldwide. An improved understanding of the dramatic effec ....Wet Granular Materials: A Three-Dimensional Study Using X-Ray Microtomography. Wet granular materials are of immense economic importance in industries such as mining, agriculture, pharmaceuticals, and food processing. It has been estimated that operations involving the storage, handling and transport of granular materials account for over a third of the capital costs and over half of all the operating costs involved in process industries worldwide. An improved understanding of the dramatic effects of liquid on the cohesion, flow and mixing of granular materials will be of benefit to Australian industry both in terms of helping to reduce costly problems, such as caking and segregation, and in terms of the development of better particulate-based products, such as ceramics and pharmaceuticals.Read moreRead less
Atomic-Scale Identification of Amorphization and Relaxation Processes in Compound Semiconductors. We seek a fundamental understanding of the processes that govern implantation-induced structure, at the nanometer scale, in the compound semiconductors used in photonic device fabrication. Since implantation-induced disorder limits the performance of such devices, the proposed project is of substantial technological significance and national benefit. The Photon Science techniques of perturbed angu ....Atomic-Scale Identification of Amorphization and Relaxation Processes in Compound Semiconductors. We seek a fundamental understanding of the processes that govern implantation-induced structure, at the nanometer scale, in the compound semiconductors used in photonic device fabrication. Since implantation-induced disorder limits the performance of such devices, the proposed project is of substantial technological significance and national benefit. The Photon Science techniques of perturbed angular correlation and extended x-ray absorption fine structure spectroscopy will be used to identify the mechanism of amorphisation and relaxation in order to enable more effective exploitation of compound semiconductors in advanced telecommunications systems.Read moreRead less
GRANULAR MATERIALS IN 3D: Structural, mechanical and dynamic properties from the grain-scale and beyond. Granular materials are the most abundant class of materials processed, stored or handled. They span from cereals to advanced-new-materials and, although simple in composition, their behaviour remains elusive. Through the unique combination of an advanced X-ray tomography facility and cutting-edge 3D network analysis and statistical mechanics approach, the structure, mechanics and dynamic be ....GRANULAR MATERIALS IN 3D: Structural, mechanical and dynamic properties from the grain-scale and beyond. Granular materials are the most abundant class of materials processed, stored or handled. They span from cereals to advanced-new-materials and, although simple in composition, their behaviour remains elusive. Through the unique combination of an advanced X-ray tomography facility and cutting-edge 3D network analysis and statistical mechanics approach, the structure, mechanics and dynamic behaviour of these systems will be explored at the grain-scale.
A greater understanding of this class of materials, which ranks second only to water on the scale of priorities of human activity, will have strong scientific, technological and economical impact in a wide range of fields from concrete to photonic-materials.Read moreRead less
Unlocking the potential of n-type silicon for solar cells. This project will lead to an improved understanding of impurities in silicon, especially several emerging low-cost n-type silicon materials made especially for solar cells. This knowledge will enable the negative effects of these impurities to be eliminated or reduced, thus yielding higher efficiency modules that produce solar electricity at a lower cost. The potential benefits to Australia, which already has an established silicon solar ....Unlocking the potential of n-type silicon for solar cells. This project will lead to an improved understanding of impurities in silicon, especially several emerging low-cost n-type silicon materials made especially for solar cells. This knowledge will enable the negative effects of these impurities to be eliminated or reduced, thus yielding higher efficiency modules that produce solar electricity at a lower cost. The potential benefits to Australia, which already has an established silicon solar cell industry, are large. They include increased employment in well-paid high-technology jobs, increased export earnings, and reduced carbon dioxide emissions. These benefits could grow rapidly, in line with the global photovoltaic industry growth rate of more than 30% per year.Read moreRead less
Boron Nitride Nanotub Synthesis and Applications. Boron nitride (BN) nanotubes have an analogous structure to carbon nanotubes but offer many electronic and chemical properties. This project aims to synthesis BN nanotubes with controlled structures using a mechano-thermal method involving ball milling of boron powder at room temperature followed by thermal annealing in nitrogen gas. Systematic investigation will be conducted to clarify the fundamental formation mechanism related to various nano ....Boron Nitride Nanotub Synthesis and Applications. Boron nitride (BN) nanotubes have an analogous structure to carbon nanotubes but offer many electronic and chemical properties. This project aims to synthesis BN nanotubes with controlled structures using a mechano-thermal method involving ball milling of boron powder at room temperature followed by thermal annealing in nitrogen gas. Systematic investigation will be conducted to clarify the fundamental formation mechanism related to various nanostructures. New chemical, mechanical and thermal properties and possible applications will be explored. The outcomes of this research will be profoundly understanding of the controlled assembly of small atoms into nanosized tubules and an innovative synthesis technology.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
Special Research Initiatives - Grant ID: SR0354821
Funder
Australian Research Council
Funding Amount
$30,000.00
Summary
Innovative Materials Production, Processing and Analysis Network. Materials science and engineering is decidedly interdisciplinary, covering a diverse spectrum of research from biology to construction, with an equally broad applications span encompassing all manufacturing industry. Australia has distinct strengths in materials but it has been difficult to promote sufficient interaction across discipline boundaries to fully exploit such strengths. The current network focuses on interdisciplinar ....Innovative Materials Production, Processing and Analysis Network. Materials science and engineering is decidedly interdisciplinary, covering a diverse spectrum of research from biology to construction, with an equally broad applications span encompassing all manufacturing industry. Australia has distinct strengths in materials but it has been difficult to promote sufficient interaction across discipline boundaries to fully exploit such strengths. The current network focuses on interdisciplinary materials interactions nationally by: i) bringing the materials community together at an annual workshop, ii) exposing PhD students and young researchers to cross-disciplinary research initiatives and facilities, iii) identifying common infrastructure needs, iv) linking with industry networks, eg AMTN, and to the international community.Read moreRead less
Formation and manipulation of ferroelectric domains with ultrafast light. This project aims to study the fundamental processes governing interaction of ultrafast light pulses with an important class of ferroelectric materials. In particular, it will investigate the physics of light-induced ferroelectric domain reversal in various types of ferroelectrics. Project outcomes will lead to the development of a novel, ultrafast laser domain patterning technique for application in nonlinear photonics, o ....Formation and manipulation of ferroelectric domains with ultrafast light. This project aims to study the fundamental processes governing interaction of ultrafast light pulses with an important class of ferroelectric materials. In particular, it will investigate the physics of light-induced ferroelectric domain reversal in various types of ferroelectrics. Project outcomes will lead to the development of a novel, ultrafast laser domain patterning technique for application in nonlinear photonics, optical memories, and photovoltaics. This technique will be employed to create the first example of three-dimensional domain patterns for versatile wave interactions. This project expects to expand Australia's knowledge in ultrafast laser engineering of materials and contribute towards its rapid uptake by industries, with great potential for commercialisation.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100197
Funder
Australian Research Council
Funding Amount
$1,102,947.00
Summary
Cryogenic Scanning Microwave Measurement Facility for Quantum Materials. This proposal addresses a major experimental capacity gap in Australian infrastructure for research and development of novel electronic materials and nanoscale quantum devices for future technologies. It will establish Australia's first non-contact, non-destructive, cryogenic scanning microwave microscopy facility for advanced materials characterization enabling new studies of these materials in the 2 to 300 Kelvin temperat ....Cryogenic Scanning Microwave Measurement Facility for Quantum Materials. This proposal addresses a major experimental capacity gap in Australian infrastructure for research and development of novel electronic materials and nanoscale quantum devices for future technologies. It will establish Australia's first non-contact, non-destructive, cryogenic scanning microwave microscopy facility for advanced materials characterization enabling new studies of these materials in the 2 to 300 Kelvin temperature range. The facility will provide crucial new information for the development of future quantum materials, enhancing our international competitiveness in the development of next-generation electronic materials and device technologies.Read moreRead less