Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0561240
Funder
Australian Research Council
Funding Amount
$121,510.00
Summary
Combined reactor for the plasma-enhanced chemical vapour deposition (PECVD) of amorphous layers of silicon, silicon nitride and silicon oxide, and for Reactive Ion Etching. Our small, but very productive group (up to 30 publications per Discovery grant) has reached critical mass (8 people), and the acquisition of essential infrastructure is peremptory. Without the proposed plasma reactor our strong international impact (10 papers, one invited, at the 2003 world conference on photovoltaics) will ....Combined reactor for the plasma-enhanced chemical vapour deposition (PECVD) of amorphous layers of silicon, silicon nitride and silicon oxide, and for Reactive Ion Etching. Our small, but very productive group (up to 30 publications per Discovery grant) has reached critical mass (8 people), and the acquisition of essential infrastructure is peremptory. Without the proposed plasma reactor our strong international impact (10 papers, one invited, at the 2003 world conference on photovoltaics) will wane. This machine permits to deposit thin layers of silicon nitride and amorphous silicon and is a versatile tool for investigating silicon materials for photovoltaics and microelectronics. Such reactors have become an essential tool for silicon solar cell work. Most laboratories across the world have at least one, including UNSW, but access to the latter is impractical.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
Graphene based nanostructures for high performance devices. Graphene sheets are the building blocks of graphite and a huge variety of carbon based nanostructures. Stacked graphene sheets have the unique property of the highest known thermal conductivity. By manipulating graphene sheets into three-dimensional channels and interconnects, vastly increased heat fluxes can be extracted from sensitive nanoscale devices such as microprocessors and micro electro mechanical systems. The potential of stac ....Graphene based nanostructures for high performance devices. Graphene sheets are the building blocks of graphite and a huge variety of carbon based nanostructures. Stacked graphene sheets have the unique property of the highest known thermal conductivity. By manipulating graphene sheets into three-dimensional channels and interconnects, vastly increased heat fluxes can be extracted from sensitive nanoscale devices such as microprocessors and micro electro mechanical systems. The potential of stacks of graphene as electrical contacts and interconnects will also be explored. By combining thermal and electrical functions, graphene will allow more efficient use of the valuable space on future devices. The outcome will be more efficient nanoscale devices to meet ever increasing performance demands.Read moreRead less
Nanocavities in Si - Structural Evolution and Metal Gettering. Nanocavities represent a novel means of minimising metallic contamination in the active region of Si microelectronic devices. We propose innovative experiments, using in-situ transmission electron microscopy and synchrotron-based x-ray methods, to achieve a fundamental understanding of the processes that govern nanocavity structural evolution and metallic impurity trapping. We seek to develop a patentable technology to enhance impu ....Nanocavities in Si - Structural Evolution and Metal Gettering. Nanocavities represent a novel means of minimising metallic contamination in the active region of Si microelectronic devices. We propose innovative experiments, using in-situ transmission electron microscopy and synchrotron-based x-ray methods, to achieve a fundamental understanding of the processes that govern nanocavity structural evolution and metallic impurity trapping. We seek to develop a patentable technology to enhance impurity trapping efficiency and thus dramatically increase the applicability of this industrially-relevant process.Read moreRead less
Probing the properties of amorphous semiconductors with swift heavy ion irradiation and synchrotron radiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Frontier Technologies and Advanced Materials. We seek to deduce and understand the processes operative during swift heavy ion irradiation of amorphous semiconductors to probe fundamental materials properties. Ou ....Probing the properties of amorphous semiconductors with swift heavy ion irradiation and synchrotron radiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Frontier Technologies and Advanced Materials. We seek to deduce and understand the processes operative during swift heavy ion irradiation of amorphous semiconductors to probe fundamental materials properties. Our results and accompanying scientific insight will broaden the applicability of amorphous semiconductors in advanced technologies, enhance the national research profile, increase the domestic knowledge base and yield skilled, young scientists trained to utilise the Australian Synchrotron.Read moreRead less
Amorphous-Phase Formation and Structure in Semiconductor Substrates following Swift Heavy-Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Frontier Technologies and Advanced Materials. We seek to deduce and understand the processes operative during swift heavy-ion irradiation of elemental and binary semiconductor substrates and identify and measure the ....Amorphous-Phase Formation and Structure in Semiconductor Substrates following Swift Heavy-Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and the Priority Goals: Breakthrough Science, Frontier Technologies and Advanced Materials. We seek to deduce and understand the processes operative during swift heavy-ion irradiation of elemental and binary semiconductor substrates and identify and measure the resulting amorphous-phase structure. Our results and accompanying scientific insight will broaden the applicability of these materials in advanced technologies, enhance the national research profile, increase the domestic knowledge base and yield skilled, young scientists trained to utilize the Australian Synchrotron when commissioned in 2007.Read moreRead less
Compact high voltage superconducting fault current limiter employing a new core architecture and novel magnetic materials. The proposed project is an example of applied research that utilises a frontier technology (superconductors) in an application with both national and community benefits. Fault current limiters are designed to protect electricity grids. The integration of superconductors in fault current limiting applications allows for this protection to be achieved in an energy efficient ma ....Compact high voltage superconducting fault current limiter employing a new core architecture and novel magnetic materials. The proposed project is an example of applied research that utilises a frontier technology (superconductors) in an application with both national and community benefits. Fault current limiters are designed to protect electricity grids. The integration of superconductors in fault current limiting applications allows for this protection to be achieved in an energy efficient manner, since negligible impedance is applied to the network during the un-faulted state. Effective and efficient protection of the electricity network is of national interest, with any failure affecting industry and individuals. The proposed research team is in a leading position to develop the potential of this technology for both national networks and a world market.Read moreRead less
Development of Magnesium Diboride Superconductor Wires with High Upper Critical Field for MRI Applications. The aim of the program is to demonstrate the superconducting magnesium diboride (MgB2) wires with improved upper critical field (Hc2,) appropriate for large-scale applications. The basic idea will be based on the two-gap superconductivity to add well-distributed impurities which will act as scatterers, increasing resistivity, and thus Hc2. The core innovation of this proposal is based on t ....Development of Magnesium Diboride Superconductor Wires with High Upper Critical Field for MRI Applications. The aim of the program is to demonstrate the superconducting magnesium diboride (MgB2) wires with improved upper critical field (Hc2,) appropriate for large-scale applications. The basic idea will be based on the two-gap superconductivity to add well-distributed impurities which will act as scatterers, increasing resistivity, and thus Hc2. The core innovation of this proposal is based on the recent breakthrough in MgB2 that was made by the CIs through nano-SiC particle doping, which achieved a record high Hc2 in bulk form and enhancement of critical current density, Jc, in magnetic fields by an order of magnitude. The expected outcome is the development of superconducting MgB2 wires and coils with high Hc2 and Jc for MRI applications.Read moreRead less
Mechanism and enhancement of supercurrent carrying ability in magnesium diboride superconductor. The newly discovered MgB2 superconductor has great potential to replace the existing conventional superconductors for uses in various medical and industrial applications. This project brings together two world leading groups with complementary expertise to develop a fundamental understanding of the factors controlling MgB2 performance and to find effective ways to significantly improve its supercurre ....Mechanism and enhancement of supercurrent carrying ability in magnesium diboride superconductor. The newly discovered MgB2 superconductor has great potential to replace the existing conventional superconductors for uses in various medical and industrial applications. This project brings together two world leading groups with complementary expertise to develop a fundamental understanding of the factors controlling MgB2 performance and to find effective ways to significantly improve its supercurrent carrying capabilities for practical applications. The outcome of this project will be of benefit to both countries and will lead to many practical applications such as transformers, rotors, and transmission cables, as well as magnetic resonance imaging without using liquid helium, reducing greenhouse gas emissions and global warming. Read moreRead less
Magnesium diboride superconductor magnets for applications. The proposed development of magnesium diboride magnets is one of the core technologies that underlie applications in magnetic resonance imaging, magnetic separators, and other devices. The proposed international research consortium is in a leading position to explore the potential of these superconductor magnets for various applications. A breakthrough in the current proposal will lead to widespread commercial activities in a number of ....Magnesium diboride superconductor magnets for applications. The proposed development of magnesium diboride magnets is one of the core technologies that underlie applications in magnetic resonance imaging, magnetic separators, and other devices. The proposed international research consortium is in a leading position to explore the potential of these superconductor magnets for various applications. A breakthrough in the current proposal will lead to widespread commercial activities in a number of industry sectors: mineral separation, health, electric power, transportation, water purification, drug delivery, and space/aviation. Application of the proposal's outcomes will lead to enormous energy savings and environmental benefits. Read moreRead less