Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0214172
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
Measuring highly resolved flow and sound in Australia's largest wind tunnel. Monash and RMIT Universities have developed an aero-acoustic facility of international standing to study flows around vehicles, buildings and structures. This is based around the largest wind tunnel in the Southern Hemisphere, which provides a National facility crucial to the development of a competitive automotive industry. To achieve the next stage of research development, velocities and acoustic fields need to be mea ....Measuring highly resolved flow and sound in Australia's largest wind tunnel. Monash and RMIT Universities have developed an aero-acoustic facility of international standing to study flows around vehicles, buildings and structures. This is based around the largest wind tunnel in the Southern Hemisphere, which provides a National facility crucial to the development of a competitive automotive industry. To achieve the next stage of research development, velocities and acoustic fields need to be measured with increased accuracy and spatial resolution than currently available. Given the physical scale of the facility, it is proposed to achieve this with an automated measurement system, which will also be integral to future research programs.Read moreRead less
Understanding structure-property relations in amorphous silicon. The research is in a field of high national priority, namely nanotechnology and has a number of clear benefits for Australia. 1) Ensures Australia maintains its current position as a world leader in the fields of nanotechnology and material science; 2) Provides training to students in the exciting areas of synchrotron operation and nanotechnology. 3) Enables leverage for further funding from both companies and international funding ....Understanding structure-property relations in amorphous silicon. The research is in a field of high national priority, namely nanotechnology and has a number of clear benefits for Australia. 1) Ensures Australia maintains its current position as a world leader in the fields of nanotechnology and material science; 2) Provides training to students in the exciting areas of synchrotron operation and nanotechnology. 3) Enables leverage for further funding from both companies and international funding sources; and 4) Supports Australian industry by contributing to research which has resulted in the formation of a new company.Read moreRead less
Dopants, defects and related issues in Zinc Oxide. ZnO is a promising semiconductor for optoelectronic devices namely green, blue, ultraviolet (UV) and white light emitting diodes (LEDs) and ultimately UV lasers. It can also act as a transparent conductive oxide which has applications in flat panel displays and photovoltaic devices. Because of these potential applications, ZnO is the 'hottest' semiconductor with abounding literature and four new international conferences organised on progress in ....Dopants, defects and related issues in Zinc Oxide. ZnO is a promising semiconductor for optoelectronic devices namely green, blue, ultraviolet (UV) and white light emitting diodes (LEDs) and ultimately UV lasers. It can also act as a transparent conductive oxide which has applications in flat panel displays and photovoltaic devices. Because of these potential applications, ZnO is the 'hottest' semiconductor with abounding literature and four new international conferences organised on progress in this research area in recent years. This project is an excellent opportunity for Australia to increase its strength in optoelectronic device research and to provide an understanding of some fundamental issues in doping, defect formation, diffusion and annihilation in ZnO.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
Synthesis of novel microporous metallosilicate adsorbents. Nano-engineered materials will play an enormous role in the 21st century. As our understanding of the molecular structure of materials improves and our manipulation techniques develop, it will become possible to create materials that direct desirable reactions and separations with unprecedented yields and specificity. The proposed work aims to develop novel synthetic microporous metallosilicates using a variety of experimental approach ....Synthesis of novel microporous metallosilicate adsorbents. Nano-engineered materials will play an enormous role in the 21st century. As our understanding of the molecular structure of materials improves and our manipulation techniques develop, it will become possible to create materials that direct desirable reactions and separations with unprecedented yields and specificity. The proposed work aims to develop novel synthetic microporous metallosilicates using a variety of experimental approaches to nano-engineer superior adsorbents for gas separations. We expect the project to contribute to fundamental knowledge of creating tailor-made microporous adsorbents and lead to important fundamental and applied intellectual property for Australian industry.Read moreRead less
Mechanical deformation of layered semiconductor structures. This project aims to reveal the mechanisms of mechanical deformation in thin film layered semiconductors structures. Currently, there is little knowledge in this area despite the importance of such structures in electronic and optoelectronic devices. Layered structures are not expected to respond to mechanical stress in the same way as bulk materials, as a result of size constraints in nanoscale films, the critical importance of strai ....Mechanical deformation of layered semiconductor structures. This project aims to reveal the mechanisms of mechanical deformation in thin film layered semiconductors structures. Currently, there is little knowledge in this area despite the importance of such structures in electronic and optoelectronic devices. Layered structures are not expected to respond to mechanical stress in the same way as bulk materials, as a result of size constraints in nanoscale films, the critical importance of strain, and the possibility of disparities between the mechanical properties of the individual layers. The results of this project will dramatically enhance the understanding of the deformation responses of nanoscale structures to mechanical stress.Read moreRead less
Amorphisation of Semiconductor and Elemental Metallic Nanocrystals by Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. We seek to understand and develop a unique methodology for modifying and tailoring the structure of semiconductor and metallic nanocrystals in ways not achievable within the bulk phase. Our res ....Amorphisation of Semiconductor and Elemental Metallic Nanocrystals by Ion Irradiation. This proposal is consistent with Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries and Priority Goals: Breakthrough Science, Advanced Materials and Frontier Technologies. We seek to understand and develop a unique methodology for modifying and tailoring the structure of semiconductor and metallic nanocrystals in ways not achievable within the bulk phase. 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
Boron nitride nanotubes for tunable conductivity. The proposed research in nanotubes falls into the national research priority areas of advanced materials and breakthrough science. This ANU research group has a leading role in Boron Nitride (BN) nanotube research internationally. The proposed collaborative research will enhance this position and further improve the nation's research profile in nanotechnology. New intellectual properties will be generated if the project is successful, which wi ....Boron nitride nanotubes for tunable conductivity. The proposed research in nanotubes falls into the national research priority areas of advanced materials and breakthrough science. This ANU research group has a leading role in Boron Nitride (BN) nanotube research internationally. The proposed collaborative research will enhance this position and further improve the nation's research profile in nanotechnology. New intellectual properties will be generated if the project is successful, which will benefit the commercialization activity of BN nanotubes at ANU. New PhD and undergraduate students will be trained by the proposed cutting edge research project.Read moreRead less