Structure of Epitaxial Semiconductor Quantum Dots. Epitaxially grown semiconductor quantum dots have received extensive attention in recent years due to their potential applications in electronic and optoelectronic devises. However, the quality of current grown quantum dots is still very far from that required for real device applications due to a lack of detailed knowledge of their nanostructures. This project aims to combine the strength of growing semiconductor quantum dots at Fudan Universit ....Structure of Epitaxial Semiconductor Quantum Dots. Epitaxially grown semiconductor quantum dots have received extensive attention in recent years due to their potential applications in electronic and optoelectronic devises. However, the quality of current grown quantum dots is still very far from that required for real device applications due to a lack of detailed knowledge of their nanostructures. This project aims to combine the strength of growing semiconductor quantum dots at Fudan University and the world-class characterisation facilities (advanced transmission electron microscopy) at the University of Queensland to actively explore optimum paths for epaxially growing device-quality semiconductor quantum dots.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0453426
Funder
Australian Research Council
Funding Amount
$235,000.00
Summary
Access for Australian Researchers to Advanced Neutron Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australi ....Access for Australian Researchers to Advanced Neutron Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's partnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcomes will be new science that cannot be generated solely within Australia.
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Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882725
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
Access for Australian Researchers to Advanced Neutron Beam Techniques. The major national benefit will be access, by peer review, to the 35 specialised instruments at the world's leading pulsed Neutron and Muon source, ISIS. This complements the access to the eight neutron instruments that will operate at the Australian Reactor OPAL. This will support (or enable) high quality research into areas as diverse as materials development, mineral processing and aspects of biological and medical scien ....Access for Australian Researchers to Advanced Neutron Beam Techniques. The major national benefit will be access, by peer review, to the 35 specialised instruments at the world's leading pulsed Neutron and Muon source, ISIS. This complements the access to the eight neutron instruments that will operate at the Australian Reactor OPAL. This will support (or enable) high quality research into areas as diverse as materials development, mineral processing and aspects of biological and medical science. It will facilitate international collaborations that are important for both research and post-graduate student training.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668044
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Access for Australian Researchers to Advanced Neutron Beam Techniques. The access to ISIS is of strategic benefit to Australia. In the 'run up' to the Replacement Research Reactor that benefit will be increased because of the current upgrade to ISIS and the imminent construction of a second target station to provide the world's best 'cold neutron' facilities.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346812
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Access for Australian Researchers to Advanced Neutron-Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australi ....Access for Australian Researchers to Advanced Neutron-Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's partnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcomes will be new science that cannot be generated solely within Australia.
Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560721
Funder
Australian Research Council
Funding Amount
$240,000.00
Summary
Access for Australian Researchers to Advanced Neutron Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australi ....Access for Australian Researchers to Advanced Neutron Beam Techniques. Neutron scattering is one of the most powerful and important investigative tools in the study of materials. Australia has only a low-flux neutron source, HIFAR, which provides no cold or hot neutrons. This excludes large, important areas of science, such as functional films, polymers, self-assembly systems, biological materials, colloids and emulsions, and real-time in-situ studies.
This application aims to continue Australia's partnership with the world's most intense neutron source, ISIS in the UK, in order to sustain the considerable Australian scientific momentum which now relies on ISIS.
The outcomes will be new science that cannot be generated solely within Australia.
Read moreRead less
Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be disc ....Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be discovered and then incorporated into new microwave components and/or devices developed in response to the requirements of the international wireless telecommunications market. The requested PhD student will gain experience in both the industrial and academic worlds and the skills needed to be part of Australia's high-tech workforce. Read moreRead less
Computer Modelling of the Morphology and Crystallography of Diffusion-controlled Phase Transformations. An analytical, phenomenological version of the successful "edge-to edge" matching approach to the morphology and crystallography of diffusion-controlled phase transformations will be developed. This will be incorporated in a Windows based computer program that can predict the essential features of precipitation (orientation relationships, habit planes, morphology and interface structure), fro ....Computer Modelling of the Morphology and Crystallography of Diffusion-controlled Phase Transformations. An analytical, phenomenological version of the successful "edge-to edge" matching approach to the morphology and crystallography of diffusion-controlled phase transformations will be developed. This will be incorporated in a Windows based computer program that can predict the essential features of precipitation (orientation relationships, habit planes, morphology and interface structure), from readily available input data for the two phases involved. It will provide a fuller understanding of diffusion-controlled phase transformations and the computer simulation will assist in the development of improved precipitation hardening alloys. In addition, a database of crystallographic data for typical metallic materials will be established in the project.Read moreRead less
Naturally Photoactive Biopolymers. The basic aim of this project is to assess the viability of using semiconducting biopolymers from the melanin family of macromolecules in photoactive device based applications. In order to do this, key optical, structural, electronic, and photochemical properties will be assessed on thin films in the solid state. The melanins are the only known semiconducting biopolymers, and are non-toxic, biocompatible and biodegradable. Their use as ?active? materials in ....Naturally Photoactive Biopolymers. The basic aim of this project is to assess the viability of using semiconducting biopolymers from the melanin family of macromolecules in photoactive device based applications. In order to do this, key optical, structural, electronic, and photochemical properties will be assessed on thin films in the solid state. The melanins are the only known semiconducting biopolymers, and are non-toxic, biocompatible and biodegradable. Their use as ?active? materials in solid state or photo-electrochemical devices has never before been suggested. Specifically, these materials could be used as the light harvesting components in dye sensitised Gratzel cells, or, as the donor material in soft solid photovoltaic junctions. The melanins are also a key class of biomolecules (their involvement in skin cancers is well documented), and hence, any advancement in our understanding of their functions and properties could have biological importance.Read moreRead less
Advanced computational techniques for micro/nano multiscale systems of NEMS/BioMEMS. The outcome of this project will have the following benefits to Australia.
1) It will improve the research level in the area of multiscale simulation of NEMS/BioMEMS;
2) The project will be beneficial to possibly establish new industries in the areas of nanotechnology as well as to make good use of today's microelectronics, mircofabrication and computer technology that have already established in Australia;
....Advanced computational techniques for micro/nano multiscale systems of NEMS/BioMEMS. The outcome of this project will have the following benefits to Australia.
1) It will improve the research level in the area of multiscale simulation of NEMS/BioMEMS;
2) The project will be beneficial to possibly establish new industries in the areas of nanotechnology as well as to make good use of today's microelectronics, mircofabrication and computer technology that have already established in Australia;
3) The manpower trained by this project in the areas of multi-scale simulation of MEMS/NEMS/BioMEMS will provide a crucial support for the future industry of Australia.
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