Design and Creation of Nanomechanical Architectures from Folding of Ultrathin Bi-layer Films. The project will achieve progress in designing, modelling, analyzing, and characterization of nanomechanical architectures that will have broad application in Australian science and industry. If successful, our research will revolutionize nanofabrication technology and nano-design methods. The project will lead to a scientific understanding of atomic interaction and stress field effect in the formation ....Design and Creation of Nanomechanical Architectures from Folding of Ultrathin Bi-layer Films. The project will achieve progress in designing, modelling, analyzing, and characterization of nanomechanical architectures that will have broad application in Australian science and industry. If successful, our research will revolutionize nanofabrication technology and nano-design methods. The project will lead to a scientific understanding of atomic interaction and stress field effect in the formation of nanosystems. The result of this research will significantly lower fabrication costs and enhance the potential of nanomaterials in various areas such as electronics and bioelectronics, telecommunication, medical instrumentations, and pharmaceutical design. Read moreRead less
Separating Subtle Interplay between Competing/Cooperating Superconductivity and Magnetism in YBa2Cu3O7-x with Nanotechnology. Superconducting cables can carry 100 to 200 times more electric current than conventional cables. The innovations in this program could enable the widespread commercialization of more efficient types of power generation, transmission, and electrical equipment and devices, offering tremendous energy savings and emissions reductions. It is estimated that ~A$400 million pe ....Separating Subtle Interplay between Competing/Cooperating Superconductivity and Magnetism in YBa2Cu3O7-x with Nanotechnology. Superconducting cables can carry 100 to 200 times more electric current than conventional cables. The innovations in this program could enable the widespread commercialization of more efficient types of power generation, transmission, and electrical equipment and devices, offering tremendous energy savings and emissions reductions. It is estimated that ~A$400 million per year can be saved if high-Tc superconducting wires and cables were to replace conventional metallic conductors. The success of this program will greatly increase scientific understanding of hig-Tc superconductivity and expand Australia's knowledge in the research on high-Tc superconductors. The training will also provide scientific talents to the country.Read moreRead less
Tailoring superconducting hybrid multilayered film systems for electric and electronic applications. This project focuses on the development of new scientific and technological aspects of the fabrication, properties and operation of novel hybrid systems for revolutionizing electricity handling and electronics. It will also solve some existing problems of film structures with promising multilayer technology. Hybrid systems, often make the headlines in science and are gaining an increasingly promi ....Tailoring superconducting hybrid multilayered film systems for electric and electronic applications. This project focuses on the development of new scientific and technological aspects of the fabrication, properties and operation of novel hybrid systems for revolutionizing electricity handling and electronics. It will also solve some existing problems of film structures with promising multilayer technology. Hybrid systems, often make the headlines in science and are gaining an increasingly promising outlook in materials engineering, nanotechnology and electronics, promising eventual application in a broad range of industries. This project will establish Australia's capability at the forefront in this area. The outcomes predicted will benefit existing Australian companies and may establish new companies dealing with these hybrid systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668257
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
Combinatorial Deposition and Characterisation Facility for New Alloy Thin Film Materials. Australia's competitive edge in materials research is key to maintaining our economic prosperity. Infrastructure that enables our researchers to synthesize novel materials with precise control over composition and structure is crucial to maintaining our strengths in this field. The proposed infrastructure will accelerate progress on the preparation and characterisation of new alloy and nanostructured materi ....Combinatorial Deposition and Characterisation Facility for New Alloy Thin Film Materials. Australia's competitive edge in materials research is key to maintaining our economic prosperity. Infrastructure that enables our researchers to synthesize novel materials with precise control over composition and structure is crucial to maintaining our strengths in this field. The proposed infrastructure will accelerate progress on the preparation and characterisation of new alloy and nanostructured materials and will pay dividends by providing early access to the best materials. This will give our energy technology, biomedical engineering, tooling, electronics and mining industries a competitive edge. Access to this new generation equipment will enhance our pool of highly skilled materials technologists.Read moreRead less
Magnetic walls as nano-manipulators for physics, bio- and medical technologies. The focus of this project is the development of new scientific and technological aspects of nanomanipulators allowing not only the effective control of molecules and other magnetic quantities for a new approach in computation, but also the vital influence of biological processes at the molecular level. The outlook of this idea becomes increasingly promising in science and a broad range of industries (electronics, mat ....Magnetic walls as nano-manipulators for physics, bio- and medical technologies. The focus of this project is the development of new scientific and technological aspects of nanomanipulators allowing not only the effective control of molecules and other magnetic quantities for a new approach in computation, but also the vital influence of biological processes at the molecular level. The outlook of this idea becomes increasingly promising in science and a broad range of industries (electronics, materials engineering, nanotechnology and biotechnology). This project will establish Australia's capability at the forefront in this rapidly advancing area. The outcomes predicted may soon lead to the development of practical devices, where Australian science and industry may play one of the key roles.Read moreRead less
Development of high-temperature superconducting coated conductors by pulsed-laser deposition technique for future long-length applications. The aim of the project is to develop a novel technology for manufacturing flexible coated conductors with the help of a pulsed laser deposition technique, in order to enhance the current-carrying ability of high-temperature superconducting coatings (including multi-layered coatings) for future long-length high power applications. To achieve desirable electr ....Development of high-temperature superconducting coated conductors by pulsed-laser deposition technique for future long-length applications. The aim of the project is to develop a novel technology for manufacturing flexible coated conductors with the help of a pulsed laser deposition technique, in order to enhance the current-carrying ability of high-temperature superconducting coatings (including multi-layered coatings) for future long-length high power applications. To achieve desirable electromagnetic properties governed by the nano-structures of the coatings, a well-balanced combination of world-class "global" and "local" electromagnetic property measurements with advanced structural characterisations is suggested. It is expected that a controlled network of nano-scale pinning centres will allow the development of high performance coated conductors.Read moreRead less
UNSW-Harvard-Cambridge Partnership in Semiconductor Nanostructures for Quantum Computing and Quantum Science. Breakthrough nanotechnologies based on quantum mechanics promise important new devices with many applications in information and communications technologies. For example, quantum computers promise an enormous increase in computing power, allowing fast and complex processing in areas such as database searching, gene sequencing and weather modeling. This new collaboration brings together r ....UNSW-Harvard-Cambridge Partnership in Semiconductor Nanostructures for Quantum Computing and Quantum Science. Breakthrough nanotechnologies based on quantum mechanics promise important new devices with many applications in information and communications technologies. For example, quantum computers promise an enormous increase in computing power, allowing fast and complex processing in areas such as database searching, gene sequencing and weather modeling. This new collaboration brings together researchers from major national Centres in Australia (UNSW), Great Britain (University of Cambridge) and the USA (Harvard University) to tackle one of modern sciences most challenging problems - how to control and manipulate quantum states.Read moreRead less
Nanoclusters with Extraordinary Properties Made out of Ordinary Materials. Ultrafast laser deposition - a process pioneered by the Applicants - has already demonstrated record yields in the production of carbon-based nano-clustered materials with better control over the size of the nano-particles than any other process. This project aims to improve fundamental understanding of the ultra-fast laser deposition method of nano-fabrication through theoretical and experimental studies, which accurate ....Nanoclusters with Extraordinary Properties Made out of Ordinary Materials. Ultrafast laser deposition - a process pioneered by the Applicants - has already demonstrated record yields in the production of carbon-based nano-clustered materials with better control over the size of the nano-particles than any other process. This project aims to improve fundamental understanding of the ultra-fast laser deposition method of nano-fabrication through theoretical and experimental studies, which accurately correlate the ablation conditions to the structural, electronic, magnetic and optical properties of resulting nano-particles. The results will be applied to efficiently produce nano-clustered materials with tuneable properties for a wide range of new technologies such as spintronics, biophotonics, and nanoclinics.Read moreRead less
Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed ....Visualizing spin-related properties of functional nanostructures (for spintronics). This project contributes to undergraduate, postgraduate and postdoctoral research and training to encourage the pursuit of excellence, with:
- increased depth of knowledge in interdisciplinary research,
- a scientific environment providing access to research not otherwise in Australia,
- experience in the design, construction and development of scientific instruments.
Possible applications include high-speed magnetic filters, sensors, quantum transistors and spin qubits for quantum computers. The technological aspects of our project's outcomes offer real prospects of local development. The development of spin-polarized electron spectroscopy has great potential for existing applications in the surface science industry.
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