Synchrotron radiation techniques applied to melting and resolidification at a nanometric scale. By delivering underpinning knowledge of melting characteristics of nanoparticles, the proposal seeks results that can lead to breakthrough applications in advanced materials engineering. Measurements of the liquid nanoparticle structure performed at the Australian Synchrotron are unprecedented and are thus likely to include the development of new methodology. National and international exposure of Aus ....Synchrotron radiation techniques applied to melting and resolidification at a nanometric scale. By delivering underpinning knowledge of melting characteristics of nanoparticles, the proposal seeks results that can lead to breakthrough applications in advanced materials engineering. Measurements of the liquid nanoparticle structure performed at the Australian Synchrotron are unprecedented and are thus likely to include the development of new methodology. National and international exposure of Australian science and the Australian Synchrotron will have both scientific and economic ramifications. Involvement of students will contribute to developing the local synchrotron knowledge base and is beneficial to the Australian synchrotron-research community as a whole.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
Electron transport in semiconductor nanowire devices - Setting two top nanoelectronics problems on the straight and narrow. This project will establish a new program to build electronic devices using tiny semiconductor nanowires. This project will contribute strongly to Australia's ongoing efforts in semiconductor nanotechnology and quantum information science, and allow Australia to play a leading role in the development of the next generation of electronics technologies.
A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumptio ....A new generation flat screen: metasurface displays. This project aims to develop a new generation flat screen that is lighter, more efficient and with higher resolution by replacing the traditional liquid crystals (LCs) with metasurfaces that are 100-times thinner than LCs. Metasurfaces are arrays of engineered dielectric and semiconductor nanoparticles, with extraordinary characteristics. The expected outcomes will lead to flat screens with resolution enhanced by 100 times and energy consumption reduced by half, as compared to current LC-based displays (e.g. LCD and LED). This novel technology will revolutionise the dimension and performance of displays and secure Australia's position in the billion dollar market of flat displays.
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Building up quantum electronics with tailored semiconductor nanostructures. This project aims to develop nanoscale indium arsenide/ gallium antimonide (InAs/GaSb) devices produced ‘from the bottom up’ using three-dimensional templated semiconductor growth methods. This material has a pair of electron and hole layers separated by a few nanometres, which provide access to states of matter such as exciton condensates and topological insulators with potential use in quantum information technologies. ....Building up quantum electronics with tailored semiconductor nanostructures. This project aims to develop nanoscale indium arsenide/ gallium antimonide (InAs/GaSb) devices produced ‘from the bottom up’ using three-dimensional templated semiconductor growth methods. This material has a pair of electron and hole layers separated by a few nanometres, which provide access to states of matter such as exciton condensates and topological insulators with potential use in quantum information technologies. The project will use templates growth to create devices where the InAs/GaSb interface sits perpendicular to the device plane. This project’s work on growth, design and production of nanoscale devices will give Australia’s transitioning economy competitive advantage and agility in critical sectors of nanotechnology, quantum technologies and energy efficient devices.Read moreRead less
New carbon phases synthesized under extreme conditions. This project aims to address one of the major fundamental puzzles in carbon science; how to experimentally synthesize new phases of carbon predicted by theory. This could be approached via a combination of high pressure and high-energy ion irradiation to transform novel nano-carbon precursors. The expected outcomes include new phases of carbon with unexplored properties, an understanding of the pathways for synthesis of carbon materials, an ....New carbon phases synthesized under extreme conditions. This project aims to address one of the major fundamental puzzles in carbon science; how to experimentally synthesize new phases of carbon predicted by theory. This could be approached via a combination of high pressure and high-energy ion irradiation to transform novel nano-carbon precursors. The expected outcomes include new phases of carbon with unexplored properties, an understanding of the pathways for synthesis of carbon materials, and new computational tools to understand nano-carbon materials under extreme conditions. This should provide benefits for industries seeking advanced materials for modern manufacturing.Read moreRead less
Crystal-chemical tuning of order and disorder: a strategy for the discovery of novel solid state ionic conductors. The ultimate aim of this project is to discover novel ionic conductors suitable for use in energy technologies. By identifying, comprehensively characterising and optimising a number of such materials, this project will provide industry with the opportunity to implement them in new and improved devices.
Locally structured polar-photofunctional materials for energy conversion. This project aims to develop a novel method to engineer local chemical structures for achieving the polarity in narrow bandgap oxides via advanced thin-film growth and ion beam irradiation techniques. The developed new polar-photofunctional materials will significantly improve opto-electro-mechanical coupling and energy conversion, facilitating uses in renewable energy harvesting and smart optomechanical devices. The proje ....Locally structured polar-photofunctional materials for energy conversion. This project aims to develop a novel method to engineer local chemical structures for achieving the polarity in narrow bandgap oxides via advanced thin-film growth and ion beam irradiation techniques. The developed new polar-photofunctional materials will significantly improve opto-electro-mechanical coupling and energy conversion, facilitating uses in renewable energy harvesting and smart optomechanical devices. The project expects to advance material science through a new concept and innovative methodology, achieve properties forbidden/limited by conventional strategies and expand candidate pools for new generation multifunctional materials, significantly advancing Australia’s capacity in advanced manufacturing and industry.Read moreRead less
Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of t ....Built-in electric field, light co-driven materials for energy and sensing . This project aims to resolve critical, bottleneck issues in the development of photocatalysis and photoelectrochemistry - key technologies towards the realisation of a sustainable carbon-neutral society. This project expects to use an innovative strain-engineering approach establishing a built-in electric field within materials for highly efficient separation and transport of photoexcited carriers. Expected outcomes of this project are to create new, ground-breaking materials and/or nanosystems that overcome intrinsic weakness of conventional semiconductors and significantly improve their photocatalytic and photoelectrochemical performance, for the benefit of the utilisation of solar and light energy in energy, environment and health. Read moreRead less
New approach to control grain boundary behaviour in superconducting thin films. This project aims at finding a new approach to overcome the cornerstone problem of high temperature superconducting films through new design, magnetic interactions, and real-time magnetic flux visualisation at the quantum level. The expected ultimate achievement would be to develop new technologies, delivering the best performance of the films.