Quantitative real-time imaging of high-temperature superconductors. This project will develop a robust technique for the quantitative real-time imaging of high-temperature superconductors. The image-analysis algorithm so obtained will be a virtual software lens, which is able to decode the information contained in data obtained by a well-established but hitherto qualitative imaging technique. We will transform this technique into one uniquely capable of obtaining two-dimensional movies of the ....Quantitative real-time imaging of high-temperature superconductors. This project will develop a robust technique for the quantitative real-time imaging of high-temperature superconductors. The image-analysis algorithm so obtained will be a virtual software lens, which is able to decode the information contained in data obtained by a well-established but hitherto qualitative imaging technique. We will transform this technique into one uniquely capable of obtaining two-dimensional movies of the current distributions, magnetic fields, and pinning defects in superconducting films. Such a quantitative characterization of these key superconductor parameters will be an important tool in the present global quest for room-temperature superconductivity.Read moreRead less
Preparation and analysis of amorphous GaN thin films. Researchers in New Zealand have developed novel processing techniques to prepare amorphous and partially crystalline gallium nitride thin films with potential application as green-blue-UV opto-electronic devices. However, characterization of the film structure using electron microscopy is essential to understand the relationship between processing conditions and opto-electronic properties. The aim of this project is to draw together specialis ....Preparation and analysis of amorphous GaN thin films. Researchers in New Zealand have developed novel processing techniques to prepare amorphous and partially crystalline gallium nitride thin films with potential application as green-blue-UV opto-electronic devices. However, characterization of the film structure using electron microscopy is essential to understand the relationship between processing conditions and opto-electronic properties. The aim of this project is to draw together specialist expertise and equipment that allows integration of microscopy into the development of these films. Australian researchers will gain access to specialized preparation and testing facilities in New Zealand, whilst researchers from New Zealand will perform structural analysis of these films in Australia.Read moreRead less
Engineering and control of metamaterials with negative refraction. This project will extend significantly the research activity on metamaterials in Australia, promoting this new field and aiming to solve high priority problems and paving the way to creation of practical sub-wavelength devices. This project is therefore of national benefit for its advances in critical fundamental research and for potential applications in a large number of engineering tasks in microwave and optical devices. The p ....Engineering and control of metamaterials with negative refraction. This project will extend significantly the research activity on metamaterials in Australia, promoting this new field and aiming to solve high priority problems and paving the way to creation of practical sub-wavelength devices. This project is therefore of national benefit for its advances in critical fundamental research and for potential applications in a large number of engineering tasks in microwave and optical devices. The project will initialize collaboration with world leading experts in the area, bringing important expertise to Australia. It will provide a greater acceptance of Australia as a major world player in fundamental research.Read moreRead less
Nonlinear metamaterials and transformation optics. This research program will bring Australia to the forefront of international research in the exciting area of nonlinear metamaterials. It will provide high-level training for students in breakthrough science directions, and contribute to the uptake of frontier technologies by Australian industries for successful operation in a competitive global environment. This project will introduce and demonstrate novel concepts for dynamically controlling a ....Nonlinear metamaterials and transformation optics. This research program will bring Australia to the forefront of international research in the exciting area of nonlinear metamaterials. It will provide high-level training for students in breakthrough science directions, and contribute to the uptake of frontier technologies by Australian industries for successful operation in a competitive global environment. This project will introduce and demonstrate novel concepts for dynamically controlling and manipulating the properties of new type of materials. This research should bridge a gap between the study of metamaterials as a theoretical curiosity and their advanced applications. Our developments will underpin future developments in imaging systems and security. Read moreRead less
Single atom defined nanostructures: atom-electronics beyond the miniaturization limit. The emerging era of atom-electronics promises to revolutionise microelectronics in the 21st century by going beyond the conventional miniaturization limit of microelectronics. Emerging atom level fabrication and control techniques offer the promise of building devices whose fundamental components are built atom-by-atom and function under completely new rules. This Discovery Project will apply critical new theo ....Single atom defined nanostructures: atom-electronics beyond the miniaturization limit. The emerging era of atom-electronics promises to revolutionise microelectronics in the 21st century by going beyond the conventional miniaturization limit of microelectronics. Emerging atom level fabrication and control techniques offer the promise of building devices whose fundamental components are built atom-by-atom and function under completely new rules. This Discovery Project will apply critical new theoretical tools, in partnership with leading experimental groups, to enable the exploration of this technology and the creation of new and innovative applications which will have far reaching implications in all areas of society and significant national benefit.Read moreRead less
Quantum coherence of electronic transport in layered magnetoresistive materials. The continued rapid expansion of information technology requires new materials and devices for information storage. State of the art computer memories are based on new materials which consist of layers of complex arrays of atoms. These materials have metallic properties quite unlike those of simple metals such as copper and steel. This research will lead to a greater understanding of and ability to design better ma ....Quantum coherence of electronic transport in layered magnetoresistive materials. The continued rapid expansion of information technology requires new materials and devices for information storage. State of the art computer memories are based on new materials which consist of layers of complex arrays of atoms. These materials have metallic properties quite unlike those of simple metals such as copper and steel. This research will lead to a greater understanding of and ability to design better materials. Australia's capacity for research and development in this scientifically challenging and technologically important field will be enhanced by this project. Read moreRead less
Proximity effects and new correlated phases in closely spaced quantum electronic devices. The aim of this project is to understand the interactions between quantum electronic devices when they are brought into close proximity. A detailed knowledge of these interactions and how to control them is important both for conintued miniaturisation in the semiconductor industry, and for the fundamental understanding of new quantum ground states. To achieve these goals new coupled device designs will be e ....Proximity effects and new correlated phases in closely spaced quantum electronic devices. The aim of this project is to understand the interactions between quantum electronic devices when they are brought into close proximity. A detailed knowledge of these interactions and how to control them is important both for conintued miniaturisation in the semiconductor industry, and for the fundamental understanding of new quantum ground states. To achieve these goals new coupled device designs will be engineered in collaboration with NTT's Basic Research Laboratories in Japan. Theses novel devices will be used to study fundamental correlations in quantum semiconductor systems, with the possibility of forming new correlated states of matter such as electron-hole superfluids.Read moreRead less
Electronics with spin: Investigating spin-dependent electrical properties of semiconductor nano-devices. Devices such as the integrated circuit and semiconductor lasers are products of basic research, and form the basis of new industries that have revolutionised society. Quantum physics was the science of the 20th century and is likely to become a key technology of the 21st century. This project will keep Australia at the forefront of the search for new and potentially commercially useful applic ....Electronics with spin: Investigating spin-dependent electrical properties of semiconductor nano-devices. Devices such as the integrated circuit and semiconductor lasers are products of basic research, and form the basis of new industries that have revolutionised society. Quantum physics was the science of the 20th century and is likely to become a key technology of the 21st century. This project will keep Australia at the forefront of the search for new and potentially commercially useful applications of quantum physics. The project will also provide training for Australian students to work in a cutting-edge semiconductor research facility, and involves linkages with leading international laboratories including Massey University (NZ), the University of Cambridge (UK), and NTT Basic Research Labs (Japan). Read moreRead less
Dual wavelength quantum dot light detectors. This project aims to develop technologies to fabricate advanced electronic materials based on gallium antimonide (GaSb), to explore their physics and use them in improved optoelectronic devices.
GaSb technology is in its infancy, therefore basic and applied research is needed to utilise these materials to their full potential for long wavelength photonic devices with unique promise in military and civilian applications: fire detection, missile and ....Dual wavelength quantum dot light detectors. This project aims to develop technologies to fabricate advanced electronic materials based on gallium antimonide (GaSb), to explore their physics and use them in improved optoelectronic devices.
GaSb technology is in its infancy, therefore basic and applied research is needed to utilise these materials to their full potential for long wavelength photonic devices with unique promise in military and civilian applications: fire detection, missile and surveillance systems, environmental monitoring, biology and medicine.
As an outcome, growth protocols for innovative device structures will be established, the structures' behaviour assessed and device fabrication and characterisation carried out and reported.
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New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combin ....New generation of hyperspectral infrared photon detectors. Although highly desirable for many applications, tuneable, on chip, infrared photon detectors are not yet available. The approach described in this application aims to develop a technology for high performance, on chip, infrared photon detectors that can be tuned over a wide wavelength range. By applying a novel in-house developed semiconductor process and a multi-disciplinary approach, this project aims to develop such devices by combining, for the first time, micromachined tuneable optical microcavities with high performance HgCdTe-based infrared detectors.Read moreRead less