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
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
Electron Tomography of Electromagnetic Fields, Potentials and Sources. The proliferation of technologies incorporating magnetic materials with exquisitely fine structure demands precise characterization methods, which are able to keep pace with magnetic miniaturization. However, existing techniques are unable to directly image magnetic materials at high resolution in three dimensions. We will overcome this deficiency, by combining an exciting new methodology for the three-dimensional visualisati ....Electron Tomography of Electromagnetic Fields, Potentials and Sources. The proliferation of technologies incorporating magnetic materials with exquisitely fine structure demands precise characterization methods, which are able to keep pace with magnetic miniaturization. However, existing techniques are unable to directly image magnetic materials at high resolution in three dimensions. We will overcome this deficiency, by combining an exciting new methodology for the three-dimensional visualisation of electromagnetic fields, with the latest cutting-edge electron-microscopes, thereby facilitating advances in magnetic nano-manufacturing. The anticipated applications are vast, from patterned nanomagnets and magnetic proteins, through to semiconductors and superconductors.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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Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact w ....Optoelectronic properties of low-dimensional semiconductor systems and semiconductor nanostructures under terahertz free-electron laser radiation. The recent application of terahertz (THz) free-electron lasers (FELs) to scientific investigation into low-dimensional semiconductor systems and semiconductor nanostructures has opened up a new field of research in semiconductor optoelectronics. This project will conduct a joint experimental and theoretical study of how these novel systems interact with intense THz laser fields. Experimentally, we plan to use Beijing FELs in China to study optoelectronic properties in GaAs-and GaN based systems. Theoretically, we intend developing fundamental new approaches to theory of electron interactions with intense laser fields in semiconductors and relating theoretical results to experiments and experimental findings.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100069
Funder
Australian Research Council
Funding Amount
$370,000.00
Summary
Ultra-low temperature facility for optical experiments. Ultra-low temperature facility for optical experiments:
The project aims to establish a state-of-the-art facility to conduct optics and photonics experiments at ultra-low temperatures, by integrating an optical-access cryogen-free dilution refrigerator into an optics laboratory. Near absolute zero temperature, complex materials and engineered nanoscale devices exhibit striking quantum mechanical behaviour. Experimental access to photonics ....Ultra-low temperature facility for optical experiments. Ultra-low temperature facility for optical experiments:
The project aims to establish a state-of-the-art facility to conduct optics and photonics experiments at ultra-low temperatures, by integrating an optical-access cryogen-free dilution refrigerator into an optics laboratory. Near absolute zero temperature, complex materials and engineered nanoscale devices exhibit striking quantum mechanical behaviour. Experimental access to photonics at millikelvin temperatures would enable a coherent quantum-mechanical interface between spins, charges, phonons and photons. This unique facility may help in designing the next generation of information, communication and metrology devices, such as quantum computers, single-photon sources and detectors, and nanoscale quantum-enhanced sensors.Read moreRead less
Develoment of a quantum repeater. Quantum information processing is a powerful emerging technology that aims to fully exploit the properties of quantum mechanics to perform computations and securely transmit information. This project will develop an essential component for this technology that will enable for the first time the direct and reversible transfer of quantum information between solid-state quantum systems and light. Successful completion of this project will provide a route to fully s ....Develoment of a quantum repeater. Quantum information processing is a powerful emerging technology that aims to fully exploit the properties of quantum mechanics to perform computations and securely transmit information. This project will develop an essential component for this technology that will enable for the first time the direct and reversible transfer of quantum information between solid-state quantum systems and light. Successful completion of this project will provide a route to fully scalable quantum computing and long range quantum networks. This project will help secure Australia's leading role in this strategically important new generation technology.Read moreRead less
Ordered Semiconductor Nanostructures for Electronics and Photonics Applications. This research program aims to develop innovative concepts and technologies to manipulate atoms to control size, shape and position of nanostructures in order to control their electronic and optical properties. The research program will produce important innovations and advance Australian knowledge in electronics, photonics, communications and computer technologies. This research will allow Australia to become a si ....Ordered Semiconductor Nanostructures for Electronics and Photonics Applications. This research program aims to develop innovative concepts and technologies to manipulate atoms to control size, shape and position of nanostructures in order to control their electronic and optical properties. The research program will produce important innovations and advance Australian knowledge in electronics, photonics, communications and computer technologies. This research will allow Australia to become a significant player in nanotechnology and has the potential for the development of patentable technologies of immense interest for high technology industries.Read moreRead less
Electronic properties of diamondlike carbon for applications in planar optical waveguides. This project will explore new applications of diamondlike carbon in the area of integrated optics for telecommunications systems. Diamondlike carbon offers opportunities to create novel electro-optic devices owing to its high refractive index and its ability to be deposited directly onto silicon substrates. This project will conduct a thorough study of the electronic properties of diamondlike carbon depo ....Electronic properties of diamondlike carbon for applications in planar optical waveguides. This project will explore new applications of diamondlike carbon in the area of integrated optics for telecommunications systems. Diamondlike carbon offers opportunities to create novel electro-optic devices owing to its high refractive index and its ability to be deposited directly onto silicon substrates. This project will conduct a thorough study of the electronic properties of diamondlike carbon deposited by two techniques and develop potential niche applications in the $5 billion integrated optical telecommunications devices. The work will combine fundamental studies of thin film electronic properties with leading edge industry applications of technology and provide an excellent research training opportunity.Read moreRead less