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
Improving optical data storage and micromachining technology through better modelling and characterisation of their laser beams. The laser sources generally do not have simple (Gaussian) distributions. The applicant has recently developed a model, describing free propagation of complex (non-Gaussian) laser beams. This project seeks to develop a comprehending model for laser beams propagation through complex optical systems. The effects of various optical elements will be defined employing a no ....Improving optical data storage and micromachining technology through better modelling and characterisation of their laser beams. The laser sources generally do not have simple (Gaussian) distributions. The applicant has recently developed a model, describing free propagation of complex (non-Gaussian) laser beams. This project seeks to develop a comprehending model for laser beams propagation through complex optical systems. The effects of various optical elements will be defined employing a novel method known as SAFE (Stable Aggregate of Flexible Elements) which is a compromise between geometrical and physical optics. Applying this model to micromachining and optical data storage (ODS), which need high beam quality (low divergence and good focussibility), enable accurate predictive capability critical to the optimisation of micromachining and ODS designs.Read moreRead less
Light-matter interactions in microstructured optical waveguides for nonlinear optical signal processing. The challenge of conceiving and constructing the necessary components and devices for the next generation of lightwave telecommunications systems is a profound one. This issue is urgent as the current operating principles of switches, filters and sources and other devices simply do not allow for the upgrade to the extremely high data transmission speeds that will be required. Using glass opti ....Light-matter interactions in microstructured optical waveguides for nonlinear optical signal processing. The challenge of conceiving and constructing the necessary components and devices for the next generation of lightwave telecommunications systems is a profound one. This issue is urgent as the current operating principles of switches, filters and sources and other devices simply do not allow for the upgrade to the extremely high data transmission speeds that will be required. Using glass optical fibres as the starting point, we will devise, demonstrate and analyze these novel components, leveraging microstructured optical fibre technology and novel fabrication techniques, which are among the most recent developments in optical fibre research.
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Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity ....Centre for Ultrahigh-bandwidth Devices for Optical Systems. The Centre, through a ground-breaking research program, will in the next five years invent and develop a set of revolutionary optical devices and will integrate these devices onto a photonic chip, for the use in the next generation of ultra-high bandwidth optical telecommunications systems. These systems will dramatically improve online services to the Australian community in key areas such as health, education and business connectivity. Australia's high tech industry will benefit from the commercialisation opportunities arising from the Centre's research, and also from the creation of a pool of highly skilled ICT professionals.Read moreRead less
Generalized imaging systems incorporating hybrid hardware-software optics. Fundamental optics research underpins the commercial optical technologies of tomorrow. Modern examples of such evolution, from the fundamental to the commercial, include lasers, LED traffic lights, thin-screen computer monitors and digital cameras. The recent advent of accessible powerful computers, together with recent advances in optical physics, promise a powerful merging of computing and optical technologies into so ....Generalized imaging systems incorporating hybrid hardware-software optics. Fundamental optics research underpins the commercial optical technologies of tomorrow. Modern examples of such evolution, from the fundamental to the commercial, include lasers, LED traffic lights, thin-screen computer monitors and digital cameras. The recent advent of accessible powerful computers, together with recent advances in optical physics, promise a powerful merging of computing and optical technologies into so-called virtual optical systems in which the computer processes optical information in a manner very similar to lenses. In particular, the computer may be used to decode distorted images provided by an imperfect imaging system. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0347499
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the ....Development of a High Performance Computing Cluster for ac3 Research. This application proposes the development of a 350 Gflop Beowulf parallel computing cluster that will support high profile research of international significance, spanning the science and technology spectrum, and according with national priority areas identified by Government and the ARC. The facility will provide an urgently needed boost in both aggregate and peak HPC capacity in NSW, thereby facilitating the solution of the next generation of computational research problems. In doing so, it will underpin innovation by world ranking groups in diverse fields such as photonics, complex/intelligent systems, nanotechnology, bioinformatics, quantum physics and chemistry, engineering, and environmental modelling.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
Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transfor ....Optical and matter-wave vortices in nonlinear and inhomogeneous media. Wave phenomena of diverse nature have a strikingly similar feature of vorticity, with the energy or matter spiralling around isolated phase singularities. This project targets the fundamental theoretical research in an interdisciplinary field of singular waves transporting vortices in nonlinear and inhomogeneous media. Our project will contribute to the designated priority area "Frontier Technologies for Building and Transforming Australian Industries" by providing fundamental understanding of novel physical phenomena and underpinning technological advances in the fields of photonics, atom, and electron optics, where Australia has built strong expertise and plays a significant role in the international development.Read moreRead less
Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include ....Moving-beam phase retrieval - a route to better microscopy! This research will benefit the nation by improving the quality of x-ray diffraction and electron microscopy techniques available to Australian scientists. It will make it possible to examine microscopic structures in more detail and therefore gain more information about the atomic positions in these structures. This will greatly benefit research that depends on finding the structure of very small objects. Such research areas include nanomaterials, biological engineering, medical science and materials science. The work is also expected to have industrial applications and to make an important contribution to the development of the synchrotron science industry in Australia.Read moreRead less
Frozen linear and nonlinear light. Frozen light refers to the observation that light inside particular media can be much brighter than outside it, essentially because it bounced around many times before leaving. Such light has many advantages which have applications in optical signal processing, lasers, and in other optical devices. Until now frozen light has only been studied in a small range of geometries and only at low intensities. In this fundamental research project we will investigate fr ....Frozen linear and nonlinear light. Frozen light refers to the observation that light inside particular media can be much brighter than outside it, essentially because it bounced around many times before leaving. Such light has many advantages which have applications in optical signal processing, lasers, and in other optical devices. Until now frozen light has only been studied in a small range of geometries and only at low intensities. In this fundamental research project we will investigate frozen light, its generation and its properties at low and high intensities, systematically, and we will assess how it can be harnessed for potential applications.Read moreRead less