New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray s ....New quantitative methods in X-ray imaging using crystal optics. This project will enhance Australian science's international leadership in the area of x-ray imaging. This powerful type of X-ray imaging, which makes use of optical elements made of perfect crystals, is specially tailored to image samples which are invisible to conventional x-ray techniques. Such "extended x-ray vision" is extremely important for imaging in medicine, biology and materials science. Furthermore, we will train x-ray scientists of tomorrow, whose expertise will allow Australia to capitalize on its investment in the Australian Synchrotron.Read moreRead less
Mechanical stresses in holey fibres. The development of holey fibres constitutes arguably the most exciting development in fibre optics in recent years. We will analyze the mechanical stresses in these fibres, which, together with the optical calculations and associated experiments, will allow us to design novel fibre-based devices. This will allow Nufern to develop new products based on holey fibres.
Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ul ....Harnessing opto-acoustic interactions for on-chip optical isolation. The project aims to develop practical on-chip photonic isolators – one-way optical circuits – by harnessing light–sound interactions in a nanoscale platform novel in its materials, design and mechanism. The project should develop new nanofabrication techniques and transform understanding of the physics of one-way photonic processes. Expected outcomes include enhanced design and fabrication capabilities for photonic circuits, ultra-compact, high-performance optical isolators and circulators that shield sensitive optical components, and a suite of theoretical tools for describing propagation and noise in these devices. These new high performance photonic circuits should benefit telecommunications, radar, defence, and sensing applications. Read moreRead less
Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The wor ....Liquid light: aqueous bio-sensing in microstructured polymer optical fibres. This project builds on Australia's world-leading position in the development of microstructured polymer optical fibres, and applies the unique benefits they provide to for ultra- sensitive bio-sensing. By using the microstructure to simultaneously confine light and liquid, microstructured optical fibres provide a unique platform for ultra-sensitive spectroscopy and structural studies of biomolecules in solution. The work has profound implications both for fundamental science and applications, particularly in medical diagnostics.Read moreRead less
Stimulating light scattering in periodic structures: How slow can it go? Proof-of-concept experiments have already proven that it is possible to reduce and control the speed of light within the laboratory. This fundamental change in our understanding of light properties generated a frenzy of scientific interest and we now have a basic understanding of the physical processes involved in slowing light. What we do not have, however, is a method of doing so that can be harnessed into useful applic ....Stimulating light scattering in periodic structures: How slow can it go? Proof-of-concept experiments have already proven that it is possible to reduce and control the speed of light within the laboratory. This fundamental change in our understanding of light properties generated a frenzy of scientific interest and we now have a basic understanding of the physical processes involved in slowing light. What we do not have, however, is a method of doing so that can be harnessed into useful applications outside of the lab. Our proposed approach offers a low power solution that can be readily incorporated into a myriad of engineered devices.Read moreRead less
Beyond metamaterials: new composites for transforming photonics. Composites containing metamaterials, new materials with extraordinary electromagnetic properties, are opening new horizons in optical physics, with the potential to deliver a range of unprecedented functionalities. This project will clarify the exotic physics of these revolutionary new materials, leading to new photonics applications.
Low threshold photonic crystal microlasers. The aims of this project are to develop detailed finite-difference time-domain numerical models of active photonic crystal structures, and to use them to optimise the design and performance of photonic-crystal-based devices, especially micro-cavity lasers. Photonic crystal microlasers have the potential to provide very efficient and low noise laser sources in micron-sized cavities, however the simplistic structures used to realise these lasers to date ....Low threshold photonic crystal microlasers. The aims of this project are to develop detailed finite-difference time-domain numerical models of active photonic crystal structures, and to use them to optimise the design and performance of photonic-crystal-based devices, especially micro-cavity lasers. Photonic crystal microlasers have the potential to provide very efficient and low noise laser sources in micron-sized cavities, however the simplistic structures used to realise these lasers to date provide sub-optimal performance. Innovative designs with improved performance will be developed by tailoring both the optical and thermal properties of planar photonic crystal stuctures. Devices designed during this project will subsequently be fabricated at facilities in France.Read moreRead less
Photonic Crystal Quantum Dot Lasers. Nanotechnology is expected to make a major impact in all industry sectors. This research has the potential to develop patentable technologies of interest to Australian industries in the fields of computers, communications, defence, environmental and medical sensing. This project will enhance Australia's international links with UK, France, Canada, Korea and USA and allow us to train skilled personnel essential for the development of high tech industries in ....Photonic Crystal Quantum Dot Lasers. Nanotechnology is expected to make a major impact in all industry sectors. This research has the potential to develop patentable technologies of interest to Australian industries in the fields of computers, communications, defence, environmental and medical sensing. This project will enhance Australia's international links with UK, France, Canada, Korea and USA and allow us to train skilled personnel essential for the development of high tech industries in Australia. Read moreRead less
Light-Matter Interactions In Nanoparticle-doped Microstructured Polymer Fibres. Microstructured optical fibres have been defined as the 'next generation' of optical fibres. This proposal offers the opportunity to make major advances in this dynamic new area, not only changing the fibre properties by means of its microstructured but also by its material properties. The proposed research will enable us to fabricate new types of optical fibre by exploiting three completely different technologies: p ....Light-Matter Interactions In Nanoparticle-doped Microstructured Polymer Fibres. Microstructured optical fibres have been defined as the 'next generation' of optical fibres. This proposal offers the opportunity to make major advances in this dynamic new area, not only changing the fibre properties by means of its microstructured but also by its material properties. The proposed research will enable us to fabricate new types of optical fibre by exploiting three completely different technologies: polymer materials, microstructured polymer fibres (mPOF) and nanoparticles. This project will build on our existing success in developing mPOF, and create major new opportunities, both in fundamental science and in applications that could and would be commercialised.Read moreRead less
Enabling next-generation high-efficiency visible laser sources through advanced waveguide engineering. Lithium niobate has the potential to become the silicon of the optoelectronic industry. In order to realise its potential, fundamental problems associated with long term stability and cost of integration need to be solved. This project will develop a new hybrid fabrication platform that circumvents the traditional approaches pursued in the past for introducing waveguides into a lithium niobate ....Enabling next-generation high-efficiency visible laser sources through advanced waveguide engineering. Lithium niobate has the potential to become the silicon of the optoelectronic industry. In order to realise its potential, fundamental problems associated with long term stability and cost of integration need to be solved. This project will develop a new hybrid fabrication platform that circumvents the traditional approaches pursued in the past for introducing waveguides into a lithium niobate chip. This platform will enable the production of robust, low cost light sources for fields as diverse as biotechnology, environmental sensing and displays. This project will lead to new IP that will establish Australia as a leader in this field.Read moreRead less