Microfabrication of integrated silicon optical cross-switches interfaced with silica optical waveguides. Project aims to fabricate novel silicon based optical switches in the form of cantilevered mirrors integrated to interface with silica optical waveguides integrated collimation lens. Significantly, it paves the way for low cost integration of optical switches with array waveguides for an all-optical dynamically reconfigurable dense wavelength division multiplexing network used in modern broad ....Microfabrication of integrated silicon optical cross-switches interfaced with silica optical waveguides. Project aims to fabricate novel silicon based optical switches in the form of cantilevered mirrors integrated to interface with silica optical waveguides integrated collimation lens. Significantly, it paves the way for low cost integration of optical switches with array waveguides for an all-optical dynamically reconfigurable dense wavelength division multiplexing network used in modern broadband telecommunication systems. International market demand for such devises is enormous. Expected outcomes include the development of arrays of low loss 2x2 integrated optical waveguide cross-switches prototypes, securing the intellectual property rights and disseminating the work internationally.Read moreRead less
Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be ....Microfibre photonics: function densification on a wavelength scale. The project will contribute to Australia's nanoscale device research and nanomanufacturing development. The project will create microfibre fabrication technologies for the creation of new optical systems of miniature proportions that will be used for cell illumination, for the creation of sensors for detection in small environments and as light tools for fundamental experiments in physics. Specialist fabrication methods will be developed that will add to the nation's skill base. The outcomes of the project will enhance Australia's knowledge capacity, research capability and will contribute significantly to each of the National Research Priorities.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0346888
Funder
Australian Research Council
Funding Amount
$288,000.00
Summary
3-D Optical Surface Profiler. Establishing a state-of-the-science 3-D optical surface profiler will enable macroscopic, microscopic and nanoscopic profiling of surfaces over a very broad range of research programs including, laser cleaning and surface modification, laser precision microfabrication, surface, materials and device characterisation and optical physics applications. The importance and significance of these projects has already been established by the projects having competitive fundi ....3-D Optical Surface Profiler. Establishing a state-of-the-science 3-D optical surface profiler will enable macroscopic, microscopic and nanoscopic profiling of surfaces over a very broad range of research programs including, laser cleaning and surface modification, laser precision microfabrication, surface, materials and device characterisation and optical physics applications. The importance and significance of these projects has already been established by the projects having competitive funding. The instrument will undoubtedly support many additional research programs. It is similar to an Atomic-Force-Microscope or stylus profilometer but has significant additional capabilites. These include profiling much larger areas at sub-nanometre resolution and the non-contact nature of the technique. These features will enable surface characterisation that can not be achieved by other means.Read moreRead less
One Step Pre-forms for Microstructured Polymer Optical Fibre. The pre-form rods this project yields will enable polymer optical fibre technology, just as suitable glass pre-forms enabled today's optical fibre. One-step casting techniques will yield PMMA rods with arrays of internal channels which can be empty, or filled with different clear polymer. Polymer microstructured optical fibre (PMOF) suitable for high bandwidth communications is then produced by drawing. It is urgently needed for local ....One Step Pre-forms for Microstructured Polymer Optical Fibre. The pre-form rods this project yields will enable polymer optical fibre technology, just as suitable glass pre-forms enabled today's optical fibre. One-step casting techniques will yield PMMA rods with arrays of internal channels which can be empty, or filled with different clear polymer. Polymer microstructured optical fibre (PMOF) suitable for high bandwidth communications is then produced by drawing. It is urgently needed for local communication networks in cars and buildings. Solid PMOF channels are new to this project, and should make PMOF easier to deploy. Nanoscale mapping of light transport modes and polymer defects will help validate channel designs.Read moreRead less
Engineered optical fibre device structures for next generation telecommunication systems. The next generation of optical telecommunication networks requires novel photonic compnents that are superior to current devices, and cannot be obtained by incremental improvement. This project will identify novel device architectures and implement these in practical devices. This will ensure that Australia remains at the cutting edge of photonics research, one of the most dynamic and exciting ereas in sc ....Engineered optical fibre device structures for next generation telecommunication systems. The next generation of optical telecommunication networks requires novel photonic compnents that are superior to current devices, and cannot be obtained by incremental improvement. This project will identify novel device architectures and implement these in practical devices. This will ensure that Australia remains at the cutting edge of photonics research, one of the most dynamic and exciting ereas in science and engineering and at the basis of a multibillion dollar industry.Read moreRead less
Low energy all-optical logic gates with improved cascadability and fan-out for future optical communications and signal processing systems. All-optical logic processing is the key to overcoming electronic bottlenecks in high-speed communication networks as single-channel speeds exceed electronic capabilities. This research will build off and extend Australia's world leading specialty fibre and fibre device capabilities and place Australia at the forefront in the international all-optical digital ....Low energy all-optical logic gates with improved cascadability and fan-out for future optical communications and signal processing systems. All-optical logic processing is the key to overcoming electronic bottlenecks in high-speed communication networks as single-channel speeds exceed electronic capabilities. This research will build off and extend Australia's world leading specialty fibre and fibre device capabilities and place Australia at the forefront in the international all-optical digital information-processing race. High quality research publications will enhance Australia's strong research reputation in photonics and advanced materials and promote international collaboration. New optical processing capabilities will benefit other application areas such as sensing and security.Read moreRead less
Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturat ....Interferometric Distributed Feedback Fibre Laser Sensors. This project will solve important problems in realising next generation underwater optical fibre sensor systems for defence and marine exploration. OFTC's expertise in specialty optical fibre and devices will be combined with Thales' expertise in underwater sensor systems to give Australia a global lead. The benefits are commercial, national security and research standing. Domestic manufacture of a major optical system will assist maturation of the sector which is dominated by component companies. This system for underwater surveillance is obviously important to a country with a large coastline to defend. This project will build Australia's global reputation renowned for research excellence in fibre and fibre devices.Read moreRead less
Passively switched mid-infrared fibre lasers using saturable absorbers placed internally or externally to the geometry of the fibre. This project will create new pulsed mid-infrared fibre lasers based on original and recently developed passive switching techniques. An original class of fibre laser systems will be shown that is based on the internal placement of saturable absorbers within the optical fibre itself. A configuration such as this will enable the production of very simple pulsed laser ....Passively switched mid-infrared fibre lasers using saturable absorbers placed internally or externally to the geometry of the fibre. This project will create new pulsed mid-infrared fibre lasers based on original and recently developed passive switching techniques. An original class of fibre laser systems will be shown that is based on the internal placement of saturable absorbers within the optical fibre itself. A configuration such as this will enable the production of very simple pulsed laser systems of high efficiency and potentially high power. This will lead into the development of practical pulsed oscillator systems the output of which can be used directly or optically amplified for applications requiring high power.Read moreRead less
Silk Fibroin Optofluidic Chips. Unlike any other material, even any other biologically occurring material, silk is unique in being very transparent, able to be shaped on a very small scale and can keep natural chemicals like proteins and enzymes active. This project will use silk to make optical devices and sensors. Optics made from silk will have all these properties, which means that they can be used as sensors and devices in biochemistry applications that have never been possible before. Thes ....Silk Fibroin Optofluidic Chips. Unlike any other material, even any other biologically occurring material, silk is unique in being very transparent, able to be shaped on a very small scale and can keep natural chemicals like proteins and enzymes active. This project will use silk to make optical devices and sensors. Optics made from silk will have all these properties, which means that they can be used as sensors and devices in biochemistry applications that have never been possible before. These cost-effective devices will have the potential to enhance healthcare, emergency medicine and assist early medical diagnosis.Read moreRead less
The photonic immunochip: retrieving individual Enzyme-linked Immuno Sorbent Assay (ELISA) array-units using optical waveguide multicolour fluorescence. Improving the sensitivity and availability of in-vitro immuno-diagnostic tests is a critical goal towards developing real time efficient tools for the detection of infectious diseases, cancers, allergies and auto-immune diseases. The goal is to increase the sensitivity of these tests by reducing background noise that has been a feature of the com ....The photonic immunochip: retrieving individual Enzyme-linked Immuno Sorbent Assay (ELISA) array-units using optical waveguide multicolour fluorescence. Improving the sensitivity and availability of in-vitro immuno-diagnostic tests is a critical goal towards developing real time efficient tools for the detection of infectious diseases, cancers, allergies and auto-immune diseases. The goal is to increase the sensitivity of these tests by reducing background noise that has been a feature of the commonly used ELISA technology. This will be achieved by developing a novel optical integrated waveguide array supporting a large range of distributed tests, including several based on a novel multi-colour detection scheme. This massively parallel approach will underpin a new generation of low-cost, efficient diagnostic tests.Read moreRead less