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
Australian Laureate Fellowships - Grant ID: FL0992016
Funder
Australian Research Council
Funding Amount
$2,064,351.00
Summary
Frontiers of Precision Time and Frequency. Devices for precise frequency and time metrology invented at the University of Western Australia have application in telecommunications, advanced radar, optical to microwave links, frequency and time standards, astronomy, tests of fundamental physics and have attracted worldwide interest. This project will strengthen Australian "know how" and expertise, and place us in a position to participate in current and future space missions. Moreover, this repres ....Frontiers of Precision Time and Frequency. Devices for precise frequency and time metrology invented at the University of Western Australia have application in telecommunications, advanced radar, optical to microwave links, frequency and time standards, astronomy, tests of fundamental physics and have attracted worldwide interest. This project will strengthen Australian "know how" and expertise, and place us in a position to participate in current and future space missions. Moreover, this represents an opportunity for high profile involvement as the only southern hemisphere user of the most accurate space clock ever developed, which will likely involve the order of 30 institutes worldwide. This work necessarily includes collaboration with the world's elite metrological institutes.Read moreRead less
Nano-Engineering of Optical Fibre Fresnel Lenses. It is expected that the development of the Fresnel Lens Fibre will greatly enhance the simplicity with which fibres can be integrated into a variety of systems. An intrinsically focussing fibre will be cheap to produce and have significant size advantages over its competitors, thus giving it an excellent competitive advantage in the market place. Australia is home to a number of companies that would directly benefit from the commercialisation of ....Nano-Engineering of Optical Fibre Fresnel Lenses. It is expected that the development of the Fresnel Lens Fibre will greatly enhance the simplicity with which fibres can be integrated into a variety of systems. An intrinsically focussing fibre will be cheap to produce and have significant size advantages over its competitors, thus giving it an excellent competitive advantage in the market place. Australia is home to a number of companies that would directly benefit from the commercialisation of a Fresnel Lens Fibre. In addition to a range of possible telecommunications applications, the focussing fibre also has applications in spectroscopy, minimally invasive surgical procedures, and especially in the field of photodynamic therapy. Read moreRead less
Characterisation and fabrication of nanophotonic devices based on multi-layer stacks. The aim of this proposal is to continue the existing collaborative project on fabrication and characterisation of nanophotonic devices based on the multi-layer stack method. The project will integrate the state-of-the-art techniques in the respective collaborating universities to fabricate a nano-probe which can produce an evanescent field approximately four orders of magnitude stronger than that under the conv ....Characterisation and fabrication of nanophotonic devices based on multi-layer stacks. The aim of this proposal is to continue the existing collaborative project on fabrication and characterisation of nanophotonic devices based on the multi-layer stack method. The project will integrate the state-of-the-art techniques in the respective collaborating universities to fabricate a nano-probe which can produce an evanescent field approximately four orders of magnitude stronger than that under the conventional condition. This novel probe provides a key to the successful fabrication of innovative nanophotonic devices including photonic transistors, photonic circuits, high-density data storage disks and drives, nano-motors and biochips, which underpin biotechnology, information technology and optical computing technology.Read moreRead less
Ultra-high density permanent and/or erasable optical memory in photorefractive media formed by ultrafast laser pulses. A possibility to form tree-dimensional 10Tb-density optical memory based on permanent modification, or damage, of transparent dielectrics, using powerful femtosecond laser pulses has already been demonstrated by the Applicants. This project aims to improve the fundamental understanding of ultrafast laser formation of nano-bits using unique ability of photorefractive materials t ....Ultra-high density permanent and/or erasable optical memory in photorefractive media formed by ultrafast laser pulses. A possibility to form tree-dimensional 10Tb-density optical memory based on permanent modification, or damage, of transparent dielectrics, using powerful femtosecond laser pulses has already been demonstrated by the Applicants. This project aims to improve the fundamental understanding of ultrafast laser formation of nano-bits using unique ability of photorefractive materials to reversible change and the refractive index. We aim to find ways for controlling the storage time, density and the writing-reading-erasing rate without inducing damage in the material. The results will be applied to efficient formation of high-speed, high density, write-read-erase 3D optical memory for applications in the information technology.
Read moreRead less
Developing New Clocks for Australia: Testing the Assumptions of Modern Physics. Clocks lie at the heart of all precise measurement devices; for example, they are the crucial elements in modern navigation and telecommunications systems. This project will develop three new clocks for Australia: a laser clock at the leading edge of technology, a novel and compact clock with commercial potential, and a microwave clock for use in the next generation of satellites. The performance advantage conferre ....Developing New Clocks for Australia: Testing the Assumptions of Modern Physics. Clocks lie at the heart of all precise measurement devices; for example, they are the crucial elements in modern navigation and telecommunications systems. This project will develop three new clocks for Australia: a laser clock at the leading edge of technology, a novel and compact clock with commercial potential, and a microwave clock for use in the next generation of satellites. The performance advantage conferred by our new devices can deliver economic benefits while also giving the possibility for scrutinizing the laws of physics for evidence that there is something beyond our present formulation.Read moreRead less
Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for fut ....Photonic routing with liquid crystals. Liquid crystals became a household item but their unequaled nonlocal optical properties are much less known and studied, although the breathtaking prospects of their future applications in photonics inspire many experts around the world. We will bring to Australia the state of the art research approach, theoretical and experimental, aiming to uncover and realize the potential of long range interaction between laser light and nonlocal liquid crystals for futuristic all-optical devices. This project will promote and enhance the rapid development of photonics in Australia, as well as deliver foremost practical expertise and outstanding training of young researchers.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
Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent ....Manipulation and Shaping of Light in the Far-Field using Advanced Fresnel Fibres. This project will focus on developing and understanding further the recent invention of the Fresnel fibre, which is designed to overcome diffraction from the end of an optical fibre. More sophisticated designs and combinations will allow arbitrary shaping of the optical field exiting an optical fibre for numerous applications. The physical basis for such phenomena to be realised is the efficient degree of coherent scattering possible in air-material fibre such as air-silica photonic crystal fibres. In conjunction advanced characterisation techniques will be developed.Read moreRead less
Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote ....Tunable nonlinear photonic devices with liquid crystals. This project will help to initiate in Australia a systematic study of nonlinear properties of liquid crystals for applications in optical components. Taking the advantage of strong and tunable nonlinear response of liquid crystals and low threshold powers, it will analyse new opportunities for controllable light manipulation in nanoscale photonic devices, suggesting realistic designs for tunable photonic circuits. The project will promote this attractive field and will facilitate the emergence of novel technologies. It will also lead to important international collaborations and bring important new expertise to Australia, complementing the core research program of the ARC Centre of Excellence CUDOS.Read moreRead less