Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancemen ....Preparation of silica-based thin film materials with large optical nonlinearity. There is currently a lack of advanced thin film materials suitable for fabricating integrated electro-optic devices to use in optical telecommunication. Such materials will be produced, and their application will be developed through this project. The physical mechanism of the marvelous optical nonlinearities of the materials will also be investigated. Thus the achievement of this project will bring great advancement in both scientific knowledge and technologies for Australia, and provide huge opportunities to boost Australian telecommunication industries, which are developing quickly in recent years.Read moreRead less
Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activ ....Integrated magneto-optic waveguide materials and devices. We aim to develop chalcogenide glass films for fabricating integrated waveguide magneto-optic (MO) devices as a radical alternative to the use of crystalline MO materials that have proven difficult to manufacture in integrated form. Using our ultra-fast pulsed laser deposition (UFPLD) technique we will produce a wide range of chalcogenide glass compositions through combinatorial materials synthesis and assess them for magneto-optic activity. UFPLD will also be used to deposit high optical quality films for device prototyping. We will design and fabricate prototype MO components which are essential, but currently unavailable, for use as optical isolators in integrated optics.Read moreRead less
Defect-induced luminescence from ion-implanted silicon: Towards silicon photonics applications. This project focusses on advanced materials science, photonics and innovative silicon optical devices that have potential for contributing to information and communications technologies, areas where Australia has considerable expertise and investment. Specifically, national benefit will be derived from breakthroughs in fundamental science and intellectual property.
Hollow-core microstructured polymer fibres for optical sensing applications. A range of remarkable new optical fibres will be fabricated utilising the capabilities of a unique polymer fibre fabrication facility and focussing on the highly demanding class of microstructured fibres in which guidance in a hollow core is achieved through photonic band gap or Bragg guidance. Long lengths of low-loss fibres of this type will be developed, and applications in optical gas sensing, spectroscopy, voltage ....Hollow-core microstructured polymer fibres for optical sensing applications. A range of remarkable new optical fibres will be fabricated utilising the capabilities of a unique polymer fibre fabrication facility and focussing on the highly demanding class of microstructured fibres in which guidance in a hollow core is achieved through photonic band gap or Bragg guidance. Long lengths of low-loss fibres of this type will be developed, and applications in optical gas sensing, spectroscopy, voltage sensing and telecommunications will be explored.Read moreRead less
Microfluidic photonic systems. Australia is set to reap commercial benefits nationally and internationally from new developments in the highly competitive domain of microtechnology. In this project, a group of Australia's leading researchers propose an innovative combination of two exciting fields of scientific research. Microfluidics is the manipulation of minute quantities of liquids in microscopic channels, while photonics is the generation, transmission, detection and analysis of light as a ....Microfluidic photonic systems. Australia is set to reap commercial benefits nationally and internationally from new developments in the highly competitive domain of microtechnology. In this project, a group of Australia's leading researchers propose an innovative combination of two exciting fields of scientific research. Microfluidics is the manipulation of minute quantities of liquids in microscopic channels, while photonics is the generation, transmission, detection and analysis of light as a means to convey, collect and process information. The marriage of these two fields promises the development of novel, high performance tunable devices for sensing, biotechnology and telecommunications.Read moreRead less
An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will b ....An integrated approach towards the development of new generation RF/microwave dielectric materials. The ultimate aim of this project is to rationally design and optimize new types of environmentally-sustainable, cost-effective and high performance microwave dielectric materials and devices for advanced information and communication technology (ICT) applications. This is a designated National Research Priority area. Our fundamental understanding of dielectric materials and their properties will be enhanced considerably by working on this project. Further, we will promote the relationship between the fundamental science of polar crystalline materials and practical applications. If successful, the results will enhance Australia's capacity and standing in this highly competitive area. Read moreRead less