Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical tel ....Miniaturised Adiabatic Light Processing Devices. The project will develop, model and analyse a range of miniaturised light-processing devices for optical communications applications that rely soley on their geometrical design for their optical functionality. Such devices are less complex than devices that rely on other physical phenomena for their operation, such as interference, resonance or grating phenomena. They have potential application to a wide range of applications including optical telecommunications, optical sensing and biophotonics. The major outcome will be a range of novel devices that are very compact, have very low optical power loss and process light signals in ways that either cannot be readily achieved by other approaches or are simpler than other approaches.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
Ultra-sensitivity through resonances in photonic bandgap fibres. The project will develop innovative biochemical sensors with extreme sensitivity using recently discovered physical processes in novel holey optical fibres. These sensors will be able to detect biological molecules, toxins or dangerous chemicals in minute concentrations, in very small sample sizes. The sensors can be mass-produced cheaply with current fabrication facilities within Australia, enabling their widespread use for water ....Ultra-sensitivity through resonances in photonic bandgap fibres. The project will develop innovative biochemical sensors with extreme sensitivity using recently discovered physical processes in novel holey optical fibres. These sensors will be able to detect biological molecules, toxins or dangerous chemicals in minute concentrations, in very small sample sizes. The sensors can be mass-produced cheaply with current fabrication facilities within Australia, enabling their widespread use for water quality monitoring, environmental monitoring, threat detection, and rapid and reliable diagnosis in medicine.Read moreRead less