Nanodiamond in glass: a new approach to nanosensing. This work will develop optical materials enriched with diamond nanoparticles. This will enable the magnetic field sensitivity of diamond nanoparticles to be combined with the capacity of micro/nanostructured optical fibres to enhance the interaction of light with matter. The outcome will be tools for probing biological processes on the nanoscale.
Manufacture of precision optical components: ground-breaking through innovative constitutive modeling. It has been a worldwide challenge to make high precision optical elements using glass moulding though it is the most effective process. This project aims to develop a novel way to optimise precision glass moulding processes. The success of this research will significantly reduce the development cost and improve the quality of the moulding products.
Understanding and optimising the microstructure of Germanium-Arsenic-Selenium glasses for superior device performance. The project will seek to use a combined theoretical and experimental approach to develop 'state of the art' optical glass materials for use in integrated nonlinear optical components. Such materials could be used as optical waveguides in broadband communication systems and offer the possibility of significant improvement in telecommunication performance.
Glass micro and nano smithing of devices and sensors for extreme environments. This application will elucidate, optimise and apply the art, science and technology of glass processing on a sub-micron scale to develop a range of optical fibre, waveguide and glass devices including sensors, lasers, two and three-dimensional components and masks for operation in harsh and extreme environments, particularly those operating above 1000 degrees celsius. A connection between changes in optical spectra, s ....Glass micro and nano smithing of devices and sensors for extreme environments. This application will elucidate, optimise and apply the art, science and technology of glass processing on a sub-micron scale to develop a range of optical fibre, waveguide and glass devices including sensors, lasers, two and three-dimensional components and masks for operation in harsh and extreme environments, particularly those operating above 1000 degrees celsius. A connection between changes in optical spectra, structural relaxation and viscous flow is used to optimise the thermal and optical resistance of glass technologies in the all-critical industrial 1000 to 1200 degrees celsius window. Fundamental and device studies will show that regeneration is the only current approach that will enable photonic technologies to operate in such harsh environments. Read moreRead less