New experimental-analytical x-ray diffraction technique for unambiguous non-destructive characterization of high-performance silicon-germanium-carbon alloys for broadband communication devices. This research will develop a new x-ray diffraction technique for characterization of silicon-germanium-carbon semiconductor alloys. These are the basis for the new generation, ultra-high speed broadband telecommunication devices. The research will establish a new theoretical methodology for fundamental st ....New experimental-analytical x-ray diffraction technique for unambiguous non-destructive characterization of high-performance silicon-germanium-carbon alloys for broadband communication devices. This research will develop a new x-ray diffraction technique for characterization of silicon-germanium-carbon semiconductor alloys. These are the basis for the new generation, ultra-high speed broadband telecommunication devices. The research will establish a new theoretical methodology for fundamental studies of x-ray scattering phenomena in compound strain-compensated materials. The experiments will be carried out using the state-of-the-art laboratory and synchrotron radiation facilities in Australia, Japan and France. The project involves direct collaboration with IHP Germany, the world-leading semiconductor developer. Highly qualified postgraduate students will be extensively trained in modern synchrotron experiments, x-ray diffraction theory and semiconductor technology during the project.Read moreRead less
Novel High-Q Resonant Structures for Space and Telecommunications. High-Q microwave resonators with low spurious mode density have important applications in telecommunications, radar, navigation, precision metrology and time standards. We will develop high-Q resonators by constructing a dielectric Bragg resonators using monocrystalline sapphire loaded in a copper cavity with new cylindrical and spherical geometries. Based on these devices, compact and economical state-of-the-art ultra-low noise ....Novel High-Q Resonant Structures for Space and Telecommunications. High-Q microwave resonators with low spurious mode density have important applications in telecommunications, radar, navigation, precision metrology and time standards. We will develop high-Q resonators by constructing a dielectric Bragg resonators using monocrystalline sapphire loaded in a copper cavity with new cylindrical and spherical geometries. Based on these devices, compact and economical state-of-the-art ultra-low noise microwave oscillators and hydrogen masers will be built for the telecommunications market and space applications.Read moreRead less