Power scaling of remote plasma sources for gallium nitride film growth with real-time monitoring of activated nitrogen species. Domestic, industrial and community lighting currently accounts for ~20% of the world's overall energy consumption. Commonly used incandescent lights are based on inefficient, century-old technologies. In contrast, light emitting diodes (LEDs) use ~80% less energy and last ~100 times longer. LED deployment will bring substantial economic and environmental benefits for Au ....Power scaling of remote plasma sources for gallium nitride film growth with real-time monitoring of activated nitrogen species. Domestic, industrial and community lighting currently accounts for ~20% of the world's overall energy consumption. Commonly used incandescent lights are based on inefficient, century-old technologies. In contrast, light emitting diodes (LEDs) use ~80% less energy and last ~100 times longer. LED deployment will bring substantial economic and environmental benefits for Australia and globally. Next generation high-efficiency LEDs for lighting, will operate with reduced energy consumption, thus contributing to reaching future national targets for CO2 emission reduction. This project will achieve reduced production cost of a key LED material, and will support Australia's leadership in a growing global semiconductor manufacturing industry.Read moreRead less
New ultraviolet light sources for the disinfection of drinking water and re-cycled waste-water. The disinfection of municipal drinking-water supplies and treatment of waste-water by exposure to high-power ultraviolet (UV) light is now a practical alternative to chlorination. UV light can kill or sterilize the micro-organisms that pose a health hazard through highly selective photo-biological reactions that disrupt the microbial DNA. The aim of this project is to research and develop new 'germici ....New ultraviolet light sources for the disinfection of drinking water and re-cycled waste-water. The disinfection of municipal drinking-water supplies and treatment of waste-water by exposure to high-power ultraviolet (UV) light is now a practical alternative to chlorination. UV light can kill or sterilize the micro-organisms that pose a health hazard through highly selective photo-biological reactions that disrupt the microbial DNA. The aim of this project is to research and develop new 'germicidal' UV light sources based on Barrier Discharge lamps, operating in novel excitation regimes, to yield high UV efficiency. Successful demonstration of the technology will provide solutions to the growing economic and environmental challenges relating to water conservation within Australia. Read moreRead less