Solar Nano-photocatalytic Disinfection and Mineralization of Treated Wastewater from Sewage Treatment Plants. Reuse of the treated wastewater from sewage treatment plants (STPs) has become significantly important in Australia due to dwindling water resources. The poor quality of the wastewater has limited its use for agriculture and aquaculture. This project aims to develop a solar nano-photocatalytic tertiary wastewater treatment process for disinfection and mineralization of the treated waste ....Solar Nano-photocatalytic Disinfection and Mineralization of Treated Wastewater from Sewage Treatment Plants. Reuse of the treated wastewater from sewage treatment plants (STPs) has become significantly important in Australia due to dwindling water resources. The poor quality of the wastewater has limited its use for agriculture and aquaculture. This project aims to develop a solar nano-photocatalytic tertiary wastewater treatment process for disinfection and mineralization of the treated wastewater from STPs, making the wastewater suitable as a water resource. The newly developed nano-fibre catalysts and photocatalytic technology in the teatm will be used and further developed in this novel process. The research will focus on the water quality objectives in terms of technical reliability, and economic and environmental sustainability.Read moreRead less
Controlling nano-carbon complexity and function. The project aims to develop versatile continuous flow thin film microfluidic device technology incorporating different external fields, including innovative magnetic or electric fields coupled with pulsed lasers, for gaining access to novel nano-carbon material for which current methods are ineffective or of limited utility. The technology will allow exquisite control, with real time monitoring, on reforming of carbon into functional material with ....Controlling nano-carbon complexity and function. The project aims to develop versatile continuous flow thin film microfluidic device technology incorporating different external fields, including innovative magnetic or electric fields coupled with pulsed lasers, for gaining access to novel nano-carbon material for which current methods are ineffective or of limited utility. The technology will allow exquisite control, with real time monitoring, on reforming of carbon into functional material with tunable properties, along with the self assembly of nano-carbon, and fabricating composites of nano-carbon material. Understanding their fundamental properties including photoluminescence will be targeted, for leveraging the properties in applications to generate new processes and products.
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Structural diverse nanocarbon using continuous flow thin film microfluidics. This project aims to develop continuous flow thin film microfluidic device technology to gain access to nano-carbon material or carbon nano-material. This project will exploit high shear stress in dynamic thin films, field effects, including Faraday waves, plasma, magnetic, laser and LED irradiation. The technology is expected to allow both scalable ‘top down’ synthesis of graphene scrolls, laterally slicing carbon nano ....Structural diverse nanocarbon using continuous flow thin film microfluidics. This project aims to develop continuous flow thin film microfluidic device technology to gain access to nano-carbon material or carbon nano-material. This project will exploit high shear stress in dynamic thin films, field effects, including Faraday waves, plasma, magnetic, laser and LED irradiation. The technology is expected to allow both scalable ‘top down’ synthesis of graphene scrolls, laterally slicing carbon nanotubes and composites of different types of carbon, and ‘bottom up’ synthesis of nano-carbon from natural saccharides. By incorporating sustainability metrics including scalability, renewable feed-stocks and minimising waste, this research is expected to be attractive to industry and minimise the effect on the environment.Read moreRead less