Innovative Technology for At-Scene Forensic Analysis using Microfluidics and Chemiluminescence. The major outcome of this project will be innovative reagents and strategies optimised for the detection of priority analytes such as drugs, explosives and chemical warfare agents. These will utilise a new technology platform based upon laboratory on a chip/microfluidics to enable the development of analytical methodologies suitable for use at crime scenes.This programme of research falls within a Nat ....Innovative Technology for At-Scene Forensic Analysis using Microfluidics and Chemiluminescence. The major outcome of this project will be innovative reagents and strategies optimised for the detection of priority analytes such as drugs, explosives and chemical warfare agents. These will utilise a new technology platform based upon laboratory on a chip/microfluidics to enable the development of analytical methodologies suitable for use at crime scenes.This programme of research falls within a National Research Priority namely 'Protecting Australia from terrorism and crime'. Through our current forensic science research collaboration the outcomes will build significantly on Australia's existing strengths in rapid detection using new analytical technologies.Read moreRead less
Advanced micro analysis systems for environmental monitoring. Understanding of the behaviour of the nutrients controlling nuisance algae in water bodies is currently limited by the cost and logistics of collecting and analysing the large numbers of samples required.
This proposal describes the development and evaluation of portable multiparameter micro analysis systems that will be capable of high frequency measurements from a sampling vessel. This will enable environmental agencies to perfo ....Advanced micro analysis systems for environmental monitoring. Understanding of the behaviour of the nutrients controlling nuisance algae in water bodies is currently limited by the cost and logistics of collecting and analysing the large numbers of samples required.
This proposal describes the development and evaluation of portable multiparameter micro analysis systems that will be capable of high frequency measurements from a sampling vessel. This will enable environmental agencies to perform rapid on-site mapping of nutrients and other water quality parameters in large water bodies, intensive scale mapping of effluent mixing and dispersal zones, quick assessment of the impact of dredging and aquaculture, and compliance monitoring in effluent streams.
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An autonomous microfluidic analyser for the determination of total phosphorus and nitrogen in aquatic systems. Development of automated monitoring systems capable of extended and remote operation will enable assessment of the effectiveness of water treatment and the impact of nutrient releases on the aquatic environment. Both are important in preserving the quality of existing water resources, and assessing the quality of recycled water, in line with the National Research Priority Environmentall ....An autonomous microfluidic analyser for the determination of total phosphorus and nitrogen in aquatic systems. Development of automated monitoring systems capable of extended and remote operation will enable assessment of the effectiveness of water treatment and the impact of nutrient releases on the aquatic environment. Both are important in preserving the quality of existing water resources, and assessing the quality of recycled water, in line with the National Research Priority Environmentally sustainable Australia, and the Priority Goal, Water - a critical resource. Commercialization of the microfluidic flow analysis system for total N and P will enhance the international competitiveness of Ecotech Pty Ltd and Australia as an exporter of scientific instruments.Read moreRead less
The pollution potential of mercury in legacy biosolids and possibilities for its minimisation by phytoremediation and phytostabilisation approaches. This project will develop: (1) new chemical analysis techniques to study the mercury fate in legacy biosolids which will lead to better understanding of their potential environmental impact; (2) environmentally-benign phytoremediation approaches using native plants to reduce mercury release so the biosolids can be safely used for land applications.