Photoelectrocatalysis-based Techniques for Bactericidal Applications. Effective control of the quality of water supply is paramount for public health. This project aims to develop a novel photoelectrocatalysis (PEC) based bactericidal technology capable of instant inactivation and rapid decomposition of waterborne pathogens in recycled water. The PEC processes at the illuminated semiconductor photoanodes with ultraviolet (UV) and visible light activities will be innovatively utilised with the ai ....Photoelectrocatalysis-based Techniques for Bactericidal Applications. Effective control of the quality of water supply is paramount for public health. This project aims to develop a novel photoelectrocatalysis (PEC) based bactericidal technology capable of instant inactivation and rapid decomposition of waterborne pathogens in recycled water. The PEC processes at the illuminated semiconductor photoanodes with ultraviolet (UV) and visible light activities will be innovatively utilised with the aim of in-situ generation of stable di-halide radical anions, reactive oxygen species and photoholes as effectual bactericides to achieve instant inactivation and rapid decomposition of waterborne pathogens. The success of the project is expected to provide Australian water industry with enabling technology to safeguard recycled water usage.Read moreRead less
Surface modification of semiconducting organic charge transfer complexes with metal nanoparticles to create a new class of multifunctional materials. This project aims to deliver a facile and cheap method to produce a class of nanostructured composite materials to be used in applications which will have environmental and social benefits such as photocatalyst development for water purification, biosensing and the creation of antibacterial fabrics to prevent the spread of infection.
A highly sensitive and selective nano-engineered sensor for the online monitoring of mercury vapour emissions from harsh industrial processes. The Australian alumina and aluminium industries contribute over $11 billion export income annually. All refineries, except one, operate in rural areas and are the main economic drivers in these regions. In order to maintain the industry's commitment to reduce the environmental impact of its processes and remain economically sustainable, innovative technol ....A highly sensitive and selective nano-engineered sensor for the online monitoring of mercury vapour emissions from harsh industrial processes. The Australian alumina and aluminium industries contribute over $11 billion export income annually. All refineries, except one, operate in rural areas and are the main economic drivers in these regions. In order to maintain the industry's commitment to reduce the environmental impact of its processes and remain economically sustainable, innovative technologies are required to monitor mercury emissions. The aim of this project is to develop robust sensors, for online monitoring of mercury vapours, that operate under challenging industrial environments. This project will also provide excellent training for young researchers in established international industrial research groups, thereby meeting skill shortages in the Australian resource sector.Read moreRead less
Special Research Initiatives - Grant ID: SR180200015
Funder
Australian Research Council
Funding Amount
$589,007.00
Summary
Combination of electrochemistry with sono to destroy and detoxify PFAS. Previously the major means of dealing with per- and poly-fluoroalkyl substances (PFAS) is by adsorption, to collect and remove PFAS from contaminated sites. However, PFAS still exist, non-degraded and waiting for destruction. Targeting slurry waste from current remediation / adsorption plants, this project aims to efficiently degrade PFAS by combining electrochemical oxidation with sono-chemistry to enhance degradation capac ....Combination of electrochemistry with sono to destroy and detoxify PFAS. Previously the major means of dealing with per- and poly-fluoroalkyl substances (PFAS) is by adsorption, to collect and remove PFAS from contaminated sites. However, PFAS still exist, non-degraded and waiting for destruction. Targeting slurry waste from current remediation / adsorption plants, this project aims to efficiently degrade PFAS by combining electrochemical oxidation with sono-chemistry to enhance degradation capacity, to accelerate PFAS desorption / transportation from slurry waste, to avoid electrode fouling and to detoxify PFAS. The expected outcome of this project is to clean up contaminated sites, including PFAS / precursors and other persistent organic pollutants, leading to significant environmental benefits.Read moreRead less