Carbon-based electrode materials for electrochemical energy storage and water desalination. Clean energy and water resource are two critical issues for an environmentally sustainable Australia. The research project will lead to the discovery of innovative carbon-based electrode materials with well-designed physical and chemical properties for clean energy storage and alternative water desalination technology.
Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class ....Band-Gap Engineered Visible Light Photocatalysts: Enabling Technologies for Sustainable Energy and the Environment. This program will contribute significantly to knowledge advancement in colloid chemistry, nanomaterials and electrochemistry, and is firmly embedded in the National Research Priorities of Frontier Science and an Environmentally Sustainable Australia. In particular, it addresses the goals of water and low emission energy supply. The outcomes of this research will advance a new class of visible-light active photocatalysts that underpin the development of hydrogen generation, low cost solar cells and water purification using sunlight. Such technologies will transform the Australian energy and environmental industries and speed up the transition from a fossil fuel economy to a renewable energy economy.Read moreRead less
Designing New Visible-light Active Photocatalysts for Efficient CO2 Reduction. The increasing concern over Climate Change has triggered great efforts in developing new CO2 capture technologies. The outcomes of this program will lead to a new class of photocatalysts that underpin the development of economical CO2 reduction for clean fuel production using sunlight. Such technologies will speed up the transition of Australian environmental and energy industries from fossil fuel economy to renewable ....Designing New Visible-light Active Photocatalysts for Efficient CO2 Reduction. The increasing concern over Climate Change has triggered great efforts in developing new CO2 capture technologies. The outcomes of this program will lead to a new class of photocatalysts that underpin the development of economical CO2 reduction for clean fuel production using sunlight. Such technologies will speed up the transition of Australian environmental and energy industries from fossil fuel economy to renewable energy economy. The research program will contribute significantly to knowledge advancement in nanomaterials, surface chemistry, and photochemistry, and falls in the National Research Priority Area of 'Environmentally Sustainable Australia' addressing the key goals of Climate Change and low emission energy supply.Read moreRead less
Development of Nanostructured TiO2 Electrodes for Photoelectrocatalytic Degradation of Organic and Microbial Pollutants in Wastewater. Australia is one of the driest continents and re-use of water/wastewater has been an urgent issue. Photoelectrocatalytic oxidation processes based on nanostructured TiO2 electrode are able to mineralize common aquatic organic and microbial pollutants. The proposed technology has the advantages of strong oxidation power and cheap production cost, and it is chemi ....Development of Nanostructured TiO2 Electrodes for Photoelectrocatalytic Degradation of Organic and Microbial Pollutants in Wastewater. Australia is one of the driest continents and re-use of water/wastewater has been an urgent issue. Photoelectrocatalytic oxidation processes based on nanostructured TiO2 electrode are able to mineralize common aquatic organic and microbial pollutants. The proposed technology has the advantages of strong oxidation power and cheap production cost, and it is chemically stable, robust under UV illumination, and most importantly, environmentally friendly. The success of the project can place Australia in a leading position of developing cutting-edge TiO2 nano-material-based photoelectrochemical technologies for environmental wastewater treatment and drinking water disinfection. Read moreRead less
Adsorption and recovery of gold thiosulfate using nanoporous carbon. The gold industry is a major export earner for both Australia and the United States. This collaborative project aims to develop an environmentally acceptable, cost effective process for the recovery of gold from thiosulfate leachate. Development of this process will remove one of the barriers to the acceptance of thiosulfate leaching over conventional cyanide extraction, leading to substantial benefits to the gold industry and ....Adsorption and recovery of gold thiosulfate using nanoporous carbon. The gold industry is a major export earner for both Australia and the United States. This collaborative project aims to develop an environmentally acceptable, cost effective process for the recovery of gold from thiosulfate leachate. Development of this process will remove one of the barriers to the acceptance of thiosulfate leaching over conventional cyanide extraction, leading to substantial benefits to the gold industry and the environment. A successful outcome in the research project would also lead to export earnings resulting from technology transfer and an enhanced reputation for high quality research.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.
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
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100026
Funder
Australian Research Council
Funding Amount
$480,000.00
Summary
A surface characterisation facility. This surface characterisation facility will provide scientists with an understanding of material's surfaces and interfaces. This will lead to a range of new technologies and innovative solutions required to address the many resource and environmental challenges facing our planet now and in the future.