Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without cau ....Cold catalysis for water splitting. This project aims to develop photocatalysts via AC magnetic field through nanoscale heating for efficient H2 generation. This project is to introduce cold catalysis concept, which heats catalysts only but not solution, thus called cold catalysis, in the area of production of renewable energy. Expected outcome is the creation of clean and low cost catalysts to effectively harvest the chemical energy from the sun via splitting of water into H2 and O2 without causing any environmental damage. This unique technology will also help to address clean energy generation, which is in line with H2 economy plan by Australia government, and provide opportunities for new industries that will benefit Australian economy.Read moreRead less
Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored mem ....Monolithic Solar Thermal Photocatalytic Membrane for Hydrogen Production. This ambitious project aims to develop a new concept of monolithic membranes composed of photocatalysts embedded in highly efficient solar thermal graphene. Such a membrane will be first of its kind and is able to utilise full solar spectrum for scalable seawater desalination and direct splitting to produce hydrogen without the need to concentrate sunlight. Expected outcomes include chemically and structurally tailored membranes and 2D floating prototypes for real life hydrogen production, and in-depth understanding of working mechanism to facilitate up-scaled renewable hydrogen generation. Significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding competitive clean energy industry are promised.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE210100084
Funder
Australian Research Council
Funding Amount
$269,020.00
Summary
Flexible Flame Aerosol Synthesis Technology. Funding is requested to establish a world-leading fabrication facility for nanostructured materials via flame synthesis. This is a scalable fabrication route used for industrial production of most nanoparticle commodities. The aim is to advance current capabilities by providing control over the reaction environment and flame reaction sources. This will extend the range of feasible materials from the current metal oxides to a broad family of nitrides, ....Flexible Flame Aerosol Synthesis Technology. Funding is requested to establish a world-leading fabrication facility for nanostructured materials via flame synthesis. This is a scalable fabrication route used for industrial production of most nanoparticle commodities. The aim is to advance current capabilities by providing control over the reaction environment and flame reaction sources. This will extend the range of feasible materials from the current metal oxides to a broad family of nitrides, sulphides, and metal-organic frameworks, enabling the engineering of electrocatalysts, optoelectronic- and bio-materials. Benefits are expected in terms of fundamental and applied knowledge generation, with impact to the Australian industry sectors of Advanced Manufacturing, Energy and Health.Read moreRead less
Sustainable production of chemicals and fuels from carbon dioxide. This project intends to deliver a cost-effective efficient bioelectrochemical process converting carbon dioxide (CO2) emissions into chemicals and fuels. Microbes are fascinating organisms giving us cheese, beer and wine. A special group of bacteria is even able to produce electricity from waste materials, or eat electricity to convert CO2 emissions into chemicals. This process has the potential to dramatically improve the sustai ....Sustainable production of chemicals and fuels from carbon dioxide. This project intends to deliver a cost-effective efficient bioelectrochemical process converting carbon dioxide (CO2) emissions into chemicals and fuels. Microbes are fascinating organisms giving us cheese, beer and wine. A special group of bacteria is even able to produce electricity from waste materials, or eat electricity to convert CO2 emissions into chemicals. This process has the potential to dramatically improve the sustainability of future chemical industry and environmental biotechnology. It has been shown that acetate, an important precursor in the chemical industry, can be produced in laboratory-scale reactors using selected microbial communities. The goal of the project is to engineer a process able to produce a broad range of biochemicals and biofuels from CO2 at high rates and high product concentrations.Read moreRead less
Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors w ....Protein biosensors for detecting smoke exposure of grapes. Bush fires and controlled burns that take place in the vicinity of vineyards can lead to grape contamination with tasteless phenolic glucosides. Their hydrolysis during wine making leads to “smoke taint” – an unpleasant medicinal taste that can render wine undrinkable. We will apply a combination of organic synthesis, protein engineering and directed evolution to develop protein-based biosensors of phenolic glucosides. These biosensors will be used to devise a simple portable colorimetric test that can be performed in the vineyard or the winery. The ability to rapidly determine the level of grape contamination with phenolic glucosides would give Australian wine growers and wine makers a powerful tool to mitigate the effects of bushfires.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100215
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Nature-inspired electrochemical conversion of nitrogen to ammonia. This project aims to achieve a highly active electrochemical catalytic system for ammonia production from atmospheric nitrogen under ambient conditions. Ammonia is essential for plant growth and food production but its synthesis is energy intensive, eco-destructive and costly. The project will design a functional device featuring a catalyst that will not only provide insights into the fundamentals of nitrogen reduction but also a ....Nature-inspired electrochemical conversion of nitrogen to ammonia. This project aims to achieve a highly active electrochemical catalytic system for ammonia production from atmospheric nitrogen under ambient conditions. Ammonia is essential for plant growth and food production but its synthesis is energy intensive, eco-destructive and costly. The project will design a functional device featuring a catalyst that will not only provide insights into the fundamentals of nitrogen reduction but also a sustainable and cost effective production of ammonia, a potential key to future world food supply and renewable energy.Read moreRead less