Nanoscale electrochemical imaging of catalyst inks for water oxidation. This project aims to reduce the cost of current water splitting technology by making new catalysts from earth abundant materials that will ensure a sustainable technological solution for the storage of renewable energy. This technology is an excellent solution to storing energy from intermittent renewable energy sources such as solar as it generates hydrogen which is a clean fuel. Using new techniques that can image the cata ....Nanoscale electrochemical imaging of catalyst inks for water oxidation. This project aims to reduce the cost of current water splitting technology by making new catalysts from earth abundant materials that will ensure a sustainable technological solution for the storage of renewable energy. This technology is an excellent solution to storing energy from intermittent renewable energy sources such as solar as it generates hydrogen which is a clean fuel. Using new techniques that can image the catalyst at the nanoscale while it is operating is expected to provide the knowledge for developing the next generation of water splitting electrolysers that can be utilised by households and businesses for storing solar or wind energy.Read moreRead less
Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a ....Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a recyclable battery configuration to allow rapid, low cost and green recycling of end-of-life batteries. The new battery will be a safe, low cost and sustainable energy storage technology for the multi-billion dollar electric vehicle and smart grid markets while simultaneously addressing battery recycling issues.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101045
Funder
Australian Research Council
Funding Amount
$448,407.00
Summary
Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized envi ....Bioinspired 2D nanocatalysts for inorganic nitrogen cycle. This project aims to develop novel catalysts for high-efficient nitrogen fixation by learning from the natural enzymes, which can convert nitrogen or nitrate into reactive ammonia at very mild conditions. It is expected that the enzyme-mimicking catalysts possessing the nitrogen active sites similar with the natural enzymes will allow the effective fixation of nitrogen from both the atmosphere and the nitrogen excessively fertilized environment into reusable ammonia. The outcomes of this project will provide a sustainable approach to solve the issues in current unbalanced inorganic nitrogen cycle in the world and contribute to a green artificial nitrogen cycle while with minimized environmental impact.Read moreRead less
Functionalising sustainable natural binders for energy storage devices. This project aims to produce low-cost energy storage devices to meet the energy demands and safety requirements of electric appliances, electric vehicles and smart electricity grids. High-cost and non-regenerable resources and existing energy storage devices’ safety issues have hindered the electrification of portable electronic devices and vehicles and use of intermittent solar and wind energy. This project will use sustain ....Functionalising sustainable natural binders for energy storage devices. This project aims to produce low-cost energy storage devices to meet the energy demands and safety requirements of electric appliances, electric vehicles and smart electricity grids. High-cost and non-regenerable resources and existing energy storage devices’ safety issues have hindered the electrification of portable electronic devices and vehicles and use of intermittent solar and wind energy. This project will use sustainable natural polymers to develop green electrode technologies for manufacturing batteries with greatly reduced production and environmental cost. The in-depth understandings from the combination of experiments and computation simulations will help create strategies to realise low cost, long-life and safe batteries.Read moreRead less
Advancing green electrochemical engineering of functional 2D nanomaterials. This project aims to produce value-added functional 2D nanomaterials by advancing the green, scalable and cost-effective electrochemical production method developed by the candidate. In addition to developing transformational electrochemical engineering technology to utilise Australian raw resources, this project will generate new knowledge in the area of materials chemistry and innovative additive manufacturing technolo ....Advancing green electrochemical engineering of functional 2D nanomaterials. This project aims to produce value-added functional 2D nanomaterials by advancing the green, scalable and cost-effective electrochemical production method developed by the candidate. In addition to developing transformational electrochemical engineering technology to utilise Australian raw resources, this project will generate new knowledge in the area of materials chemistry and innovative additive manufacturing technology. Expected outcomes of this project include improved pilot-scale electrochemical reactors for producing various functional 2D nanomaterials and enabling precise control of their molecular and bulk properties. These tailored 2D nanomaterials will significantly improve the performances of flexible and energy-related devices.Read moreRead less
Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide d ....Chlorine Evolution Catalysts for Efferent Seawater Electrolysis. Seawater is the most abundant aqueous resource on earth that is readily accessible at very low costs, but yet to be directly utilised for production of hydrogen fuel and commodity chemicals. This project aims to develop cheap and plentiful carbon-based high performance chlorine evolution electrocatalysts for seawater electrolysis powered by renewable electricity to realise the production of hydrogen, chlorine and sodium hydroxide directly from seawater. The electrolyser can also be used to treat desalination brine while produce hydrogen and chemicals. The success of the project will set a firm technological foundation for seawater utilisation, which will add to Australian capability to meet future energy and environment challenges.Read moreRead less
Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all ox ....Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all oxide-based PEMFC technology using a recently developed sintered and heteropolyacid functionalised mesoporous silica membrane. The utilisation of all-oxide-PEMFCs using non-precious metal catalysts is expected to significantly enhance the power density, reduce costs, and enhance the commercial viability of PEMFC technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101253
Funder
Australian Research Council
Funding Amount
$367,646.00
Summary
Perovskite photovoltaic-assisted energy conversion system using wastewater. This project aims to explore the potential of a solar-driven electrochemical system to simultaneously generate hydrogen and electricity by utilising wastewater as a fuel. The key concept of this system is integrating high efficiency perovskite solar cells as a high voltage supplier, with the electrochemical system to accelerate solar-to-hydrogen conversion and oxygen reduction for solar-to-electricity conversion during o ....Perovskite photovoltaic-assisted energy conversion system using wastewater. This project aims to explore the potential of a solar-driven electrochemical system to simultaneously generate hydrogen and electricity by utilising wastewater as a fuel. The key concept of this system is integrating high efficiency perovskite solar cells as a high voltage supplier, with the electrochemical system to accelerate solar-to-hydrogen conversion and oxygen reduction for solar-to-electricity conversion during oxidisation of organic fuels in wastewater. This project expects to open up an independent and transportable power grid-free electrochemical system to address energy and water utilisation issues, especially for remote and Indigenous areas in Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE140101662
Funder
Australian Research Council
Funding Amount
$395,220.00
Summary
Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is wel ....Non-Oxidative and Scalable Electrochemical Production of Functional Graphene and its Nanohybrids. The lack of cost-effective and scalable graphene production methods is the current bottleneck that impedes the commercialisation of advanced graphene-based nanomaterials. Novel electrochemical production of those functional materials directly from bulk graphite not only holds the key to the solution but also provides a non-oxidative route for the production of highly conductive graphene which is well suited for applications such as biosensing, energy storage and conversion. Besides achieving scientific breakthroughs in graphene electrochemistry, this project will directly benefit many Australian socio-economic objectives, including manufacturing of Australia's natural resources into valuable energy related products.Read moreRead less
Development of high performance cathode materials for Lithium-ion batteries. This project will lead to a new family of cathode materials for Lithium-ion batteries with both high energy and power densities. The newly-developed energy storage system will be critically important for the efficient use of renewables in Australia's electricity grid and hybrid transportation industry.