Electrodeposited Cathodes with Tunable Stoichiometry for Alkaline Batteries. The growing dependency on intermittently-available renewable energy sources has resulted in metal-ion batteries being adopted as the most common solution; yet its fabrication requires multi-stage high-temperature processing leading to high costs, quality issues, and reduced service life. Thus, the present project targets the room-temperature fabrication of binary and ternary oxide cathodes by a single-step, high-yield, ....Electrodeposited Cathodes with Tunable Stoichiometry for Alkaline Batteries. The growing dependency on intermittently-available renewable energy sources has resulted in metal-ion batteries being adopted as the most common solution; yet its fabrication requires multi-stage high-temperature processing leading to high costs, quality issues, and reduced service life. Thus, the present project targets the room-temperature fabrication of binary and ternary oxide cathodes by a single-step, high-yield, cost-effective technique and their integration into Na-ion batteries with minimal and no processing. The expected outcomes from this novel and efficient device fabrication can lead to significant commercial, social, and environmental benefits owing to the advancement of the battery industry and associated job creation.
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Discovery Early Career Researcher Award - Grant ID: DE230100637
Funder
Australian Research Council
Funding Amount
$428,154.00
Summary
An integrated electrolyser for CO2 conversion from capture media. This project aims to develop an efficient electrochemical method to convert carbon dioxide (CO2) to valuable chemicals. It expects to displace the energy-costly step of its upstream CO2 capture process. The key novelty is the use of flow-through electrodes and optimal solvents to promote CO2 conversion at high rates. Expected outcomes include enhanced efficiency of CO2 sequestration, and new techniques to develop electrodes with w ....An integrated electrolyser for CO2 conversion from capture media. This project aims to develop an efficient electrochemical method to convert carbon dioxide (CO2) to valuable chemicals. It expects to displace the energy-costly step of its upstream CO2 capture process. The key novelty is the use of flow-through electrodes and optimal solvents to promote CO2 conversion at high rates. Expected outcomes include enhanced efficiency of CO2 sequestration, and new techniques to develop electrodes with well-controlled local reaction environments, which are essential for electrochemical energy conversion and storage. This will benefit Australia's environment and industries such as cement and aluminium manufacturing in managing carbon emissions, and accelerate Australia’s transition to a carbon-neutral economy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100084
Funder
Australian Research Council
Funding Amount
$950,000.00
Summary
Australia’s fuel cells and electrolysers prototyping and testing facility. This project aims to address a major gap in Australian infrastructure for researching and developing technologies for Power to X, including hydrogen production and use. The aspiration is to establish an integrated fuel cell and electrolyser prototyping and testing facility to support Australia’s excellent fundamental research in advanced energy materials, electrocatalysis, and engineering design. The aim is to equip the r ....Australia’s fuel cells and electrolysers prototyping and testing facility. This project aims to address a major gap in Australian infrastructure for researching and developing technologies for Power to X, including hydrogen production and use. The aspiration is to establish an integrated fuel cell and electrolyser prototyping and testing facility to support Australia’s excellent fundamental research in advanced energy materials, electrocatalysis, and engineering design. The aim is to equip the research community with the capability to fabricate electrolyser and fuel cell prototypes at relevant scales to accelerate translational research in these areas. Doing so will also enable the technical and expertise platform needed to support industry's transition toward Australia’s 2050 net zero objective.Read moreRead less
A unifying model for ion exchange membranes – towards a low carbon future. Polymeric ion exchange membranes are key to emerging renewable energy systems and bioprocessing applications. Advances in this field are currently impeded by a focus on their performance in idealised pure solutions and siloed research. This project aims to draw together fundamental and applied research to develop an innovative, unifying model for the transport of both charged ions and uncharged molecules through these mem ....A unifying model for ion exchange membranes – towards a low carbon future. Polymeric ion exchange membranes are key to emerging renewable energy systems and bioprocessing applications. Advances in this field are currently impeded by a focus on their performance in idealised pure solutions and siloed research. This project aims to draw together fundamental and applied research to develop an innovative, unifying model for the transport of both charged ions and uncharged molecules through these membranes within complex, multicomponent mixtures. The team will build on strong collaborations to drive uptake of the new model within the clean energy and CO2 reduction sectors to advance the abatement of Australian emissions; and will prepare young researchers for a role within these emerging fields.Read moreRead less