Discovery Early Career Researcher Award - Grant ID: DE190101410
Funder
Australian Research Council
Funding Amount
$393,000.00
Summary
Structural and compositional controlled nanocarbon-based electrocatalyst. This project aims to develop highly effective carbon-based electro-catalysts for oxygen reduction by using elaborately designed metal-organic framework precursors. Oxygen reduction is a key cathodic reaction in clean energy technologies such as metal-air batteries and fuel cells. Expected outcomes of this project include carbon-based nanomaterials with optimised topological and compositional features. This project will bro ....Structural and compositional controlled nanocarbon-based electrocatalyst. This project aims to develop highly effective carbon-based electro-catalysts for oxygen reduction by using elaborately designed metal-organic framework precursors. Oxygen reduction is a key cathodic reaction in clean energy technologies such as metal-air batteries and fuel cells. Expected outcomes of this project include carbon-based nanomaterials with optimised topological and compositional features. This project will broaden the knowledge of designed synthesis of carbon-based nanocatalysts for oxygen reduction and provide a conceptual nanofabrication framework for preparing functional nanomaterials.Read moreRead less
In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox ....In pursuit of high performance lithium-oxygen batteries. This project aims to achieve high-energy lithium-oxygen batteries for electric vehicles. Electrification of road transport will minimise consumption of fossil fuels, reduce carbon dioxide emissions, and increase energy security. Lithium-oxygen batteries have the highest energy density among all rechargeable battery systems, which is more than 10 times the density of current lithium-ion batteries. Through exploration of new catalysts, redox mediators, and porous material architectures, this project intends to significantly improve the performance of lithium-oxygen batteries, including specific capacity, cycle life and round-trip efficiency.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100036
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate ....Rechargeable room-temperature sodium-oxygen batteries. This project aims to develop high performance room-temperature sodium-oxygen batteries as a green and low-cost power source for large scale electrical energy storage. Through electrode architecture design, this research intends to significantly improve the performance of sodium-oxygen batteries, including specific capacity, cycle life and round-trip energy efficiency. Expected outcomes include reducing consumption of fossil fuels to generate electricity, with benefits for the environment, climate change and energy security.Read moreRead less
Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and compr ....Photoelectrode design for solar driven methane to methanol conversion. This project aims to achieve efficient photoelectrocatalytic partial oxidation of greenhouse gas methane for methanol production with high selectivity. The program will design new semiconductor materials through rational defect engineering and co-catalyst selection to revolutionise methane conversion. The expected outcomes include sustainable processes to convert methane into valuable liquid chemicals like methanol, and comprehensive understanding on functional material design for solar driven catalytic reactions. The significant benefits will include revolutionary methane mitigation technologies and sustainable processes for value-added chemical production, alleviating key environmental and energy challenges facing Australia and the world.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100661
Funder
Australian Research Council
Funding Amount
$439,237.00
Summary
Designing Multi-Metallic Compound Electrocatalysts for Chemicals Production. This project aims to design highly active, specifically selective, satisfactorily stable catalysts based on advanced ionic compound materials for carbon dioxide (CO2) electroreduction. Innovations are expected in the multi-metallic composition to ensure catalytic performance while maintain stability under electrochemical conditions. With assistance of artificial-intelligence approaches, numerous atomic-scale modelling, ....Designing Multi-Metallic Compound Electrocatalysts for Chemicals Production. This project aims to design highly active, specifically selective, satisfactorily stable catalysts based on advanced ionic compound materials for carbon dioxide (CO2) electroreduction. Innovations are expected in the multi-metallic composition to ensure catalytic performance while maintain stability under electrochemical conditions. With assistance of artificial-intelligence approaches, numerous atomic-scale modelling, speed-up theoretical simulation and rational screening can be achieved. Expected outcomes include providing guidance in elemental composition ratio and suitable reaction conditions for experiments. Benefits include reduced CO2 to fight climate change and increased green-fuel production for sustainable growth of Australia.Read moreRead less
Solar driven methane conversion for green methanol production. This project aims to develop advanced photoelectrode materials for solar driven methane partial oxidation to produce methanol. The key concepts are to develop new semiconductor devices and alloy metal cocatalysts in solving the slow charge and mass transfer challenges in catalytic methane partial oxidation reactions. The expected outcomes include ground-breaking approaches for catalytic materials design, efficient solar fuel producti ....Solar driven methane conversion for green methanol production. This project aims to develop advanced photoelectrode materials for solar driven methane partial oxidation to produce methanol. The key concepts are to develop new semiconductor devices and alloy metal cocatalysts in solving the slow charge and mass transfer challenges in catalytic methane partial oxidation reactions. The expected outcomes include ground-breaking approaches for catalytic materials design, efficient solar fuel production and cutting-edge knowledge on methane activation mechanism. The program is aligned with Australia’s Net-Zero Emission 2050 target, representing an innovative pathway in converting greenhouse gases into valuable chemicals, which will bring environmental and economic benefits to Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100357
Funder
Australian Research Council
Funding Amount
$409,118.00
Summary
Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the ....Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the structure-property relationship in new catalytic systems, and technological breakthroughs in reducing carbon dioxide emissions. The success of this project will bring significant environmental and economic benefits, and position Australia at the frontier of global transition to a low-carbon economy.Read moreRead less
Potassium ion batteries for large scale renewable energy storage. The project aims to develop potassium ion batteries for renewable energy storage and conversion. Potassium ion batteries could be the most promising choice for large-scale electrical energy storage, particularly for renewable energy sources and smart electrical grids, due to their low cost, natural abundance and the advantages of potassium compared to lithium/sodium ion batteries. This study will research the electrochemical react ....Potassium ion batteries for large scale renewable energy storage. The project aims to develop potassium ion batteries for renewable energy storage and conversion. Potassium ion batteries could be the most promising choice for large-scale electrical energy storage, particularly for renewable energy sources and smart electrical grids, due to their low cost, natural abundance and the advantages of potassium compared to lithium/sodium ion batteries. This study will research the electrochemical reactions and charge transfer pathway of electrode materials with excellent potassium ion storage performance. This project is expected to develop high performance potassium ion batteries and advance the prominence of Australia in the global renewable energy market.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100021
Funder
Australian Research Council
Funding Amount
$440,154.00
Summary
Kesterite/Si Tandem Structure for Unassisted Overall Solar Fuel Production. This project aims to develop Kesterite/Si tandem device for photoelectrochemical carbon dioxide reduction to produce solar fuels. It is expected to reveal the photoelectrochemical mechanism of the p-n heterojunction, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a high-performance kesterite photocathode for efficient CO2 reduction, a kesterite/Si tandem dev ....Kesterite/Si Tandem Structure for Unassisted Overall Solar Fuel Production. This project aims to develop Kesterite/Si tandem device for photoelectrochemical carbon dioxide reduction to produce solar fuels. It is expected to reveal the photoelectrochemical mechanism of the p-n heterojunction, thereby promoting solar energy utilisation and greenhouse gas reduction. Expected outcomes include delivery of a high-performance kesterite photocathode for efficient CO2 reduction, a kesterite/Si tandem device for overall unassisted solar fuel production, and an in-depth understanding of structure-performance correlation to guide future heterojunction photocathode design. This project should provide significant benefits in minimising fossil fuel consumption, increasing energy security, and expanding the clean energy industry.Read moreRead less
Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding ....Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding of sodium-ion batteries, and provide techniques for the development of a promising low-cost system for renewable energy storage, which is urgently needed in smart electricity grids. Read moreRead less