Functional two-dimensional materials for photocatalysis. This project aims to explore and tailor two-dimensional materials and heterostructures by new synthetic strategies, and to develop a comprehensive understanding of the effects of crystalline and electronic structures on photocatalysis at the atomic level. The project expects to provide deep insight into catalytic mechanisms by bridging the current gap between realistic systems and theoretical calculations. By simply using solar energy, the ....Functional two-dimensional materials for photocatalysis. This project aims to explore and tailor two-dimensional materials and heterostructures by new synthetic strategies, and to develop a comprehensive understanding of the effects of crystalline and electronic structures on photocatalysis at the atomic level. The project expects to provide deep insight into catalytic mechanisms by bridging the current gap between realistic systems and theoretical calculations. By simply using solar energy, the project aims to provide an efficient and durable method for clean energy generation/conversion, and carbon sequestration. This project will build national research capacity in an emerging field and put Australia at the forefront of research on photocatalysis to address energy and environmental issues. Read moreRead less
Mechanisms and innovative technologies for machining nanoscale multilayered thin film solar panels. This project addresses an important manufacturing bottleneck in the solar energy industry by addressing significant limitations in machining multilayered solar panels. A successful outcome will provide an important breakthrough in machining technology applicable not only to solar panels but other material science applications.
Discovery Early Career Researcher Award - Grant ID: DE180101300
Funder
Australian Research Council
Funding Amount
$368,446.00
Summary
Probing interfacial impedance in all-solid-state lithium-ion batteries. This project aims to investigate the mechanism behind the high impedance at the interface between electrodes and the solid electrolyte in solid-state lithium-ion batteries using advanced in-situ transmission electron microscopy. The outcomes will deepen knowledge in chemical and structural evolution at the electrode–electrolyte interface during battery operation under different conditions, and thus inform the design and fabr ....Probing interfacial impedance in all-solid-state lithium-ion batteries. This project aims to investigate the mechanism behind the high impedance at the interface between electrodes and the solid electrolyte in solid-state lithium-ion batteries using advanced in-situ transmission electron microscopy. The outcomes will deepen knowledge in chemical and structural evolution at the electrode–electrolyte interface during battery operation under different conditions, and thus inform the design and fabrication of safe, high power, and long lasting solid-state batteries for a myriad of portable electronic devices and the emerging electric vehicles.Read moreRead less
Cost-effective metal selenide materials for solid-state devices. Thermoelectric materials, directly converting thermal energy into electrical energy, offer a green and sustainable solution for the global energy dilemma. This project aims to develop cost-effective metal selenide materials for high-efficiency solid-state devices using a novel industry-level approach, coupled with nanostructure and band engineering strategies. The key breakthrough is to design high-performance metal selenide thermo ....Cost-effective metal selenide materials for solid-state devices. Thermoelectric materials, directly converting thermal energy into electrical energy, offer a green and sustainable solution for the global energy dilemma. This project aims to develop cost-effective metal selenide materials for high-efficiency solid-state devices using a novel industry-level approach, coupled with nanostructure and band engineering strategies. The key breakthrough is to design high-performance metal selenide thermoelectric materials with engineered chemistry and unique structures for new generation thermoelectrics. The expected outcomes will lead to an innovative technology for harvesting electricity from waste heat or sunlight, which will place Australia at the forefront of energy and manufacturing technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220101105
Funder
Australian Research Council
Funding Amount
$425,000.00
Summary
Developing Sustainable and Reliable Anode-free Lithium Metal Batteries. This project aims to investigate and optimise the functional properties of anode-free lithium metal battery electrodes. The project expects to develop a novel, high-throughput electrochemistry platform that can rapidly screen new materials and chemistries across length scales, from single atoms to entire battery cells. Understanding battery performance in such detail is expected to enhance our capability to design and manufa ....Developing Sustainable and Reliable Anode-free Lithium Metal Batteries. This project aims to investigate and optimise the functional properties of anode-free lithium metal battery electrodes. The project expects to develop a novel, high-throughput electrochemistry platform that can rapidly screen new materials and chemistries across length scales, from single atoms to entire battery cells. Understanding battery performance in such detail is expected to enhance our capability to design and manufacture smart battery materials that are higher performing, safer and longer lasting than current technologies. This should provide significant socio-economic and environmental benefits, through the development of commercially-feasible next-generation devices, used by households or businesses to store renewable energy.Read moreRead less
Covalently immobilised molecular catalysts for carbon dioxide reduction. This project aims to develop innovative catalytic systems on semiconductor surfaces, to use sunlight for conversion of carbon dioxide (CO2) into high energy-content products. Sustainable chemical transformation of CO2 into valuable products, especially fuels, is one of the most important chemical processing challenges. This project will use innovative molecular engineering to covalently fix light-harvester to semiconductors ....Covalently immobilised molecular catalysts for carbon dioxide reduction. This project aims to develop innovative catalytic systems on semiconductor surfaces, to use sunlight for conversion of carbon dioxide (CO2) into high energy-content products. Sustainable chemical transformation of CO2 into valuable products, especially fuels, is one of the most important chemical processing challenges. This project will use innovative molecular engineering to covalently fix light-harvester to semiconductors. The expected outcome will be an efficient system to enhance CO2 conversion, which will not only reduce the environmental impact but also generate a cheap source of energy by closing the carbon loop. Using this approach, existing high carbon-emitting processes will be able to be replaced by new carbon-neutral or even carbon-negative ones for much-reduced environmental impact on our society.Read moreRead less
Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectros ....Assembling multi-functional nanocomposites for carbon dioxide reduction by hybrid catalytic and photochemical approach. The overall aim of this project is to assemble multi-functional nanocomposites for carbon dioxide reduction by an integrated catalytic and photocatalytic approach. The issues of impending depletion of fossil fuel resources and irreversible climate change due to carbon dioxide emissions have stimulated research for the sustainable utilisation of carbon dioxide. In situ spectroscopic studies combined with theoretical calculations will be used to elucidate the underlying reaction mechanisms of the synergistic effects of photon and thermal reduction of carbon dioxide . The success of the proposed project will allow the reduction of carbon dioxide, generate a cheap energy source in the form of environmentally benign hydrocarbons and close the carbon loop. Read moreRead less