Next generation material imaging, spectrometry and fabrication techniques. This project aims to solve a common, fundamental problem limiting the performance of mass spectrometers and high resolution electron microscopes: surface modification caused by unintended chemical reactions due to electron impact. The intended project outcomes will advance current understanding of electron restructuring of surfaces and open the door to next-generation material imaging, spectrometry and fabrication techniq ....Next generation material imaging, spectrometry and fabrication techniques. This project aims to solve a common, fundamental problem limiting the performance of mass spectrometers and high resolution electron microscopes: surface modification caused by unintended chemical reactions due to electron impact. The intended project outcomes will advance current understanding of electron restructuring of surfaces and open the door to next-generation material imaging, spectrometry and fabrication techniques. It will develop a superior detector for mass spectrometry and improve the imaging and nanofabrication capabilities of state-of-the-art electron microscopes. Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101102
Funder
Australian Research Council
Funding Amount
$404,748.00
Summary
Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to un ....Single-Atom Catalysts on Atomically Thin Nanomaterials for H2O2 Production. Single-atomic sites supported on graphene analogs is an ideal structural mode for the design of electrocatalysts due to its ultimate small size limit, atomic thickness, and easily tuned electronic properties. This project aims to use a theory-guided approach to develop efficient electrocatalysts for the production of value-added hydrogen peroxide. The structural advantages of graphene analogs will be fully utilised to unlock the catalytic power of single-atomic sites, and consequently achieve high catalytic activity and selectivity. The outcome will set a solid scientific foundation to enable economically viable technologies for eco-friendly hydrogen peroxide production and bring significant socioeconomic benefits to Australia.Read moreRead less
Atomically Thin 3d Transition Metal Electrocatalysts for Water Splitting. The current industrial-scale hydrogen productions are reliant on high temperature steam reforming fossil fuels, consuming large quantity of energy and fossil resources, and emitting huge amounts of CO2. This project aims to develop cheap and plentiful transition metal-based high performance water splitting electrocatalysts, enabling economically viable large-scale water electrolytic hydrogen production driven by renewable ....Atomically Thin 3d Transition Metal Electrocatalysts for Water Splitting. The current industrial-scale hydrogen productions are reliant on high temperature steam reforming fossil fuels, consuming large quantity of energy and fossil resources, and emitting huge amounts of CO2. This project aims to develop cheap and plentiful transition metal-based high performance water splitting electrocatalysts, enabling economically viable large-scale water electrolytic hydrogen production driven by renewable electricity. A theory-guided catalyst approach will be used to guide the efficient design and development of high performance electrocatalysts. The success of the project will lead to a suit of high performance water splitting electrocatalysts, leaping forward water electrolytic hydrogen production technology.Read moreRead less
Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the ....Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the key feed-stock of CO for sustainable use in hydrocarbon fuels, providing significant benefits in the reduction of greenhouse emissions.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101883
Funder
Australian Research Council
Funding Amount
$403,948.00
Summary
Carbon-based catalysts for value-added chemicals from CO2 and sunlight . This project aims to address the problem of excessive carbon dioxide in the atmosphere by utilizing newly designed - carbon architecture derived catalysts and constructing important integrated devices. The insights thus gained will generate new knowledge both in the chemical sciences of understanding the mechanism of carbon dioxide reduction on advanced carbon-based catalysts, and the engineering of effectively integrated d ....Carbon-based catalysts for value-added chemicals from CO2 and sunlight . This project aims to address the problem of excessive carbon dioxide in the atmosphere by utilizing newly designed - carbon architecture derived catalysts and constructing important integrated devices. The insights thus gained will generate new knowledge both in the chemical sciences of understanding the mechanism of carbon dioxide reduction on advanced carbon-based catalysts, and the engineering of effectively integrated devices. The expected outcome of this project is a low-cost approach to the sustainable generation of clean and renewable value-added chemicals from carbon dioxide driven by sunlight, which provides significant benefits for human society in terms of clean energy and environmental protection.Read moreRead less