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
Efficient and selective water electrolysis for clean energy and environment. This project aims to develop an anion exchange membrane electrolysis cell for efficient co-generation of hydrogen and hydrogen peroxide from the splitting of water by coupling the hydrogen evolution reaction with a selective, two-electron water oxidation reaction catalysed by cost-effective, perovskite materials. This project expects to generate new knowledge in understanding the selective water electrolysis and in deve ....Efficient and selective water electrolysis for clean energy and environment. This project aims to develop an anion exchange membrane electrolysis cell for efficient co-generation of hydrogen and hydrogen peroxide from the splitting of water by coupling the hydrogen evolution reaction with a selective, two-electron water oxidation reaction catalysed by cost-effective, perovskite materials. This project expects to generate new knowledge in understanding the selective water electrolysis and in developing efficient energy conversion technologies. This project is expected to improve the utilisation of renewable energy and promote development of manufacturing and chemical industries in Australia. This should provide significant benefits to achieve energy safety and environmental sustainability for Australia.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240101013
Funder
Australian Research Council
Funding Amount
$435,237.00
Summary
New water-inserted perovskites for high-current-density water electrolysis. This project aims to develop a new type of water-inserted perovskite oxide materials to realise high-current-density hydrogen production in anion-exchange-membrane water elecrolysers using renewable electricity. Innovations are expected in the rational design and engineering of novel materials, elucidation of new catalytic mechanisms from experimental and computational studies, and breakthroughs in commercially-relevant ....New water-inserted perovskites for high-current-density water electrolysis. This project aims to develop a new type of water-inserted perovskite oxide materials to realise high-current-density hydrogen production in anion-exchange-membrane water elecrolysers using renewable electricity. Innovations are expected in the rational design and engineering of novel materials, elucidation of new catalytic mechanisms from experimental and computational studies, and breakthroughs in commercially-relevant water electrolysis processes. Expected outcomes include innovative materials engineering methods, in-depth reaction mechanism understandings, and demonstration of robust electrolysers. This project will provide significant benefit to Australia’s hydrogen industry and economic growth and energy sustainability in the long run.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
Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reac ....Energy-efficient liquid-flow system for electroreduction of carbon dioxide. Concerns about fossil fuel depletion and rising carbon emissions have brought about an urgent demand for carbon dioxide (CO2) capture and utilisation technologies. Facilitated by the mechanism-driven catalyst development and engineering innovation, this project aims to deliver a durable and cost-effective approach to electrochemical transformation of CO2 into the valuable products. The proposed automatic liquid-flow reactor system is expected to enable an energy efficient and practical viable CO2 reduction in benign aqueous electrolytes. The resulting innovations will not only reduce the environmental impact of atmospheric CO2 but also generate highly concentrated industrial feedstocks for the sustainable production of commodity chemicals.Read moreRead less
Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as ....Solar rechargeable Zinc-Bromine Flow Batteries. This project aims to develop a new solar rechargeable Zinc-Bromine flow battery for better utilization of the abundant yet intermittently available sunlight. The key design is to create a solar-driven photoelectrochemical process to convert the discharged electrode materials back to their charged states and realise the direct storage of solar energy. Expected outcomes include new solar driven rechargeable technology and photoelectrode materials, as well as new knowledge generated from collaborations across materials science, photoelectrochemistry and nanotechnology disciplines. Further advances in functional materials for solar energy storage will assist in addressing the global energy shortage and mitigating environmental pollution.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100383
Funder
Australian Research Council
Funding Amount
$450,554.00
Summary
Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected ou ....Photothermal management with graphene metamaterials. Environmental and industrial thermal management represents major global energy consumption and CO2 emission. This project aims to investigate a game-changing passive thermal management solution to tackle both heating and cooling problems without using any electricity. This is made possible by designing a nanostructured graphene metamaterial to either totally reject or totally absorb electromagnetic waves in certain spectral ranges. Expected outcomes include new design and fabrication strategies for novel photothermal films with high performance and cost-effectiveness. This is expected to lead to the development of novel energy efficient technologies for Australian industries, producing direct economic, social and environmental benefits.Read moreRead less
Characterising and Manipulating Triplet Interactions. Organic optoelectronic devices are based on organic semiconductors and are found throughout modern life. They underpin technologies such as phone and television displays, low-energy lighting, and solar cells.
The project Aims to use spectroscopy to comprehensively understand the underlying physics of organic optoelectronic device materials. This is Significant enabling science that will accelerate development of light-emitting diodes, solar ....Characterising and Manipulating Triplet Interactions. Organic optoelectronic devices are based on organic semiconductors and are found throughout modern life. They underpin technologies such as phone and television displays, low-energy lighting, and solar cells.
The project Aims to use spectroscopy to comprehensively understand the underlying physics of organic optoelectronic device materials. This is Significant enabling science that will accelerate development of light-emitting diodes, solar cells, and new quantum information technologies. Expected outcomes include new knowledge about organic semiconductors, enhanced Australian research capacity, and international collaboration. Benefits include device innovations and the training of researchers in synthesis, fabrication, and spectroscopy.Read moreRead less
Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functi ....Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functional materials to improve battery performance and thus further reduce the cost of energy storage. Expected outcomes include new materials and methods for advanced battery technology and manufacturing. The success of the project will significantly support the national priority of net-zero carbon emissions by 2050.Read moreRead less
Electrolyte and interface engineering of solid-state sodium batteries. This project aims to develop large-scale solid-state sodium-ion batteries exhibiting better safety compared to classic liquid electrolyte batteries without compromising on performance, thus addressing the significant issue of safety in batteries. This will be achieved by novel engineering of solid-state electrolytes and electrolyte-electrode interfacing by a fundamental understanding of sodium-ion transport using statistical ....Electrolyte and interface engineering of solid-state sodium batteries. This project aims to develop large-scale solid-state sodium-ion batteries exhibiting better safety compared to classic liquid electrolyte batteries without compromising on performance, thus addressing the significant issue of safety in batteries. This will be achieved by novel engineering of solid-state electrolytes and electrolyte-electrode interfacing by a fundamental understanding of sodium-ion transport using statistical and machine-learning techniques. Expected outcomes include an understanding of ion-transport mechanisms in batteries, delivery of advanced solid-state electrolytes with high ionic conductivity, and batteries with excellent performance and safety characteristics, which benefits Australia's environment and sustainability.Read moreRead less