Discovery Early Career Researcher Award - Grant ID: DE240100660
Funder
Australian Research Council
Funding Amount
$421,117.00
Summary
A Solar Photoelectrochemical Cell for Unbiased Hydrogen Production. This project aims to develop a photoelectrochemical cell for photoelectric conversion and green hydrogen production by using solar power as the only energy input. This project expects to generate new knowledge in photoelectrode material design by combining low-cost semiconductors with natural or synthetic molecular catalysts. Expected outcomes are to generate a sustainable solar hydrogen technique with no electricity consumption ....A Solar Photoelectrochemical Cell for Unbiased Hydrogen Production. This project aims to develop a photoelectrochemical cell for photoelectric conversion and green hydrogen production by using solar power as the only energy input. This project expects to generate new knowledge in photoelectrode material design by combining low-cost semiconductors with natural or synthetic molecular catalysts. Expected outcomes are to generate a sustainable solar hydrogen technique with no electricity consumption, high solar-to-hydrogen conversion efficiency and long-term stability, promoting the development of green hydrogen industries in Australia with zero carbon emissions. This should provide significant benefits to reduce greenhouse gas emissions, achieve environmental sustainability and meet renewable energy demand.Read moreRead less
2D oxide supported single-atom catalysts for sustainable fuel generation. This project aims to develop two-dimensional oxide supported single-atom catalysts for sustainable fuel generation from water and CO2 using combined theoretical and experimental investigations. The outcomes of this project will offer atomic and electronic level principles in designing high-performance catalysts and provide novel approaches on green fuel generations for emerging energy technologies. The success of this proj ....2D oxide supported single-atom catalysts for sustainable fuel generation. This project aims to develop two-dimensional oxide supported single-atom catalysts for sustainable fuel generation from water and CO2 using combined theoretical and experimental investigations. The outcomes of this project will offer atomic and electronic level principles in designing high-performance catalysts and provide novel approaches on green fuel generations for emerging energy technologies. The success of this project will meet the knowledge gap between advanced materials and practical sustainable energy technologies, and contribute to the development of sustainable society of Australia and international community by supplying low-cost and green fuels.Read moreRead less
Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that h ....Nitride materials: In the “bond ionicity Goldilocks zone” for solar energy. Progress towards commercial devices for solar-driven hydrogen generation as well as in-situ electricity generation for vehicles is currently hampered by a lack of earth-abundant, stable, non-toxic semiconductor materials that can be fabricated by scalable methods. This project aims to develop the first scalable solution synthesis methods for a new class of earth-abundant Zn-based nitride semiconductor nanocrystals that have favourable bond ionicity and establish their optoelectronic properties for renewable energy devices for the first time. Flexible solution processing methods will be exploited to tune surface composition, remove defects and create devices to achieve optimised performance in these challenging new nitride material systems.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100810
Funder
Australian Research Council
Funding Amount
$397,072.00
Summary
Solar-powered methanol conversion for on-demand hydrogen production. Methanol is an ideal hydrogen carrier due to its low cost, high hydrogen content, and liquid phase for easy storage and transport but facing problems with hydrogen release. This project aims to achieve cost-effective and emission-free methanol conversion for on-demand hydrogen production. The key concept is the rational design of high-performance single-atom catalytic materials for solar-powered photocatalytic methanol conversi ....Solar-powered methanol conversion for on-demand hydrogen production. Methanol is an ideal hydrogen carrier due to its low cost, high hydrogen content, and liquid phase for easy storage and transport but facing problems with hydrogen release. This project aims to achieve cost-effective and emission-free methanol conversion for on-demand hydrogen production. The key concept is the rational design of high-performance single-atom catalytic materials for solar-powered photocatalytic methanol conversion to hydrogen and value-added chemical formaldehyde with high productivity and selectivity. Expected outcomes include cutting-edge knowledge in the synthesis of functional materials and technology for efficient methanol-to-hydrogen conversion, contributing to the development of the hydrogen economy in Australia.Read moreRead less
High entropy metal organic frameworks for sustainable hydrogen production. The ultimate critical core for green hydrogen fuel generation is efficient and cost-effective catalysts. This project aims to design novel high entropy metal organic frameworks (HE-MOFs) using advanced high throughput computational screening integrated with experimental validation for sustainable hydrogen production. The outcome of this project will discover a new class of HE-MOFs materials with superior hydrogen generati ....High entropy metal organic frameworks for sustainable hydrogen production. The ultimate critical core for green hydrogen fuel generation is efficient and cost-effective catalysts. This project aims to design novel high entropy metal organic frameworks (HE-MOFs) using advanced high throughput computational screening integrated with experimental validation for sustainable hydrogen production. The outcome of this project will discover a new class of HE-MOFs materials with superior hydrogen generation efficiency, while also provide rational design principles for the exploration of high-efficient catalysts in sustainable fuel generation. The success of this project will help to achieve the zero-carbon target and contribute to the development of a sustainable society with low-cost and renewable energy supply.Read moreRead less
2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomin ....2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomings. Expected outcomes will include improved electrochemical performance of materials and an integrated energy system utilizing these multi-functional materials to produce green hydrogen at low cost and high efficiency. The project should contribute largely to Australia’s transition to robust and affordable clean energy.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL230100178
Funder
Australian Research Council
Funding Amount
$3,343,741.00
Summary
Nonmetals for green catalysis. This proposal aims to develop nonmetal materials and technologies for frontier green catalysis that is targeted to contaminant degradation and chemical synthesis by catalytic oxidation processes. The project will systematically unveil the intrinsic nature of nonmetal elements in heterogeneous catalysis, develop rational design principles, and achieve scaling-up of intelligent nanomaterials and integrated green catalytic systems for high reactivity and selectivity. ....Nonmetals for green catalysis. This proposal aims to develop nonmetal materials and technologies for frontier green catalysis that is targeted to contaminant degradation and chemical synthesis by catalytic oxidation processes. The project will systematically unveil the intrinsic nature of nonmetal elements in heterogeneous catalysis, develop rational design principles, and achieve scaling-up of intelligent nanomaterials and integrated green catalytic systems for high reactivity and selectivity. This cross-disciplinary research will deliver benefits to Australian industry in water treatment and fine chemical synthesis, foster Australian R&D in green technologies, synthesise catalysts from natural resources and industrial waste, and promote strong sustainability outcomes.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