Discovery Early Career Researcher Award - Grant ID: DE230101712
Funder
Australian Research Council
Funding Amount
$394,818.00
Summary
All-perovskite tandem solar cells for efficient green hydrogen production. This project aims to design functional materials for the development high-performance and durable solar energy conversion devices, which enable efficient green solar hydrogen production to reduce fossil fuel consumption and alleviate environmental burden. The expected outcomes include advanced semiconducting materials, proof-of-concept solar-driven water electrolytic system with a high solar-to-hydrogen conversion efficie ....All-perovskite tandem solar cells for efficient green hydrogen production. This project aims to design functional materials for the development high-performance and durable solar energy conversion devices, which enable efficient green solar hydrogen production to reduce fossil fuel consumption and alleviate environmental burden. The expected outcomes include advanced semiconducting materials, proof-of-concept solar-driven water electrolytic system with a high solar-to-hydrogen conversion efficiency, and cutting-edge knowledge in material science, physical chemistry, and nanotechnology. The success of this project expects to facilitate pilot-scale green hydrogen industry and thus position Australia at the frontier of advanced materials, clean energy, and renewable hydrogen supply technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210100930
Funder
Australian Research Council
Funding Amount
$396,948.00
Summary
Defect Engineering Enabling Efficient Solar Hydrogen Production. The project aims to achieve efficient renewable hydrogen production through solar driven photoelectrochemical water splitting. As a carbon-emission free process, photoelectrochemical water splitting is significant in solar hydrogen supply. The key idea is to design innovative photoelectrode materials using defect engineering strategy which allows more efficient conversion of solar energy to hydrogen. The expected outcomes include h ....Defect Engineering Enabling Efficient Solar Hydrogen Production. The project aims to achieve efficient renewable hydrogen production through solar driven photoelectrochemical water splitting. As a carbon-emission free process, photoelectrochemical water splitting is significant in solar hydrogen supply. The key idea is to design innovative photoelectrode materials using defect engineering strategy which allows more efficient conversion of solar energy to hydrogen. The expected outcomes include high Solar-to-Hydrogen conversion efficiency on the new materials and cutting-edge knowledge in advanced material design. The success of this project will contribute to the implementation of the Australia's National Hydrogen Strategy and position the nation at the frontier of renewable hydrogen supply technologies.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
ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green che ....ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green chemical industries by utilising abundant sunlight, seawater, and waste feedstocks. This should provide significant benefits, through industry collaborations, our new world-leading capacity will train a next generation of game changers to empower emerging carbon industries to solve grand socio-economic challenges, ultimately meeting zero-carbon emissions targets.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
Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalab ....Enabling Next-generation Rechargeable Aluminium-ion Batteries. This project aims to develop a new generation of high performance and low-cost cathode materials for rechargeable aluminium ion batteries. To address the low capacity issue of current cathodes, this project anticipates to generate new knowledge in the material design of novel graphene materials. By developing an innovative surface perforation technique coupled in a continuous production process, this project expects to produce scalable and cost-effective graphene cathodes with a record-high capacity. Expected outcomes of this project include industrial adaptable manufacturing processing and advanced materials for aluminium ion batteries, thus increasing the competitiveness of the partner organisation in the rapid growing graphene market.
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Industrial Transformation Research Hubs - Grant ID: IH190100022
Funder
Australian Research Council
Funding Amount
$4,787,259.00
Summary
ARC Research Hub for Sustainable Crop Protection. The Hub aims to develop and commercialise an innovative biological alternative to chemical fungicides targeting economically significant diseases of broadacre and horticultural crops. It addresses industry challenges of fungicide resistance, chemical residues in food, off-target effects and environmental harm. It builds on ground-breaking ‘BioClay’ platform to deliver pathogen targeting RNA using clay particles as non-genetically modified crop pr ....ARC Research Hub for Sustainable Crop Protection. The Hub aims to develop and commercialise an innovative biological alternative to chemical fungicides targeting economically significant diseases of broadacre and horticultural crops. It addresses industry challenges of fungicide resistance, chemical residues in food, off-target effects and environmental harm. It builds on ground-breaking ‘BioClay’ platform to deliver pathogen targeting RNA using clay particles as non-genetically modified crop protection. An expert multidisciplinary team uniting science, commercial and social licence pathways ensures industry and consumer uptake advancing $60B Australian Agriculture. The Hub translates to increased productivity, market access and enhanced environmental credentials of Australian food.
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