Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100137
Funder
Australian Research Council
Funding Amount
$358,275.00
Summary
Integrated thin film facility for catalysis and energy materials research. This project aims to establish thin film fabrication with catalytic/gas sorption characterisation needed for energy research. This project will overcome current limitations in advanced energy materials design via wet chemical methods. It will enable materials synthesis and characterisation toward thermal/photo/electro-catalytic, hydrogen storage, and battery technologies. The facility is expected to drive fundamental conc ....Integrated thin film facility for catalysis and energy materials research. This project aims to establish thin film fabrication with catalytic/gas sorption characterisation needed for energy research. This project will overcome current limitations in advanced energy materials design via wet chemical methods. It will enable materials synthesis and characterisation toward thermal/photo/electro-catalytic, hydrogen storage, and battery technologies. The facility is expected to drive fundamental concepts, and enable combinatorial search and new thin film technology. It is anticipated that this facility will increase Australia’s international competitiveness in the development of advanced energy materials.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100126
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
An integrated kinetic measurement system enabling efficient solar energy conversion. This measurement facility will underpin advances in the fundamental understanding of new semiconducting materials for high efficiency light-driven energy conversion systems. The outcomes of the research at the facility will lead to significant economic and environmental benefits for many industries, such as low cost solar cells and water purifications.
Discovery Early Career Researcher Award - Grant ID: DE180100523
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
Tailoring efficient photo-thermal catalysts for carbon dioxide reduction. This project aims to develop a highly solar-efficient and environmentally-friendly approach to reducing greenhouse gas carbon dioxide (CO2) into valuable fuels that will be beneficial for relieving energy shortage and improving global sustainability. New multifunctional catalysts will be constructed by combining various catalytic active centres and optical promoters, for optimising energy efficiency and reaction activity. ....Tailoring efficient photo-thermal catalysts for carbon dioxide reduction. This project aims to develop a highly solar-efficient and environmentally-friendly approach to reducing greenhouse gas carbon dioxide (CO2) into valuable fuels that will be beneficial for relieving energy shortage and improving global sustainability. New multifunctional catalysts will be constructed by combining various catalytic active centres and optical promoters, for optimising energy efficiency and reaction activity. Such knowledge gained is essential for the success of the low-carbon industry and a more environmentally-friendly energy economy in Australia.Read moreRead less
A New Photocatalytic System for Solar-to-Chemical Energy Conversion. The expected outcomes of this program are a new class of photocatalyst systems for converting waste products into valuable chemicals using solar energy. Using advanced materials and photocatalysis, the project aims to develop a new class of bi-functional photoelectrochemical (PEC) systems for application in waste brine treatment and valuable chemical generation. The key concept lies in the innovative design of layered semicondu ....A New Photocatalytic System for Solar-to-Chemical Energy Conversion. The expected outcomes of this program are a new class of photocatalyst systems for converting waste products into valuable chemicals using solar energy. Using advanced materials and photocatalysis, the project aims to develop a new class of bi-functional photoelectrochemical (PEC) systems for application in waste brine treatment and valuable chemical generation. The key concept lies in the innovative design of layered semiconductors as efficient and stable photocatalysts and their integration into PEC reaction systems for simultaneous solar hydrogen and valuable chemicals (eg bromine) generation from brine. The project aims to advance fundamental understanding of the photocatalytic water-splitting concept to other waste product splitting.Read moreRead less
Highly-efficient, reversible fuel cell. This project aims to develop a reversible fuel cell - electrolyser capable of storing electricity (in the form of hydrogen gas) with the same overall energy efficiency as the best present storage system, pumped hydro. Whereas pumped hydro requires large infrastructure like dams, the proposed cell will be extremely inexpensive and easily scalable.
Australian Laureate Fellowships - Grant ID: FL140100081
Funder
Australian Research Council
Funding Amount
$2,380,000.00
Summary
Engineering hybrid photocatalytic systems for sustainable fuel generation. Engineering hybrid photocatalytic systems for sustainable fuel generation. The project aims to develop next generation hybrid photo-(co)catalyst and gaseous photoelectrode systems that will effectively harness solar energy to transform carbon dioxide into sustainable fuels using a multi-scale approach: designing hetero-structured material systems; elucidating surface reaction mechanisms, and engineering coupled photo/ther ....Engineering hybrid photocatalytic systems for sustainable fuel generation. Engineering hybrid photocatalytic systems for sustainable fuel generation. The project aims to develop next generation hybrid photo-(co)catalyst and gaseous photoelectrode systems that will effectively harness solar energy to transform carbon dioxide into sustainable fuels using a multi-scale approach: designing hetero-structured material systems; elucidating surface reaction mechanisms, and engineering coupled photo/thermal-catalytic and unique gaseous photoelectrochemical systems. This project aims to yield fundamental new knowledge for the economical conversion and storage of solar energy as an environmentally benign chemical fuel, as well as create contemporary material systems and reactors for photo- and thermal-catalysis and photoelectrochemical reactions that utilise carbon dioxide as a feedstock.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100098
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
A comprehensive gas/vapour sorption facility for the fast advancement of decarbonised energy technologies. Solutions to clean energy production, storage and use are critical to Australia’s prosperity, yet there is a significant lack of targeted research facilities for the development of the highly needed materials and technologies for powering a sustainable Australia. This facility will bring research efforts closer to practical solutions.
Metal-support interactions: single atoms Vs nanoclusters. This project aims to fundamentally understand the catalytic mechanism at an atomic level through metal-metal and metal-metal/support interactions. The optimised configuration of active sites for a specific reaction is consequently identified, providing the design principles of novel catalysts. The precisely control of synthesis for such active sites and assembly of the target active sites into a catalyst will deliver a completely new meth ....Metal-support interactions: single atoms Vs nanoclusters. This project aims to fundamentally understand the catalytic mechanism at an atomic level through metal-metal and metal-metal/support interactions. The optimised configuration of active sites for a specific reaction is consequently identified, providing the design principles of novel catalysts. The precisely control of synthesis for such active sites and assembly of the target active sites into a catalyst will deliver a completely new methodology for catalyst development. The expected outcomes from this project include new science and knowledge of Chemistry, new design philosophy and strategies for catalysts, and the highly efficient catalysts for electrocatalytic reactions, benefiting Australian renewable energy research and industry.Read moreRead less
Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to ....Integrated photo and thermal catalysis for economic carbon dioxide conversion to fuels. The project aims to develop an integrated process for simultaneously photo- and thermal-catalytic conversion of carbon dioxide and water vapour to hydrocarbon fuels and chemicals using solar light and waste heat from flue gas. This project will design and make multi-functional catalysts based on zirconium metal organic frameworks, incorporating quantum dots and metal nanoclusters. This project is expected to develop an advanced materials system, reduce carbon dioxide and use it to produce fuel, and harness solar energy. The project should advance Australia’s leading role in reducing carbon emission, and producing clean energy and nanotechnology.Read moreRead less
CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable e ....CO2 Utilisation for Energy Storage. This project aims to develop a novel technology that can convert carbon dioxide into useful products while storing intermittent renewable energy as green stable chemical energy. The project plans to focus on the development of a robust cathode for the conversion of carbon dioxide with optimum physical and chemical structure to achieve long-term stable performance. This technology would make a significant contribution to increasing the proportion of renewable energy in our energy supply and reducing our carbon dioxide emissions.Read moreRead less