Discovery Early Career Researcher Award - Grant ID: DE240100623
Funder
Australian Research Council
Funding Amount
$412,037.00
Summary
New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of ....New electrodes for green electrochemical carbon dioxide capture. This project aims to develop new electrochemical carbon capture technology. By designing and fabricating new functional electrodes and high-performance electrochemical devices based on water and driven by renewable electricity, this project will enhance the ability to capture CO2, the primary greenhouse gas that causes global climate change. Expected outcomes include new multi-dimension electrodes with unique chemistry and state-of-the-art CO2 capture devices plus in-depth knowledge of electrochemical CO2 capture mechanisms for optimised device design and control. Benefits include the development of circular carbon economies with capabilities to effectively capture CO2, supporting Australian industries to achieve net zero emissions by 2050.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100846
Funder
Australian Research Council
Funding Amount
$350,237.00
Summary
Probing Electrochemical Interface in CO2 reduction by Operando Computation. This project aims to explore the structure and dynamics of electrochemical interfaces using operando computational techniques, reveal the influence of catalyst structure and electrolyte environment on catalytic performance, and propose effective design strategies to facilitate the conversion of CO2 to high value-added fuels and chemicals. Innovations are expected in the new mechanism and rational design of electrocatalys ....Probing Electrochemical Interface in CO2 reduction by Operando Computation. This project aims to explore the structure and dynamics of electrochemical interfaces using operando computational techniques, reveal the influence of catalyst structure and electrolyte environment on catalytic performance, and propose effective design strategies to facilitate the conversion of CO2 to high value-added fuels and chemicals. Innovations are expected in the new mechanism and rational design of electrocatalysts. Expected outcomes include the discovery of new mechanisms at the electrochemical interface, the effect of local environmental changes on catalytic performance, and effective strategies for C2+ product. Benefits include a sustainable future for Australia with decreased CO2 emissions and increased green-fuel production.Read moreRead less
Towards Robust Hydrogen Electrode for High-Rate Alkaline Electrolysis. This project aims to develop robust, efficient porous hybrid hydrogen electrodes for electrochemical hydrogen production in anion exchange membrane water electrolyser. anion exchange membrane water electrolyser powered by renewable energy has emerged as a key avenue towards clean hydrogen with zero carbon footprint. However, the electrochemical turnover on the hydrogen electrode has been significantly hindered by the sluggish ....Towards Robust Hydrogen Electrode for High-Rate Alkaline Electrolysis. This project aims to develop robust, efficient porous hybrid hydrogen electrodes for electrochemical hydrogen production in anion exchange membrane water electrolyser. anion exchange membrane water electrolyser powered by renewable energy has emerged as a key avenue towards clean hydrogen with zero carbon footprint. However, the electrochemical turnover on the hydrogen electrode has been significantly hindered by the sluggish reaction kinetics in alkaline solution. The project is expected to generate cost-effective hydrogen electrodes for hydrogen electrolyzers, advanced knowledge in the electrode material engineering, electrochemical reaction mechanistic insights, and eventually promoted development of disruptive electrolysis technology.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100159
Funder
Australian Research Council
Funding Amount
$473,847.00
Summary
Developing Room-Temperature Liquid Metal Batteries for Safe Energy Storage. To overcome safety issues intrinsic to the prevalent solid metal anodes in battery technology, this project aims to develop room-temperature liquid metal batteries by employing liquid Sodium-Potassium alloy. Innovations will span the development of the electrode concept, interface-oriented electrolyte design guided by theory and experiment, and prototype battery cell examples to illustrate how high round-trip efficiencie ....Developing Room-Temperature Liquid Metal Batteries for Safe Energy Storage. To overcome safety issues intrinsic to the prevalent solid metal anodes in battery technology, this project aims to develop room-temperature liquid metal batteries by employing liquid Sodium-Potassium alloy. Innovations will span the development of the electrode concept, interface-oriented electrolyte design guided by theory and experiment, and prototype battery cell examples to illustrate how high round-trip efficiencies at fast charging can be achieved over a prolonged time. The anticipated outcomes would transform battery technology concepts while providing a critical scientific basis for commercialisation. Further, the success of this project would help Australia realise its shift from traditional to emerging sustainable energy 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
Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional ....Engineered redox polymers for catalytic water purification. This project aims to develop a novel family of chemically and structurally controlled redox polymer as metal-free catalysts for wastewater micropollutant treatment. Innovations lie in the synthesis of high-performance and nanostructured carbon-based materials, multiscale modeling, and in situ characterizations for understanding structure-property relationship in carbon catalysis. Expected outcomes will deliver innovations in functional materials, mechanism, catalytic engineering, and sustainable separation processes. This project will provide significant benefits in renovating smart nanomaterials in advanced manufacturing and clean environmental technologies, promoting Australia’s economic development and environment protection.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
Discovery Early Career Researcher Award - Grant ID: DE230100357
Funder
Australian Research Council
Funding Amount
$409,118.00
Summary
Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the ....Catalyst design for converting carbon dioxide into valuable chemicals. This project aims to use solar energy to convert carbon dioxide, the primary greenhouse gas that drives global climate change, into valuable chemicals via catalytic reduction. This project expects to facilitate the selective production of valuable ethylene from carbon dioxide reduction by developing novel cocatalyst materials derived from metal-oxo cluster molecules. Expected outcomes include fundamental understanding of the structure-property relationship in new catalytic systems, and technological breakthroughs in reducing carbon dioxide emissions. The success of this project will bring significant environmental and economic benefits, and position Australia at the frontier of global transition to a low-carbon economy.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101021
Funder
Australian Research Council
Funding Amount
$435,000.00
Summary
Developing tunable nanoporous graphene membranes for resource recovery. This project aims to advance the development of atom-thick nanoporous graphene molecular filters (membranes) to tackle challenging separations in the chemical industry and open new pathways to recover valuable materials from waste streams. The extreme thinness of these membranes allows them to separate molecules with a fraction of the energy typically used by commercially available technologies. The proposed electrochemical ....Developing tunable nanoporous graphene membranes for resource recovery. This project aims to advance the development of atom-thick nanoporous graphene molecular filters (membranes) to tackle challenging separations in the chemical industry and open new pathways to recover valuable materials from waste streams. The extreme thinness of these membranes allows them to separate molecules with a fraction of the energy typically used by commercially available technologies. The proposed electrochemical platform is expected to fabricate and operate fit-for-purpose membranes with unprecedented control. Significant new knowledge in the areas of material engineering, nanofluidics, and membranes is expected from exploiting this platform to study ion transport under confinement and make membranes for resource recovery.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230100789
Funder
Australian Research Council
Funding Amount
$397,613.00
Summary
Photo-thermal ammonia decomposition . This project aims to develop of novel catalysts targeted to utilise light and heat for the photo-thermal decomposition of ammonia to produce hydrogen and generate new understanding on the role of light in thermal catalytic reactions. The emergence of the hydrogen economy has resulted in the urgent need for safe and efficient hydrogen transport and storage vectors. Ammonia, a hydrogen carrier, is being increasingly considered as a potential key to facilitate ....Photo-thermal ammonia decomposition . This project aims to develop of novel catalysts targeted to utilise light and heat for the photo-thermal decomposition of ammonia to produce hydrogen and generate new understanding on the role of light in thermal catalytic reactions. The emergence of the hydrogen economy has resulted in the urgent need for safe and efficient hydrogen transport and storage vectors. Ammonia, a hydrogen carrier, is being increasingly considered as a potential key to facilitate the hydrogen economy due to its relative ease of storage. The development of catalysts tailored toward capturing light for ammonia decomposition will enable a new potential pathway for the hydrogen economy, with ammonia as a hydrogen vector. Read moreRead less