Discovery Early Career Researcher Award - Grant ID: DE120102784
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Water-swellable rubber with nanoparticle-enabled super capacity as smart water-leakage sealant. A novel water-swellable rubber (WSR) sealant with continuous hydrophobic phase and isolated hydrophilic phase is developed for stopping water leakage from gaps and cracks. Nanoparticle-enabled blocks and network channels in rubber matrix effectively improve the integrity and capability of WSR as smart water-leakage sealants in various applications.
Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviou ....Reinforcement of rubber products using nanostructured carbon materials. Reinforcement of rubber products using nanostructured carbon materials. This project aims to use the surface-functionalized nanostructured carbons as fillers to reinforce natural rubber. These fillers should significantly enhance the cross-linking between carbon and rubber matrix, leading to high-performance composite products with long lifetime, high thermal conductivity, high oil resistance and outstanding dynamic behaviours. This project is expected to make Australia capable of fabricating superior rubber-based materials and devices that are comfortable, quiet and energy efficient, for use in aircrafts, automobiles and vessels. It should also reduce the use of non-degradable rubber materials, promoting Australia’s economic development and environment protection.Read moreRead less
Australian Laureate Fellowships - Grant ID: FL210100050
Funder
Australian Research Council
Funding Amount
$3,263,000.00
Summary
Interfacial design and engineering for high-performance batteries. This Fellowship aims to design the next generation of batteries - for use in portable devices, electric vehicles and smart grids - that will overcome the energy density, cycle life, and safety issues, and will contribute to a more sustainable future. This comprehensive and ground-breaking research program combines experiment and theory of electrode/electrolyte interfacial behaviour with materials engineering, to develop a toolkit ....Interfacial design and engineering for high-performance batteries. This Fellowship aims to design the next generation of batteries - for use in portable devices, electric vehicles and smart grids - that will overcome the energy density, cycle life, and safety issues, and will contribute to a more sustainable future. This comprehensive and ground-breaking research program combines experiment and theory of electrode/electrolyte interfacial behaviour with materials engineering, to develop a toolkit of new battery design principles. The program expects to deliver high energy-density batteries with outstanding safety profiles and extended cycle lives. These outcomes would revolutionise battery technologies and position Australia as a global leader in the critical transition to a decarbonised economy.
Read moreRead less
Early Career Industry Fellowships - Grant ID: IE230100048
Funder
Australian Research Council
Funding Amount
$466,097.00
Summary
Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway ....Ammonium-selective membranes to shift water industry into circular economy. The project aims to develop ammonium-selective membranes which are urgently needed in Australian key industries for sustainable ammonia recovery. The project expects to construct the membranes to achieve desirable pore size and surface functionality for fast and selective ammonia transport. The developed membranes should make ammonia recovery from wastewater more effective and sustainable, leading to the healthy waterway and reduced energy for both ammonia production and removal. Recovered ammonia expects to produce valuable products, supporting agriculture industry and hydrogen economy. The developed membranes should enable water industry's shift into circular economy, providing significant economic and environmental benefits to Australia.Read moreRead less
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
Nanostructured non-precious metal and metal-free catalysts for sustainable clean energy generation. The innovative technologies for substitution of precious metal catalysts will be developed and used in fuel cells for clean energy generation in a highly efficient and sustainable form. This effort will lead to the reduction in carbon dioxide emissions and the alleviation of environmental and climate change problems.
Australian Laureate Fellowships - Grant ID: FL170100154
Funder
Australian Research Council
Funding Amount
$2,683,730.00
Summary
Solar-driven sustainable production of fuels and chemicals. This project aims to address the efficient and sustainable production of fuels and chemicals using abundant sources like water, carbon dioxide and sunlight by an integrated reaction system. Through understanding molecular design principles and material engineering, this project expects to develop a range of novel electrocatalysts featuring high activity, efficiency, selectivity and stability for carbon dioxide reduction and hydrogen evo ....Solar-driven sustainable production of fuels and chemicals. This project aims to address the efficient and sustainable production of fuels and chemicals using abundant sources like water, carbon dioxide and sunlight by an integrated reaction system. Through understanding molecular design principles and material engineering, this project expects to develop a range of novel electrocatalysts featuring high activity, efficiency, selectivity and stability for carbon dioxide reduction and hydrogen evolution reactions. These new catalysts will facilitate a hybrid reaction cell as artificial leaf mimics by associating photocatalysis and electrocatalysis processes. The expected outcome of this project is of great importance for solar fuel generation and carbon dioxide utilisation, which are the key energy and environmental challenges facing Australia and the world today. This will provide benefits such as an innovative system of solar energy transformation that will lead to the production of fuels and key chemicals in an efficient, selective and sustainable form, ultimately bringing environmental benefits through much smaller greenhouse gas emissions.Read moreRead less
Photocatalysts for solar hydrogen production. This project aims to develop photocatalysts with adjustable nano-structures and compositions to efficiently and stably catalyse water splitting for hydrogen production using sunlight. This project will include theoretical computations to predict the electronic band structure, adsorption energetics and active sites of photocatalysts, and to guide the design and synthesis of high-performance photocatalysts. These photocatalysts are important for clean ....Photocatalysts for solar hydrogen production. This project aims to develop photocatalysts with adjustable nano-structures and compositions to efficiently and stably catalyse water splitting for hydrogen production using sunlight. This project will include theoretical computations to predict the electronic band structure, adsorption energetics and active sites of photocatalysts, and to guide the design and synthesis of high-performance photocatalysts. These photocatalysts are important for clean and cost-effective solar hydrogen production with zero-emission of greenhouse gases. This project could help resolve Australia and the world’s energy and environmental challenges.Read moreRead less
Photocatalysts for Converting Plastic Wastes into Hydrogen and Chemicals. The aim is to produce new fundamental science for sustainable production of hydrogen and value-added chemicals through a solar-driven photocatalytic approach using abundant plastic wastes and high-performance photocatalysts. A range of active, selective, robust and cheap photocatalysts will be developed for conversion processes at ambient temperatures and pressures, via an interdisciplinary approach combining atomic-level ....Photocatalysts for Converting Plastic Wastes into Hydrogen and Chemicals. The aim is to produce new fundamental science for sustainable production of hydrogen and value-added chemicals through a solar-driven photocatalytic approach using abundant plastic wastes and high-performance photocatalysts. A range of active, selective, robust and cheap photocatalysts will be developed for conversion processes at ambient temperatures and pressures, via an interdisciplinary approach combining atomic-level material design principles, in situ/ex situ characterisations and theoretical computations. Expected outcomes will be of high impact for solar energy use, and fuels/chemicals generation. Environmental impact will derive from consuming abundant plastic wastes; helping mitigate plastic contamination of global concern.Read moreRead less
Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearl ....Develop Catalyst Materials for Future Fuels by Operando Computation. This project aims to design catalyst materials for the production of future fuels (green ammonia, hydrocarbon and alcohol). Using carbon and nitrogen as energy carriers, these fuels are generated from renewable sources such as wind or solar; they are safe, reliable, and possess high energy density. The outcomes include advance in computational electrochemistry to the Opeando level, electrocatalysts design principles with clearly articulated reaction mechanisms, and candidate materials for experimental validation. Facilitated by advanced computation techniques and reliable catalyst materials design procedure, this project will address the biggest challenge in future fuel generation, which is the lack of efficient catalyst materials. Read moreRead less