Efficient Pipeline Transport of Highly Concentrated Wastewater Sludge . This project aims to investigate the rheology and fluid mechanics of highly concentrated wastewater sludges and develop tools to support effective pipeline designs for wastewater treatment plants. The project expects to generate new knowledge about the complex flow of concentrated wastewater which will enable predictive models to support the design and optimization of pipeline transport systems. Expected outcomes of the proj ....Efficient Pipeline Transport of Highly Concentrated Wastewater Sludge . This project aims to investigate the rheology and fluid mechanics of highly concentrated wastewater sludges and develop tools to support effective pipeline designs for wastewater treatment plants. The project expects to generate new knowledge about the complex flow of concentrated wastewater which will enable predictive models to support the design and optimization of pipeline transport systems. Expected outcomes of the project include a new toolkit that will enable wastewater treatment plants to design and optimize both existing and future pipeline systems. This will support the Australian wastewater industry to plan for future growth, increase throughput and efficiency, reduce environmental pollutants, and capital and operating costs.Read moreRead less
Industrial Transformation Research Hubs - Grant ID: IH170100009
Funder
Australian Research Council
Funding Amount
$4,000,000.00
Summary
ARC Research Hub for Energy-efficient Separation. The ARC Research Hub for Energy-efficient Separation aims to develop advanced separation materials, innovative products and smart processes to reduce the energy consumption of separation processes. The Research Hub will create a multi-disciplinary training platform, supplying a highly-trained workforce for the advanced manufacturing sector, particularly in separation technology–a growth area in which Australia can lead the world. The advancement ....ARC Research Hub for Energy-efficient Separation. The ARC Research Hub for Energy-efficient Separation aims to develop advanced separation materials, innovative products and smart processes to reduce the energy consumption of separation processes. The Research Hub will create a multi-disciplinary training platform, supplying a highly-trained workforce for the advanced manufacturing sector, particularly in separation technology–a growth area in which Australia can lead the world. The advancement of Australia’s capability as a world-leading technology provider in manufacturing advanced separation materials and equipment will enable Australian industry to become more energy-efficient and cost-competitive in a global economy.Read moreRead less
Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use ....Engineering two dimensional polymers for membrane-based chemical separation. This project aims to develop novel two-dimensional polymers with precisely controlled pore-sizes for preparing membrane materials which can efficiently separate these gaseous chemicals at ambient temperatures. Key industrial chemical mixtures with similar size and boiling points are difficult to separate by conventional distillation methods. Currently, purification of olefins alone accounts for 0.3% of global energy use. The expected outcomes of the project will have a huge impact on industrial purification processing by providing a disruptive membrane technology, and will significantly reduce energy consumption and open up new routes for resources.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100583
Funder
Australian Research Council
Funding Amount
$445,000.00
Summary
Engineering of biocatalysis in metal-organic frameworks for CO2 conversion. Transforming the greenhouse gas carbon dioxide (CO2) into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to architect a biocascade system in metal-organic frameworks (MOFs) for artificial CO2 conversion. Learned from the living organisms, a whole biocatalysis unit including enzymes and cofactors will be encased and protected in an artificial porous ....Engineering of biocatalysis in metal-organic frameworks for CO2 conversion. Transforming the greenhouse gas carbon dioxide (CO2) into valuable fuels would be beneficial for relieving energy shortage and improving global sustainability. This project aims to architect a biocascade system in metal-organic frameworks (MOFs) for artificial CO2 conversion. Learned from the living organisms, a whole biocatalysis unit including enzymes and cofactors will be encased and protected in an artificial porous polymeric MOF coating. This approach is expected to deliver robust biocatalysts with high reaction-activity and chemo-selectivity in converting CO2 into methanol under the industrial operating condition, involving thermal, pH, and chemical stressors. This advancement will contribute to a carbon-neutral industry and society.Read moreRead less
Advanced Proton-Conducting Ceramic FCs for Power Generation from Ammonia . The project aims to design an innovative ammonia fuel cell using a new perovskite substrate decorated with metal nanoparticles, which demonstrates multi-functionalities and tackles most challenges of conventional fuel cells (FCs). The key concept of this project is the designing of the novel architected smart perovskite as both anode and electrolyte of the fuel cell by systematic modelling and experimental development. T ....Advanced Proton-Conducting Ceramic FCs for Power Generation from Ammonia . The project aims to design an innovative ammonia fuel cell using a new perovskite substrate decorated with metal nanoparticles, which demonstrates multi-functionalities and tackles most challenges of conventional fuel cells (FCs). The key concept of this project is the designing of the novel architected smart perovskite as both anode and electrolyte of the fuel cell by systematic modelling and experimental development. The versatile cell components developed in this project will improve the operational stability and efficiency of the fuel cell, thereby providing a promising pathway for ammonia fuel cells to replace hydrogen fuel cells. This study will reinforce the development of the future supply of reliable, low cost and clean energy. Read moreRead less
Hybrid Hydrocarbon-Carbon Fuel Cells for Long-Life Power Generation. This project aims to design an innovative high-energy portable power source based on a hybrid direct hydrocarbon-carbon fuel cell concept, in which the deposited carbon in the anode of a fuel cell during operation with liquid hydrocarbon fuels can be used as a fuel by subsequent operation in the direct carbon fuel cell mode. The key concept in this project is the controlled deposition and utilization of carbon over the anode of ....Hybrid Hydrocarbon-Carbon Fuel Cells for Long-Life Power Generation. This project aims to design an innovative high-energy portable power source based on a hybrid direct hydrocarbon-carbon fuel cell concept, in which the deposited carbon in the anode of a fuel cell during operation with liquid hydrocarbon fuels can be used as a fuel by subsequent operation in the direct carbon fuel cell mode. The key concept in this project is the controlled deposition and utilization of carbon over the anode of the fuel cell by systematic modelling and experimental development. A continuous power output will be realized via an intelligent cycling mode with an intermittent supply of pure liquid hydrocarbon fuels, thereby achieving an extremely high fuel utilization efficiency in a hybrid electrochemical system.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100445
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Engineering triple-phase boundary for superior aqueous metal-air batteries. This project aims to advance development of high-performance rechargeable aqueous zinc-air (Zn-air) batteries by engineering the triple-phase boundary to increase battery efficiency and power density for practical applications. There is an urgent need to develop sustainable and efficient energy storage and conversion systems to underpin technological development with increasing demand for superior battery technologies fo ....Engineering triple-phase boundary for superior aqueous metal-air batteries. This project aims to advance development of high-performance rechargeable aqueous zinc-air (Zn-air) batteries by engineering the triple-phase boundary to increase battery efficiency and power density for practical applications. There is an urgent need to develop sustainable and efficient energy storage and conversion systems to underpin technological development with increasing demand for superior battery technologies for portable electronics, renewable power sources and electrified vehicles. This project expects to accelerate the commercialisation of rechargeable aqueous Zn-air batteries and progress global commitments to new clean energy sources and storage technologies that are efficient, cost-effective and reliable.Read moreRead less
Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outco ....Electrochemical conversion of carbon dioxide to formic acid. This project aims to develop economical and scalable carbon dioxide electrochemical technologies to convert carbon dioxide in blast furnace flue gas to formic acid as a value-added product in steel-making plants. The project expects to develop new electrochemical catalysts, to optimise the structure of electrodes and ultimately improve carbon dioxide conversion efficiency and reaction selectivity towards formic acid. The expected outcomes of this project will provide an efficient and economically viable electrochemical technology to convert carbon dioxide to a valuable product such as formic acid or syngas, with the potential to significantly reduce the emission of carbon dioxide from steel-making processes and coal-fired power plants.Read moreRead less