Big Data-based Distributed Control using a Behavioural Systems Framework. With Industry 4.0 turning into reality, industrial processes are becoming distributed cyber-physical systems which generate, process, store and communicate large amounts of data. Using the behavioural systems framework, this project aims to develop a novel distributed control approach for complex processes directly based on big process data. A new model-free framework will be developed to represent and analyse the process/ ....Big Data-based Distributed Control using a Behavioural Systems Framework. With Industry 4.0 turning into reality, industrial processes are becoming distributed cyber-physical systems which generate, process, store and communicate large amounts of data. Using the behavioural systems framework, this project aims to develop a novel distributed control approach for complex processes directly based on big process data. A new model-free framework will be developed to represent and analyse the process/controller networks and interaction effects, and determine the feasibility of desired control performance under distributed control. Novel big data-based distributed control design approaches will be developed by extending the dissipativity, contraction and differential dissipativity conditions for behavioural systems.Read moreRead less
Nano-engineering of hierarchical catalysts for renewable chemicals. Producing high-value chemicals based on renewable alternatives -biomass resources is vital for the climate and a sustainable economy. This project will develop a unique nano-engineering approach to design hierarchical catalysts for the selective conversion of biomass into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts and th ....Nano-engineering of hierarchical catalysts for renewable chemicals. Producing high-value chemicals based on renewable alternatives -biomass resources is vital for the climate and a sustainable economy. This project will develop a unique nano-engineering approach to design hierarchical catalysts for the selective conversion of biomass into tailor-made products. Advanced in situ spectroscopic techniques will be employed to establish the structure-reactivity relationship of working catalysts and thereby manipulate the key factors governing the activity/selectivity. Such cutting-edge knowledge gained is crucial for optimising process efficiency and resource utilisation, which is essential for the success of the biorefining industry and a more environmentally-friendly chemical economy in Australia.Read moreRead less
Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty ....Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty chemicals. The outcomes and further technology adoptions will extend the capacity of the Partner Organisation for producing specialty battery materials. The outcomes could help Australia’s battery industry switch to a more diversified pathway, which benefits the economic development of Australia in a long term.Read moreRead less
Dual-membrane upgrading towards sustainable wastewater management. Water utilities in Australia have set aspirational targets for energy- and carbon-neutral wastewater services by as early as 2030. However, these two aims are often incompatible because of excessive aeration energy consumption and substantial greenhouse gas emissions in wastewater treatment plants. This project aims to develop a novel biotechnology that enables simultaneous bioenergy recovery, cost-efficient nitrogen removal and ....Dual-membrane upgrading towards sustainable wastewater management. Water utilities in Australia have set aspirational targets for energy- and carbon-neutral wastewater services by as early as 2030. However, these two aims are often incompatible because of excessive aeration energy consumption and substantial greenhouse gas emissions in wastewater treatment plants. This project aims to develop a novel biotechnology that enables simultaneous bioenergy recovery, cost-efficient nitrogen removal and mitigation of greenhouse gas emissions, thus bringing multifaceted benefits to wastewater management. The project will provide strong support to the Australian water industry in their endeavour to achieve economically and environmentally sustainable wastewater services.Read moreRead less
A unifying model for ion exchange membranes – towards a low carbon future. Polymeric ion exchange membranes are key to emerging renewable energy systems and bioprocessing applications. Advances in this field are currently impeded by a focus on their performance in idealised pure solutions and siloed research. This project aims to draw together fundamental and applied research to develop an innovative, unifying model for the transport of both charged ions and uncharged molecules through these mem ....A unifying model for ion exchange membranes – towards a low carbon future. Polymeric ion exchange membranes are key to emerging renewable energy systems and bioprocessing applications. Advances in this field are currently impeded by a focus on their performance in idealised pure solutions and siloed research. This project aims to draw together fundamental and applied research to develop an innovative, unifying model for the transport of both charged ions and uncharged molecules through these membranes within complex, multicomponent mixtures. The team will build on strong collaborations to drive uptake of the new model within the clean energy and CO2 reduction sectors to advance the abatement of Australian emissions; and will prepare young researchers for a role within these emerging fields.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100722
Funder
Australian Research Council
Funding Amount
$362,245.00
Summary
Enabling Novel Hydrogen Storage via Combustible Ice for a Low-Carbon Future. This project aims to develop a new method for sustainable hydrogen storage. Hydrogen is vital for decarbonising Australia's economy, yet finding an efficient way for hydrogen storage is a global challenge. This project seeks to encapsulate hydrogen effectively in water to produce hydrogen-carrying combustible ice for efficient large-scale hydrogen storage, taking the advantages of water as the safest and cheapest raw ma ....Enabling Novel Hydrogen Storage via Combustible Ice for a Low-Carbon Future. This project aims to develop a new method for sustainable hydrogen storage. Hydrogen is vital for decarbonising Australia's economy, yet finding an efficient way for hydrogen storage is a global challenge. This project seeks to encapsulate hydrogen effectively in water to produce hydrogen-carrying combustible ice for efficient large-scale hydrogen storage, taking the advantages of water as the safest and cheapest raw material. Expected outcomes are cutting-edge knowledge and a new pathway of hydrogen storage. This project would contribute to turning Australia’s abundant renewable energy resources into substantial economic and environmental benefits and promote Australia's competitive edge in the global transition toward a low-carbon future.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE230101044
Funder
Australian Research Council
Funding Amount
$444,318.00
Summary
Bio-inspired nanomaterials with tunable drug loading and controlled release. This project aims to develop new platform technologies for making bio-inspired nanomaterials with tunable drug loading and controlled release. This project will revolutionise current approaches to make lipid nanoparticles camouflaged with natural cell membranes for delivery of both insoluble and soluble drugs. Significant outcomes will include a novel commercially relevant salt-induced nanoprecipitation platform technol ....Bio-inspired nanomaterials with tunable drug loading and controlled release. This project aims to develop new platform technologies for making bio-inspired nanomaterials with tunable drug loading and controlled release. This project will revolutionise current approaches to make lipid nanoparticles camouflaged with natural cell membranes for delivery of both insoluble and soluble drugs. Significant outcomes will include a novel commercially relevant salt-induced nanoprecipitation platform technology for making precisely engineered nanomaterials with tailored functions for applications in controlled release and targeted delivery. Benefits include securing a sustainable future for Australia, with new nanotechnology strategies for advanced manufacturing.Read moreRead less
High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing ....High activity catalysts for CO2 recycling to valuable chemical products. This proposal targets the development of novel porous solid catalysts, containing highly dispersed metal clusters that provide exceptional activity for the conversion (recycling) of carbon dioxide to fuels and other higher value chemical products. These novel materials will improve the productivity and/or reduce the energy required to facilitate the CO2 conversion, thereby reducing costs for industry, whilst also providing environmental benefit by carbon dioxide utilisation.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE240100863
Funder
Australian Research Council
Funding Amount
$460,847.00
Summary
High-Efficiency, Modular and Low-Cost Hydrogen Liquefaction and Storage . Australia’s first modular hydrogen liquefaction and storage. This project aims to develop a novel multi-faceted cooling system and software to increase efficiency, lower cost, and improve the safety of hydrogen liquefaction and storage. The project will establish a new multi-disciplinary research capability in Australia and expand our fundamental knowledge to model, design, and build modular liquefaction and zero-boil-off ....High-Efficiency, Modular and Low-Cost Hydrogen Liquefaction and Storage . Australia’s first modular hydrogen liquefaction and storage. This project aims to develop a novel multi-faceted cooling system and software to increase efficiency, lower cost, and improve the safety of hydrogen liquefaction and storage. The project will establish a new multi-disciplinary research capability in Australia and expand our fundamental knowledge to model, design, and build modular liquefaction and zero-boil-off storage systems, allowing widespread distribution and usage of hydrogen. It will create a paradigm shift from traditional scale-up to modern number-up approaches. This level of innovation is crucial for Australia to lead the world in hydrogen and also enable accessible and sustainable clean energy sources for Australians.Read moreRead less
Interfacial engineering of multilayered metal organic framework membranes . Metal-organic frameworks are a popular class of microporous materials with tunable structural properties and functionalities. This project aims to investigate the designed synthesis of thin, hierarchically structured films of this material on membranes, which displays extraordinary ion selectivity and ion rectification properties. A better understanding of the interfacial properties will be gained through advanced charac ....Interfacial engineering of multilayered metal organic framework membranes . Metal-organic frameworks are a popular class of microporous materials with tunable structural properties and functionalities. This project aims to investigate the designed synthesis of thin, hierarchically structured films of this material on membranes, which displays extraordinary ion selectivity and ion rectification properties. A better understanding of the interfacial properties will be gained through advanced characterisation, and with proper design and tuning of the film, will ultimately lead to the development of high performing ion-selective membranes that will be applied for energy storage and separation applications. This project is expected to benefit Australia’s renewable energy and resource sectors.Read moreRead less