Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100185
Funder
Australian Research Council
Funding Amount
$400,000.00
Summary
High throughput microbial microculture and single cell analysis facility. High throughput microbial microculture and single cell analysis facility:
To support the emerging research area of microbial heterogeneity and variation in response to conditions, this project aims to establish a facility centred on a 24-microbioreactor system for high throughput microbial culturing. This is designed to be connected to two complementary analysis techniques – flow cytometry and high resolution infra-red mi ....High throughput microbial microculture and single cell analysis facility. High throughput microbial microculture and single cell analysis facility:
To support the emerging research area of microbial heterogeneity and variation in response to conditions, this project aims to establish a facility centred on a 24-microbioreactor system for high throughput microbial culturing. This is designed to be connected to two complementary analysis techniques – flow cytometry and high resolution infra-red microscopy – for the non-destructive measurement of metabolic activities and mapping of constituents of whole cells. This would help us to determine the variation in response between organisms, to guide cell line development and process optimisation for a wide range of biotechnology applications. Expected outcomes may apply to Australia’s brewing, wine, food processing, aquaculture, biofuels, biomedical and biotechnology industries.Read moreRead less
Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunct ....Regulating guest transport in microporous materials by electric field. This project aims to address the fundamentals and applications of regulating micropore accessibility. It has long been known that some highly adsorbing molecular sieves suddenly become inaccessible to gases below certain temperatures. Following a recent breakthrough in elucidating the mechanism of such temperature-regulated guest admission, this project will explore electrical regulation of micropore accessibility in conjunction with developing new mechanisms, materials, and control tools for applications, including tunable molecular sieves, valves and gas encapsulation devices. The outcomes of this project will generate new knowledge in the active manipulation of the admission and release of guest molecules in/out of microporous materials, and establish new expertise and capabilities that can advance gas separation, storage and sensing technologies. It is expected that this project will contribute to the long term benefit in low emission energy supplies and Australia's natural gas industry, improve the separation efficiency of our chemical industry, and boost the development of the hydrogen 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
Special Research Initiatives - Grant ID: SR180100036
Funder
Australian Research Council
Funding Amount
$650,054.00
Summary
Remediation of PFAS in current and legacy biosolids application sites. This project aims to develop novel immobilisation, adsorption and/or thermal destruction methods for biosolids, soil and groundwater in current and legacy per- and poly-fluroalkyl substance (PFAS) sites receiving biosolids. Biosolids generated during waste water treatment carry an unknown potential risk of soil and groundwater PFAS contamination, through their application in agriculture and rehabilitation sites. This project ....Remediation of PFAS in current and legacy biosolids application sites. This project aims to develop novel immobilisation, adsorption and/or thermal destruction methods for biosolids, soil and groundwater in current and legacy per- and poly-fluroalkyl substance (PFAS) sites receiving biosolids. Biosolids generated during waste water treatment carry an unknown potential risk of soil and groundwater PFAS contamination, through their application in agriculture and rehabilitation sites. This project will provide the first major investigation of the release, fate and remediation of perfluorinated compounds in relation to their environmental pathways through wastewater treatment plants in Australia. The data will be evaluated to determine if perfluorinated compounds should be further incorporated into Australian soil and water quality monitoring programs. The project will provide evidence of research advice and methodologies being successfully adopted by water industry end-users, government regulatory agencies and private remediation industries.Read moreRead less
Micromechanic modelling and analysis of the dynamics of non-spherical particles coupled with fluid flow. This project aims to develop advanced theories and mathematical models to describe the packing and flow of non-spherical particles coupled with fluid flow. This will be achieved through a combined theoretical and experimental program, involving the use of advanced discrete particle simulation and detailed analysis of packing/flow structures, particle-particle and particle-fluid interactions a ....Micromechanic modelling and analysis of the dynamics of non-spherical particles coupled with fluid flow. This project aims to develop advanced theories and mathematical models to describe the packing and flow of non-spherical particles coupled with fluid flow. This will be achieved through a combined theoretical and experimental program, involving the use of advanced discrete particle simulation and detailed analysis of packing/flow structures, particle-particle and particle-fluid interactions at a particle scale. Research outcomes including theories, computer models and simulation techniques will be applied to representative industrial operations of importance to Australia's economic and technological future.Read moreRead less
Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent e ....Rare Earth Metal Separation by Polymer Inclusion Membranes. The project aims to develop a novel hydrometallurgical method for the separation of the rare earth metals dysprosium and terbium from mixed rare earth metal solutions using polymer inclusion membranes with a crosslinked or non-crosslinked polymer backbone. These metals are crucial for the manufacturing of advanced technology products. The membrane-based method is expected to offer significant advantages over the currently used solvent extraction methods by eliminating the use of solvents and conducting the separation as a continuous process where the extraction and back-extraction steps take place simultaneously. These advantages are expected to make the separation process more cost-effective and drastically reduce its environmental impact.Read moreRead less
Next generation gas separations via innovative adsorption technologies. This project aims to develop new gas separation technologies that combine novel materials and pressure swing adsorption cycles to deliver inexpensive industrial processes capable of both high recovery and high purity products. The project will advance our ability to manipulate the phenomenon of regulated guest admission into microporous materials, and integrate such materials within new types of dual-reflux adsorption cycles ....Next generation gas separations via innovative adsorption technologies. This project aims to develop new gas separation technologies that combine novel materials and pressure swing adsorption cycles to deliver inexpensive industrial processes capable of both high recovery and high purity products. The project will advance our ability to manipulate the phenomenon of regulated guest admission into microporous materials, and integrate such materials within new types of dual-reflux adsorption cycles that deliver multiple refined gas products. Successful implementation of these industrial developments will increase Australia's access to cheap supplies of natural gas, encourage the broader use of biomass, lower the carbon emissions of industrial processes, and efficiently recover high-value compounds only present at trace concentrations.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100266
Funder
Australian Research Council
Funding Amount
$367,446.00
Summary
Granular interfaces for sustainable processing of raw materials. This project aims to develop an innovative interface model and a comprehensive understanding of the interfacial behaviours between granular materials using advanced numerical, experimental and theoretical approaches. This project expects to generate new knowledge of mixing and segregation in particle science and technology and a practical guide to applications. Expected outcomes of this project include the enhanced competitiveness ....Granular interfaces for sustainable processing of raw materials. This project aims to develop an innovative interface model and a comprehensive understanding of the interfacial behaviours between granular materials using advanced numerical, experimental and theoretical approaches. This project expects to generate new knowledge of mixing and segregation in particle science and technology and a practical guide to applications. Expected outcomes of this project include the enhanced competitiveness of Australia and energy efficiency in its important industries such as minerals, metallurgical, chemical, energy and pharmaceutical. These outcomes should provide significant benefits such as mitigated emissions and global warming in a carbon and resource constrained world.Read moreRead less
Improving performance of solvent extraction equipment for the minerals processing industry. This project will develop a fundamental understanding of how a new type of solvent extraction column, which was recently introduced to the mining industry, responds to changes in process conditions and operating parameters. This will enable the potential for optimal and efficient use of these assets and ensure a competitive advantage for Australia's biggest export earner.
Nano-engineered catalysts for sustainable fuel production from waste . This project aims to address two major problems simultaneously-reducing the burden of non-recyclable waste currently going to landfill in Australia, and offsetting Australia’s reliance on imported diesel to support industry and transport needs. While approximately 95% of diesel consumed in Australia is imported, vast quantities of carbon-based waste ends up in landfill. Municipal Solid Waste (MSW) is a mixture of plant-based ....Nano-engineered catalysts for sustainable fuel production from waste . This project aims to address two major problems simultaneously-reducing the burden of non-recyclable waste currently going to landfill in Australia, and offsetting Australia’s reliance on imported diesel to support industry and transport needs. While approximately 95% of diesel consumed in Australia is imported, vast quantities of carbon-based waste ends up in landfill. Municipal Solid Waste (MSW) is a mixture of plant-based waste (including food, garden, paper, and wood) and fossil-fuel derived materials (plastics). Using an innovative and environmentally-sustainable catalytic process, the outcomes of this project are aimed alleviating Australia’s dependence on diesel fuel imports and better waste management solutions in Australia.Read moreRead less