Periodic nano-ratchets: a new paradigm for biomolecule separation. This project proposes the theoretical and experimental study of a new separation principle. The platform technologies developed from this research will see wide ranging applications. They will reveal new insights into fundamental phenomena of membranes and separation processes underpinning development of new generation of separation technologies. New membranes and microchip separation devices which can be applied to genomic, prot ....Periodic nano-ratchets: a new paradigm for biomolecule separation. This project proposes the theoretical and experimental study of a new separation principle. The platform technologies developed from this research will see wide ranging applications. They will reveal new insights into fundamental phenomena of membranes and separation processes underpinning development of new generation of separation technologies. New membranes and microchip separation devices which can be applied to genomic, proteomic, forensic and a range medical, biotechnological and analytical applications will be readily achievable. This is an international and interdisciplinary research project and its outcomes will enhance Australia's ability in frontier technologies, advanced materials.Read moreRead less
Selective enrichment of proteins using micro-Gradiflow technology and characterisation of proteins using LC-MS/MS. This project describes crucial areas for the technology development of protein enrichment and fractionation. While current techniques are powerful, the usefulness to identify and characterise proteins of low abundance from massively complex samples in the presence of abundant proteins is limited and requires up to mililitre volumes. We intend to develop the micro-Gradiflow technolog ....Selective enrichment of proteins using micro-Gradiflow technology and characterisation of proteins using LC-MS/MS. This project describes crucial areas for the technology development of protein enrichment and fractionation. While current techniques are powerful, the usefulness to identify and characterise proteins of low abundance from massively complex samples in the presence of abundant proteins is limited and requires up to mililitre volumes. We intend to develop the micro-Gradiflow technology in association with Gradipore as a means of protein fractionation using microlitre volumes of sample. This technology will be applicable to all areas of proteomic research and in particular to the study of cell differentiation. The outcome for Australian industry, our competitiveness both industrial and scientific, and the potential for economic advancement is tremendous.Read moreRead less
Development of novel passive sampling devices for ammonia monitoring. This project will develop novel inexpensive passive samplers for ammonia which is an indicator for faecal contamination in stormwater. These devices will increase dramatically the efficiency in isolating intermittent faecal contamination sources in drainage networks by eliminating the need for extensive manual sampling and inspection operations.
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
Development of bagasse fly ash adsorbent for the removal of impurities in sugar process streams. High quality raw sugar attracts a premium and is important in maintaining market access in these times of increasing competition and excess production from overseas producers. Options that are in current use in Australia for the removal of colour and impurities are not very cost effective. This research will develop a sugarcane waste (fly ash) into an adsorbent for the removal of these impurities. Th ....Development of bagasse fly ash adsorbent for the removal of impurities in sugar process streams. High quality raw sugar attracts a premium and is important in maintaining market access in these times of increasing competition and excess production from overseas producers. Options that are in current use in Australia for the removal of colour and impurities are not very cost effective. This research will develop a sugarcane waste (fly ash) into an adsorbent for the removal of these impurities. This will enable the sugar industry and rural communities to become more sustainable through enhanced competitiveness and diversification through co-generation and value-added products. This project will also reduce the disposal costs ($2 M/y) for the sugar industry and minimize environmental pollution due to the use of a waste product.Read moreRead less
On-site and comprehensive technology for chemical weapons, toxins and drugs. This project aims to evaluate and validate broad capabilities of advanced chemical profiling using benchtop and portable gas chromatography–mass spectrometry for forensic applications. Establishing guidelines for sampling various matrices, key performance measures, and improving chemical and residue identification for drug profiling in clandestine laboratories and public venues, chemical warfare agents, and chemical tox ....On-site and comprehensive technology for chemical weapons, toxins and drugs. This project aims to evaluate and validate broad capabilities of advanced chemical profiling using benchtop and portable gas chromatography–mass spectrometry for forensic applications. Establishing guidelines for sampling various matrices, key performance measures, and improving chemical and residue identification for drug profiling in clandestine laboratories and public venues, chemical warfare agents, and chemical toxins is expected. Anticipated outcomes for project partners in defence and policing include detailed knowledge of sample and residue composition and on-site assessment of chemical risks with immediate feedback. Benefits should include improved community and security services safety by enhanced detection of harmful substances.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC140100022
Funder
Australian Research Council
Funding Amount
$2,148,935.00
Summary
ARC Training Centre for Portable Analytical Separation Technologies. ARC Training Centre for Portable Analytical Separation Technologies. Portable analytical separation systems will enable point-of sample analysis for complex samples in food, environmental and clinical applications. The Training Centre aims to train the next generation of industry-ready Australian researchers through creating a sustainable research partnership between university-based researchers and Australian industry focused ....ARC Training Centre for Portable Analytical Separation Technologies. ARC Training Centre for Portable Analytical Separation Technologies. Portable analytical separation systems will enable point-of sample analysis for complex samples in food, environmental and clinical applications. The Training Centre aims to train the next generation of industry-ready Australian researchers through creating a sustainable research partnership between university-based researchers and Australian industry focused on developing new capabilities and technologies that have the potential to facilitate, support, or catalyse the progressive deployment of portable separation science technologies into society. This will enable the development of new, portable and affordable analytical separation systems and contribute to creating a sustainable, globally competitive manufacturing industry in Australia.Read moreRead less
Hatchery production of rock lobster seedstock for aquaculture and enhancement with emphasis on ozonation of culture water to reduce disease. The strong and growing worldwide demand for a range of lobster products cannot be fulfilled by existing wild fisheries. Only the sustainable production of lobsters using hatchery seedstock will satisfy the needs of aquaculture and the possibility of enhancing and reseeding the fishery. Lobster aquaculture will provide a new high-value industry for coastal r ....Hatchery production of rock lobster seedstock for aquaculture and enhancement with emphasis on ozonation of culture water to reduce disease. The strong and growing worldwide demand for a range of lobster products cannot be fulfilled by existing wild fisheries. Only the sustainable production of lobsters using hatchery seedstock will satisfy the needs of aquaculture and the possibility of enhancing and reseeding the fishery. Lobster aquaculture will provide a new high-value industry for coastal rural Australia, especially in areas with existing fishing and aquaculture enterprises. This project will develop new technologies to address the challenging target of producing commercial quantities of juvenile lobsters for aquaculture and enhancement.Read moreRead less
Self-assembled nanolayers of functionalised latexes as selective and adaptable nano-stationary phases in separation science. A new approach is proposed for the design and synthesis of functionalised ion-exchange stationary phases for analytical nano-separation methods. Desired charged functional groups are first affixed chemically onto nanometre sized latex particles and these particles are then self-assembled mechanically as monoloayer coatings onto a suitable supporting template such as fused ....Self-assembled nanolayers of functionalised latexes as selective and adaptable nano-stationary phases in separation science. A new approach is proposed for the design and synthesis of functionalised ion-exchange stationary phases for analytical nano-separation methods. Desired charged functional groups are first affixed chemically onto nanometre sized latex particles and these particles are then self-assembled mechanically as monoloayer coatings onto a suitable supporting template such as fused silica, monolithic silica or polymer beds, microfibres or microtubes, and channels in microchips. The resultant coated surface then acts as a highly efficient ion-exchange stationary phase which will be used in a wide range of separation technologies including ion chromatography, capillary electrophoresis, capillary electrochromatography and solid-phase microextraction.Read moreRead less
Separation science based on nanoparticle-coated monolithic scaffold stationary phases. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pre-and post-blast identification of explosives in counter-ter ....Separation science based on nanoparticle-coated monolithic scaffold stationary phases. The proposed project will generate highly significant, fundamental advances in separation science by developing new stationary phases and separation technologies suitable for the analysis of very complex samples which cannot be addressed by current methods. These technologies will be applied in a wide range of areas of national importance including pre-and post-blast identification of explosives in counter-terrorism applications; environmental, clinical, and forensic analysis; energy generation and foods. The project will also lead to very significant new intellectual property having extremely high commercial potential worldwide, and thereby generates the promise of considerable direct financial returns to Australia.Read moreRead less