Atomically thin membranes to transform chemical separations. Energy-efficient chemical separation is at the heart of modern resource and manufacturing industries, central to a prosperous and sustainable Australia. This project aims to develop next generation membrane technologies to transform chemical separations by employing recent breakthrough in materials discovery and nanofluidics. Expected outcomes include new fundamental understandings on sub-continuum transport physics and new atomically ....Atomically thin membranes to transform chemical separations. Energy-efficient chemical separation is at the heart of modern resource and manufacturing industries, central to a prosperous and sustainable Australia. This project aims to develop next generation membrane technologies to transform chemical separations by employing recent breakthrough in materials discovery and nanofluidics. Expected outcomes include new fundamental understandings on sub-continuum transport physics and new atomically thin membranes that enable energy-efficient separations for processing challenging streams beyond water purification. This project aims to position Australia at the forefront of sustainable separation technology and make the local resource and manufacturing industries more sustainable and globally competitive.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE130100051
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Fabrication and characterisation facilities for lithium rechargeable batteries and supercapacitors. The facility, unlike any currently existing in Australia, will help researchers studying electrodes and cells at a high level. It will provide a new path to high-level research performance and will significantly enhance Australia’s research capability to bring new materials/technologies under development closer to application.
Nanostructured magnetic materials for clean automotive technologies. Greater utilisation of the petrol-electric hybrid technology is an effective and realistic approach to the problem of increasing greenhouse gas emissions from transportation sources. Owing to the requirement of the temperature stability of the magnets used in the electric motors in the current hybrid vehicles, the magnets contain considerable amounts of costly rare-earth elements. This impedes the utilisation of the technology ....Nanostructured magnetic materials for clean automotive technologies. Greater utilisation of the petrol-electric hybrid technology is an effective and realistic approach to the problem of increasing greenhouse gas emissions from transportation sources. Owing to the requirement of the temperature stability of the magnets used in the electric motors in the current hybrid vehicles, the magnets contain considerable amounts of costly rare-earth elements. This impedes the utilisation of the technology and hence alternative cost effective magnets with high temperature stability are needed. In this project we will exploit a range of alloy design strategies in manganese-bismuth/iron nanocomposite magnets, thereby realising a novel permanent magnet, free of costly rare-earth elements.Read moreRead less
Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite ....Development of nanoporous materials for capture and release of oxygen. This project aims to develop new materials to make lighter, more efficient oxygen concentrators. The project will combine materials that can capture oxygen with particles that can be magnetically heated, making it possible to release the oxygen rapidly and efficiently when needed. Expected outcomes from this project include new composite materials and better understanding of how gases are trapped and released within composite materials. Benefits from this project may include oxygen concentrators that are more portable and have longer battery life, both with industrial and medical applications.Read moreRead less
Pore Engineering of Chromatography Membranes for Bioseparation. Protein separation and purification is an essential unit operation in manufacturing processes of therapeutic proteins. The project aims to advance the practical applications of chromatography membrane, an emerging technology for protein separation and purification, by tailoring membrane pore geometry and surface functionality to achieve enhanced separation performance. The project expects to generate advanced knowledge and technique ....Pore Engineering of Chromatography Membranes for Bioseparation. Protein separation and purification is an essential unit operation in manufacturing processes of therapeutic proteins. The project aims to advance the practical applications of chromatography membrane, an emerging technology for protein separation and purification, by tailoring membrane pore geometry and surface functionality to achieve enhanced separation performance. The project expects to generate advanced knowledge and techniques in the fields of reactive polymer synthesis, functional membrane fabrication and application in bioseparation. The innovative membranes developed in the project are able to improve the production capacity of therapeutic protein manufacturing processes, providing significant economic benefits to Australia.Read moreRead less
Carbon Molecular Sieve Membranes for Organic Solvent Separation. Directly addressing the pressing challenge of organic solvent separation faced by numerous industries, the project aims to develop molecular sieve membranes with outstanding selectivity and solvent tolerance by constructing zeolite-carbon mixed matrix membrane via incorporating zeolite nanosheets into carbon materials. The project expects to generate advanced knowledge of nanosheet synthesis, membrane fabrication and selective mole ....Carbon Molecular Sieve Membranes for Organic Solvent Separation. Directly addressing the pressing challenge of organic solvent separation faced by numerous industries, the project aims to develop molecular sieve membranes with outstanding selectivity and solvent tolerance by constructing zeolite-carbon mixed matrix membrane via incorporating zeolite nanosheets into carbon materials. The project expects to generate advanced knowledge of nanosheet synthesis, membrane fabrication and selective molecule transport. The membranes developed in the project have great potentials for improving the production capacity and sustainability of Australian industries, e.g., pharmaceutical manufacturing, bioethanol production and petroleum refining, providing significant economic and environmental benefits to Australia.Read moreRead less
Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random aniso ....Core loss mechanisms in soft magnetic nanostructures. This project aims to clarify the mechanism of power losses in magnetic cores used in the petrol-electric hybrid cars by investigating the relationship between the core losses and magnetic correlation lengths in iron alloys. This project expects to generate new knowledge on the effect of magneto-mechanical interaction on the anomalous core loss in iron based alloys. The intended outcomes include an experimental confirmation of the random anisotropy model, a major theoretical model in nanostructured materials and identification of ideal magnetic domain configurations for lower power losses. These intended outcomes should bring great benefits to the development of low-carbon vehicle technologies for sustainable motorisation in Australia.Read moreRead less
Nanostructured soft magnetic alloys for low-carbon cars. The aim of this project is to prepare iron-based magnetic nanostructures that exhibit a magnetic induction of 1.9 tesla and core losses lower than those of iron-silicon steels, which would deliver smaller and efficient magnetic cores for petrol-electric hybrid cars. Preliminary results from the research team show that iron-metalloid alloys with an iron content of 87 per cent meet this magnetic induction with room for further improvement of ....Nanostructured soft magnetic alloys for low-carbon cars. The aim of this project is to prepare iron-based magnetic nanostructures that exhibit a magnetic induction of 1.9 tesla and core losses lower than those of iron-silicon steels, which would deliver smaller and efficient magnetic cores for petrol-electric hybrid cars. Preliminary results from the research team show that iron-metalloid alloys with an iron content of 87 per cent meet this magnetic induction with room for further improvement of magnetic softness. The project aims to systematically investigate the effect of metalloid and micro-alloying elements on the nano-crystallisation behaviour of the precursor amorphous alloys in order to identify the alloy composition and processing conditions for preparing magnetically soft nanostructures.Read moreRead less
Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include ne ....Crystal engineering of membranes for chiral separation . This project addresses the urgent challenge of chiral separation in the manufacturing of pharmaceuticals and agrochemicals by creating a new class of membranes produced by engineering functionalised porous framework crystals. This project expects to generate new knowledge regarding how membrane chemistry and architecture can be used to achieve highly selective, fast chiral molecule transport. The expected outcomes of the project include new membrane compositions, design principles, fabrication techniques, and proof-of-concept production of scalable, high-performance composite membranes. This project should produce significant economic and environmental benefits in the development of advanced membranes, pharmaceuticals, and agrochemicals.Read moreRead less
Soft magnetic nanostructures for clean automotive technologies: origin of induced magnetic anisotropies. This project will clarify the mechanism of annealing-induced magnetic anisotropies in magnetic nanostructures and thereby establish a basis for further alloy development of efficient core materials for electric motors. The project outcomes will potentially lead to a significant reduction of the heat loss in petrol-electric hybrid cars.