Bulk Mg based hydrogen storage alloys with faster activation. Bulk Mg based hydrogen storage alloys with faster activation. This project aims to improve the performance and efficiency of manufacture of magnesium-based hydrogen storage alloys, making them more cost competitive and widely useable. A hydrogen economy will reduce greenhouse gas emissions and improve air quality in urban areas. The expected outcomes are an understanding of the mechanisms governing the activation process, a necessary ....Bulk Mg based hydrogen storage alloys with faster activation. Bulk Mg based hydrogen storage alloys with faster activation. This project aims to improve the performance and efficiency of manufacture of magnesium-based hydrogen storage alloys, making them more cost competitive and widely useable. A hydrogen economy will reduce greenhouse gas emissions and improve air quality in urban areas. The expected outcomes are an understanding of the mechanisms governing the activation process, a necessary step in manufacture, and techniques to exploit these mechanisms to minimise the activation time. This is expected to develop competitive, bulk magnesium-based hydrogen storage alloys for effective and safe hydrogen storage systems.Read moreRead less
Smart Materials Between Two and Three Dimensions. Shape-memory alloys involving martensitic transformations, are important as smart materials. Both the transformation nucleation and the sample morphology are unsolved issues relevant for these applications. Of particular note are the softening of certain lattice-vibrational frequencies, the development of a tweed-like microstructure on cooling the material and the role of defects, particularly the sample surface, in the transformation process. ....Smart Materials Between Two and Three Dimensions. Shape-memory alloys involving martensitic transformations, are important as smart materials. Both the transformation nucleation and the sample morphology are unsolved issues relevant for these applications. Of particular note are the softening of certain lattice-vibrational frequencies, the development of a tweed-like microstructure on cooling the material and the role of defects, particularly the sample surface, in the transformation process. This project addresses these issues using model materials in thin-film and bulk-crystal forms. Capacitance dilatometry, optical, electron and scanning-probe microscopies, and x-ray techniques, will unlock an understanding of the physical and metallurgical conditions controlling these transformations.Read moreRead less
Increasing solid electrolyte conductivity through defect design. This project aims to engineer electrolyte materials, based on organic ionic plastic crystals, and use isomeric doping to improve the ionic conductivity. The development of safer batteries relies on eliminating the volatile and flammable solvents commonly used as the electrolyte. Improving the safety and performance of batteries is important as electricity costs increase. Solid state ionic electrolytes can address leakage and volati ....Increasing solid electrolyte conductivity through defect design. This project aims to engineer electrolyte materials, based on organic ionic plastic crystals, and use isomeric doping to improve the ionic conductivity. The development of safer batteries relies on eliminating the volatile and flammable solvents commonly used as the electrolyte. Improving the safety and performance of batteries is important as electricity costs increase. Solid state ionic electrolytes can address leakage and volatility problems, but the conductivity must be improved if these materials are to support high battery power. The project’s electrolyte materials can be used in lithium metal batteries, which have higher theoretical energy densities than traditional lithium ion batteries. This project will develop new solid state electrolytes, with improved conductivity, and use these materials in emerging lithium battery technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0239650
Funder
Australian Research Council
Funding Amount
$500,000.00
Summary
Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the Univer ....Advanced instrumentation for nano-scale imaging and analysis. It is widely accepted that the emerging fields of Nanotechnology and Nanoengineering will dominate research activity in a wide range of disciplines over the next decade. Progress in nanoscience and technology requires parallel development in nanocharacterisation and nanofabrication techniques. This proposal seeks to enhance the level of research infrastructure support for nano-scale microscopy and microanalysis at UTS and the University of Sydney by providing the following advanced instrumentation for nano-scale imaging, analysis and manipulation of materials:
- A Schottky field emission gun environmental scanning electron microscope
- Equipment kit for the rapid preparation of high quality transmission electron microscope specimens.Read moreRead less
Mechanisms for Improved Ductility of Magnesium Alloys. The work will lead to more ductile magnesium alloys. These alloys will be more readily formed into automotive components. The lighter cars that will result will be cheaper to run and more environmentally friendly. The exchange of key researchers that will occur under this proposal will provide an exciting injection of expertise into the partner organisations from which students will greatly benefit. The work will also open up access to state ....Mechanisms for Improved Ductility of Magnesium Alloys. The work will lead to more ductile magnesium alloys. These alloys will be more readily formed into automotive components. The lighter cars that will result will be cheaper to run and more environmentally friendly. The exchange of key researchers that will occur under this proposal will provide an exciting injection of expertise into the partner organisations from which students will greatly benefit. The work will also open up access to state-of-the-art equipment in the collaborating laboratories.Read moreRead less
Development of SmCo-based High Temperature Permanent Magnets: Microstructure and Coercivity Mechanism. This project is to develop high performance permanent magnets for elevated temperature applications. Microstructure and magnetic properties will be examined using atom probe, TEM, XRD and magnetometry. The specific atom probe is the state-of-the-art technique for the characterization of nanostructure and falls in the designated National Research Priority 3, PG2 Frontier Technologies (nanotechno ....Development of SmCo-based High Temperature Permanent Magnets: Microstructure and Coercivity Mechanism. This project is to develop high performance permanent magnets for elevated temperature applications. Microstructure and magnetic properties will be examined using atom probe, TEM, XRD and magnetometry. The specific atom probe is the state-of-the-art technique for the characterization of nanostructure and falls in the designated National Research Priority 3, PG2 Frontier Technologies (nanotechnology). The magnet alloys concerned are an example of Advanced Materials (NRP3, PG3), possessing the best performance amongst such functional materials. The expertise gained in the use of the atom probe technique in this project will have broader applications in the study of nanostructured materials and other metal alloy problems within Australia.Read moreRead less
Engineering the kinetic stability of alloys for advanced stainless material development. A framework for understanding and designing metals and alloys with kinetic stability in mind will allow for discovery and breakthrough science to underpin technological innovation. This work has potential benefits for multiple industry sectors, with the ultimate intent of developing advanced materials for use in transport, construction, energy generation and medicine; all sectors of which can improve our qua ....Engineering the kinetic stability of alloys for advanced stainless material development. A framework for understanding and designing metals and alloys with kinetic stability in mind will allow for discovery and breakthrough science to underpin technological innovation. This work has potential benefits for multiple industry sectors, with the ultimate intent of developing advanced materials for use in transport, construction, energy generation and medicine; all sectors of which can improve our quality of life, whilst also addressing the multi-billion dollars of loss attributed to metallic corrosion each year. Such work will also benefit Australia through the development of a strategic international capability in a highly interdisciplinary field.Read moreRead less
Design of tuneable microstructures for additive manufacturing. The project intends to develop methods to tune the microstructure of materials in additive manufacturing so that components can be manufactured with maximum productivity and properties. Additive manufacturing is leading the mass customisation of manufacturing. Designed tunable microstructures enable structure and properties to be tailored for specific applications. One of the greatest challenges, however, is how to control the scale ....Design of tuneable microstructures for additive manufacturing. The project intends to develop methods to tune the microstructure of materials in additive manufacturing so that components can be manufactured with maximum productivity and properties. Additive manufacturing is leading the mass customisation of manufacturing. Designed tunable microstructures enable structure and properties to be tailored for specific applications. One of the greatest challenges, however, is how to control the scale and morphology of the microstructure. This project aims to use the interdependence model of grain refinement to control and design grain sizes. The project first plans to investigate the near-rapid solidification conditions in aluminium alloys. It then plans to re-design the harder-to-manufacture titanium alloys to improve grain size control.Read moreRead less
Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifun ....Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifunctional materials and new nanodevice structures which may open up unprecedented opportunities for both scientific and technological endeavoursRead moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0560705
Funder
Australian Research Council
Funding Amount
$825,000.00
Summary
Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast ....Advanced Deformation Simulation Laboratory. For Australia to maintain its position as a world leader in the science of metals processing it must have the capability for state-of-the-art physical simulation. The present proposal is for the purchase and installation of two leading edge simulation tools: a high rate/short inter-pass hot deformation simulator and a hot equal channel angular extrusion press. Advanced hot deformation simulation is required for the development and optimisation of "fast" industrial processes and for understanding the complex microstructural reactions associated with them. High temperature extrusion is required for the development of ultra-fine and nano-grained light metals.Read moreRead less