Hydrogen storage materials for energy conversion applications. For a clean environment, the ideal synthetic fuel is hydrogen because it is lightweight, highly abundant and its oxidation product (water) is environmentally benign. However, the effective storage of hydrogen remains a scientific challenge. This project aims to develop innovative materials with high hydrogen storage capacity and long cycle life, including new composite hydrides, catalysed metal hydrides and various nanotubes. The exp ....Hydrogen storage materials for energy conversion applications. For a clean environment, the ideal synthetic fuel is hydrogen because it is lightweight, highly abundant and its oxidation product (water) is environmentally benign. However, the effective storage of hydrogen remains a scientific challenge. This project aims to develop innovative materials with high hydrogen storage capacity and long cycle life, including new composite hydrides, catalysed metal hydrides and various nanotubes. The expected outcome is the achievement of high reversible hydrogen storage capacity to meet all the demands required for energy conversion applications, in particular, for hydrogen storage/fuel-cell vehicular applications.Read moreRead less
Fatigue in Lead-free Piezoceramics. This project aims are to achieve a fundamental understanding of the fatigue behaviour of lead-free piezoelectric ceramics which achieve high strain through phase transformations and then ascertain the effects of this behaviour on material degradation rates. The expected outcomes will facilitate replacement of toxic lead in commodity electronics. The focus will be on new lead-free bismuth-alkali-based piezoelectric ceramic systems which demonstrate exciting pot ....Fatigue in Lead-free Piezoceramics. This project aims are to achieve a fundamental understanding of the fatigue behaviour of lead-free piezoelectric ceramics which achieve high strain through phase transformations and then ascertain the effects of this behaviour on material degradation rates. The expected outcomes will facilitate replacement of toxic lead in commodity electronics. The focus will be on new lead-free bismuth-alkali-based piezoelectric ceramic systems which demonstrate exciting potential as alternate materials to lead zirconate titanate (PZT) materials. Successful optimisation of the materials' design and knowledge of their degradation rates are expected to facilitate their commercialisation through a profound reduction in the environmental challenges associated with manufacture and disposal of devices.Read moreRead less
Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be disc ....Tailoring the microwave dielectric properties of promising electroceramics for use in wireless telecommunication components and devices. This project aims to develop and tailor the microwave dielectric properties of promising electroceramic materials specifically targeting next generation wireless telecommunications applications. The partnership between the ANU and the Australian company Microwave and Materials Designs has the potential to enable new microwave electroceramic materials to be discovered and then incorporated into new microwave components and/or devices developed in response to the requirements of the international wireless telecommunications market. The requested PhD student will gain experience in both the industrial and academic worlds and the skills needed to be part of Australia's high-tech workforce. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0668469
Funder
Australian Research Council
Funding Amount
$195,000.00
Summary
The Rapid Kinetics Research Facility - an Integrated system for rapid kinetic studies of materials using synchrotron radiation. The Rapid Kinetics Research Facility will provide Australian researchers with the tools to follow and understand very rapid processes within advanced materials. This will greatly assist in: i) the development of more efficient materials processing technologies, ii) the development of advanced catalysts able to neutralize pollutants and reduce the energy cost of industri ....The Rapid Kinetics Research Facility - an Integrated system for rapid kinetic studies of materials using synchrotron radiation. The Rapid Kinetics Research Facility will provide Australian researchers with the tools to follow and understand very rapid processes within advanced materials. This will greatly assist in: i) the development of more efficient materials processing technologies, ii) the development of advanced catalysts able to neutralize pollutants and reduce the energy cost of industrial processes, iii) the development of viable hydrogen fuel storage media and iv) the training of young Australian researchers in advanced methods of materials characterization. Read moreRead less
An energetic approach to characterise fracture of soft matter by cutting. Cutting of soft materials is a common daily life experience (e.g. slicing of meat and cheese) and an essential operation in many industries, healthcare (e.g. surgery) and manufacturing (e.g. paint removal) among them. By measuring the cutting forces of the tool and examining the deformation mechanisms of the work-piece, this project aims to put the cutting process on a strong scientific and technological footing. It provid ....An energetic approach to characterise fracture of soft matter by cutting. Cutting of soft materials is a common daily life experience (e.g. slicing of meat and cheese) and an essential operation in many industries, healthcare (e.g. surgery) and manufacturing (e.g. paint removal) among them. By measuring the cutting forces of the tool and examining the deformation mechanisms of the work-piece, this project aims to put the cutting process on a strong scientific and technological footing. It provides an ingenious method to measure the fracture energy, i.e. specific resistance to cracking, of plastics, bulk and thin film polymer nanocomposites at different cut-depths. New knowledge gained from the project is expected to improve tool design and optimise cutting conditions to increase the cutting process efficiency.Read moreRead less
Aligning and Chaining Carbon Nanofillers in Fibre Composites: Synergistically Improving Damage Tolerance and Diagnosis. Recent studies reveal that alternating electric or magnetic fields can rotate conductive nanofillers in polymers. This project aims to advance a new concept of aligning nano-scale reinforcements (for example, graphene nano-sheets and carbon nanofibres) along the thickness direction of composite materials. The alignment of nano-sized reinforcement will address the perennial prob ....Aligning and Chaining Carbon Nanofillers in Fibre Composites: Synergistically Improving Damage Tolerance and Diagnosis. Recent studies reveal that alternating electric or magnetic fields can rotate conductive nanofillers in polymers. This project aims to advance a new concept of aligning nano-scale reinforcements (for example, graphene nano-sheets and carbon nanofibres) along the thickness direction of composite materials. The alignment of nano-sized reinforcement will address the perennial problem of through-thickness weaknesses of fibre-reinforced composites and, at the same time, improve the electrical conductivity of composites. The synergistic improvements in the mechanical and electrical properties will improve damage tolerance and diagnosis of composites, thus expanding their applications in transport and civil construction to help reduce carbon dioxide emission.Read moreRead less
Development of hierarchical carbon nanotube-glass fibre composites. Development of hierarchical carbon nanotube-glass fibre composites. This project aims to develop a new generation of hierarchical carbon nanotube-glass fibre reinforced composites, using a novel synthesis method that grafts carbon nanotubes (CNTs) onto glass fibre and glass fabric. These hierarchical nano- and micro-fibre composites will have improved in-plane mechanical properties, enhanced fracture toughness and higher electri ....Development of hierarchical carbon nanotube-glass fibre composites. Development of hierarchical carbon nanotube-glass fibre composites. This project aims to develop a new generation of hierarchical carbon nanotube-glass fibre reinforced composites, using a novel synthesis method that grafts carbon nanotubes (CNTs) onto glass fibre and glass fabric. These hierarchical nano- and micro-fibre composites will have improved in-plane mechanical properties, enhanced fracture toughness and higher electric conductivity. This project will use a comprehensive experimental and theoretical study to develop design tools for producing this new generation of composites. The anticipated outcome is lighter and stronger glass fibre composite structures, such as wind turbines in the renewable wind energy industry and boats in the marine industry.Read moreRead less
Investigation of a series of metallic sustrate materials suitable for developing long Y-Ba-Cu-O superconductors. Aims: Researchers from Institute for Superconducting and Electronic Materials, the University of Wollongong (UoW) & the Dept. Mat. Sci & Eng., University of Cincinnati (UC) in USA will build strong collaborations through joint research on a series of metallic substrate materials. Significance: The research work will contribute to the development of the second generation of high temper ....Investigation of a series of metallic sustrate materials suitable for developing long Y-Ba-Cu-O superconductors. Aims: Researchers from Institute for Superconducting and Electronic Materials, the University of Wollongong (UoW) & the Dept. Mat. Sci & Eng., University of Cincinnati (UC) in USA will build strong collaborations through joint research on a series of metallic substrate materials. Significance: The research work will contribute to the development of the second generation of high temperature superconducting wire technology. Expected outcomes: strengthen international research experience for junior researchers and develop new collaborations between senior researchers from UoW in Australia and UC in USA.Read moreRead less
Development of novel ferroelectric magnetic materials for multi-functional applications. Ferroelectric magnets having simultaneous ferroeletricity and ferromagnetism is an area of emerging scientific interest. This project is to develop novel ferroelectric magnetic materials for multifunctional applications and falls into National Research Priority, Frontier Technologies for Building and Transforming Australian Industries. This project will provide trainings for postgraduate students and develop ....Development of novel ferroelectric magnetic materials for multi-functional applications. Ferroelectric magnets having simultaneous ferroeletricity and ferromagnetism is an area of emerging scientific interest. This project is to develop novel ferroelectric magnetic materials for multifunctional applications and falls into National Research Priority, Frontier Technologies for Building and Transforming Australian Industries. This project will provide trainings for postgraduate students and develop patentable science and technologies. The scope for use of the novel multifunctional materials will be enormous with great markets in the fields of magnetoelectronics, magnetic electromechanical industrial devices. It will benefit Australian manufacturing industry in the long term. Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0882246
Funder
Australian Research Council
Funding Amount
$750,000.00
Summary
Comprehensive Analysis Facility for Thin Films and Surfaces. The provision of infrastructure for the analysis of thin films will enhance Australia's capabilities in creating new materials and in creating new devices that meet needs in medicine, communications, the environment and security. As devices become smaller, sufaces and interfaces dominate their performance. The new facility will enable researchers to understand the structure and composition of the interior and interfaces of thin films a ....Comprehensive Analysis Facility for Thin Films and Surfaces. The provision of infrastructure for the analysis of thin films will enhance Australia's capabilities in creating new materials and in creating new devices that meet needs in medicine, communications, the environment and security. As devices become smaller, sufaces and interfaces dominate their performance. The new facility will enable researchers to understand the structure and composition of the interior and interfaces of thin films as well as mapping local variations in their key properties. Instruments with unique capabilities will measure elemental composition, crystallographic phase, defect and void distributions and spatially resolved stress, electrical, mechanical and magnetic properties.Read moreRead less