Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U ....Evolution of Contact Damage in Layer Structures. Brittle layer structures (eg brittle coating on ceramic substrate) can be much more damage tolerant than their constituent material components - cracks tend to remain contained within the coating. Very little is known about the factors that control this behaviour. This project will exploit unique local expertise in modelling damage evolution to fill a niche in a large study being carried out at the National Institute of Standards (NIST) in the U.S.A. An understanding of the factors that maximise the containment of cracks is essential to the design and development of the next generation of advanced layer composites for many biomechanical and other engineering applications.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989123
Funder
Australian Research Council
Funding Amount
$575,000.00
Summary
Spark Plasma Sintering (SPS) Facility for Advanced Materials Processing. The establishment of the first Spark Plasma Sintering (SPS) facility would significantly enhance Australia's capacity in manufacturing of advanced materials, especially the more sophisticated and specialized materials, which is a National Research Priority. This facility will benefit a large number of researchers and projects in Australia's premier research organisations and will also meet the needs of organisations outside ....Spark Plasma Sintering (SPS) Facility for Advanced Materials Processing. The establishment of the first Spark Plasma Sintering (SPS) facility would significantly enhance Australia's capacity in manufacturing of advanced materials, especially the more sophisticated and specialized materials, which is a National Research Priority. This facility will benefit a large number of researchers and projects in Australia's premier research organisations and will also meet the needs of organisations outside the consortium. It will allow Australian researchers to remain at the leading edge of research and enhance collaborations in advanced materials nationwide. The successful outcomes of these activities will underpin the advancement in many areas of research and technology developments in the country.Read moreRead less
Boundary Effects on Bridging-Stress/Crack-Opening Relationship and Specific Fracture Energy. This project is to investigate the boundary/interface influence on fracture/material properties of composites and thin layered structures along crack path to free boundary and bi-material interface. The local fracture energy dissipation along crack path is emphasised and used to study the boundary influence on the cohesive law - the relationship between crack bridging stress and crack opening displaceme ....Boundary Effects on Bridging-Stress/Crack-Opening Relationship and Specific Fracture Energy. This project is to investigate the boundary/interface influence on fracture/material properties of composites and thin layered structures along crack path to free boundary and bi-material interface. The local fracture energy dissipation along crack path is emphasised and used to study the boundary influence on the cohesive law - the relationship between crack bridging stress and crack opening displacement. New fracture mechanics model is proposed that incorporates the boundary/interface influence and the more popular size effect. The new boundary/interface effect model will be more relevant to modern materials applications related to layered ceramics, thin films, coatings in electronic and bio-medical applications.Read moreRead less
Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering applicat ....Comparative Study of MnAs and Co-Based Magnetoelastic Functional Materials. Magnetoelastic materials are an emerging new class of functional materials with great potential in a wide range of innovative applications including smart structures, sensors and actuators, microelectronics, micro-electromechanical systems, and medical engineering. The study of magnetoelastic materials is still in its infancy and a great effort is required to develop them into practical materials for engineering application. This study aims to investigate two promising candidate materials: CoNi and MnAs. Expected outcomes include the characterisation of their functional properties and understanding of the mechanisms of magnetoelasticity in these materials. Such understanding is expected to contribute to the development of practical magnetoelastic materials and their applications.
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