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Failure modes in ceramic-based layer structures: Relevance to failure of dental crowns. With the aging of our population, issues concerning the lifetime of biological system are paramount to the quality of life and economic well being of our society. This project is closely linked to the development of prosthetic materials and structures that will improve performance and life of biomechanical devices, by providing better understanding to the mechanics of failure and failure origins of ceramic-ba ....Failure modes in ceramic-based layer structures: Relevance to failure of dental crowns. With the aging of our population, issues concerning the lifetime of biological system are paramount to the quality of life and economic well being of our society. This project is closely linked to the development of prosthetic materials and structures that will improve performance and life of biomechanical devices, by providing better understanding to the mechanics of failure and failure origins of ceramic-based dental crowns and restorations, and to develop materials that will withstand exacting conditions - in body fluids - over extended lifetimes. Crown replacement is by far the most widespread of all prosthetic procedures. This project promises to help bridge the gap between physical and medical science in Australia. Read moreRead less
Effects of prosthesis design on bone remodelling and longevity of dental restorations. The project targets both the 'Promoting and Maintaining Good Health' and 'Advanced Materials' designated research priority areas. The research will underpin Australia's leading role on some emerging interdisciplinary frontiers of biomechanics, biomaterials, health sciences and biomedical software. The development of computer aided clinical plan will help optimise dental restorations for 'long-term success'. Th ....Effects of prosthesis design on bone remodelling and longevity of dental restorations. The project targets both the 'Promoting and Maintaining Good Health' and 'Advanced Materials' designated research priority areas. The research will underpin Australia's leading role on some emerging interdisciplinary frontiers of biomechanics, biomaterials, health sciences and biomedical software. The development of computer aided clinical plan will help optimise dental restorations for 'long-term success'. The benefit will be to improve the ongoing performance and longevity of dental restoration, which complies with the highly demanding national goal of 'ageing well'. The study will also provide a new means to improve the therapy effect for many young Australians' effort towards a 'healthy start to their life'.Read moreRead less
Topography Optimisation of Implants for Enhancing Osseointegration. With recent increased life expectancy, the ratio of implant recipients to total population has dramatically increased. The project will address a critical issue in ensuring long-term success of prosthetic treatment. The proposed computational multiscale modelling will provide a sound scientific alternative means to optimisation of overall implant design including surface topography. The anticipated outcomes of this research will ....Topography Optimisation of Implants for Enhancing Osseointegration. With recent increased life expectancy, the ratio of implant recipients to total population has dramatically increased. The project will address a critical issue in ensuring long-term success of prosthetic treatment. The proposed computational multiscale modelling will provide a sound scientific alternative means to optimisation of overall implant design including surface topography. The anticipated outcomes of this research will help improve the quality of prosthetic therapy, and benefit our prosthodontic and orthopaedic professionals and their patients. The study clearly aligns with the national research goals of frontier technologies and maintaining good health.Read moreRead less
Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve des ....Failure of Complex Biomechanical Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate dental crown structures. We are now at a critical point in the understanding of how these structures fail, and are beginning to make substantive predictions to improve designs for prolonged life. The project is connected to the dental community and international crown material manufacturers through a broader NIH project in the USA. The improved materials and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a bro ....Failure of Worn Tooth Structures. Layer structures are replete in biological systems, both natural and artificial. Issues concerning the lifetime of such systems are paramount to the quality of life and economic well being of our aging society. Our project will analyse damage in brittle layer systems that simulate natural teeth and dental crown structures that have been subject to wear. The project is connected to the dental community and international crown material manufacturers through a broader National Institutes of Health project in the USA. The improved understanding of damage mechanisms in natural teeth and crown designs resulting from this project will have impact worldwide, including Australia.Read moreRead less
Nano-mechanical and nano-structural investigation of dentine: unravelling a novel nano-scale regulator of high durability of mineralised tissues. This project proposes that proteoglycans (PG) are key regulators of the high durability of dentine. PGs are primarily responsible for the structural organization of collagen in all vertebrates, however virtually nothing is known about their role on the biomechanics of mineralized tissues. This study aims to thoroughly address this question.
Containment and reduction of rework in offshore oil and gas projects. This research will ensure that hydrocarbon projects are delivered successfully, on time and budget, safely to specified quality and with minimal environment impact. The successful delivery of such projects is thwarted by rework made during the design process. Strategies to reduce rework from occurring in the future will be developed.
Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative ....Understanding the molecular structure and chemical behaviour of asphaltenes. This project will advance the science underpinning technologies for cost-effective use of heavy oil resources. Asphaltene aggregation and precipitation pose enormous challenges for extraction, transport, storage and refining of heavy oils. Understanding the physicochemical properties of asphaltenes is crucial to the future oil industry as light crudes become scarce. This project plans to develop and deploy an innovative molecular probe technique, combined with sequential thermal and solvent extraction and advanced tools for nanoscale characterisation, to reveal the molecular structure and chemical behaviour of asphaltenes. The resulting understanding of the mechanisms of asphaltene aggregation and dissociation may provide a scientific basis for controlling asphaltene precipitation to improve the stability and thus improve the use of heavy oils.Read moreRead less
Multicomponent Transport in Nanopores. Good understanding of transport mechanisms in nanopores is crucial to the successful application of numerous recently developed novel templated microporous and mesoporous materials. This project seeks to extend a new theory developed by the applicants for single component transport in cylindrical mesopores, to cylindrical micropores as well as to multicomponent adsorbates, in conjunction with experiments using microporous and mesoporous materials such as M ....Multicomponent Transport in Nanopores. Good understanding of transport mechanisms in nanopores is crucial to the successful application of numerous recently developed novel templated microporous and mesoporous materials. This project seeks to extend a new theory developed by the applicants for single component transport in cylindrical mesopores, to cylindrical micropores as well as to multicomponent adsorbates, in conjunction with experiments using microporous and mesoporous materials such as MCM-41, VPI-5 and AlPO4-5. The outcome will be a powerful new theory for a priori prediction of transport coefficients for multicomponent fluids in nanopores based on molecular level information alone, thereby overcoming the empiricism in existing models.Read moreRead less
Fluidised bed nanoparticle reactors for gas-solid catalytic reactions. This is a "frontier technologies" (nanotechnology) project and promises to open up new opportunities for exciting development in molecular engineering. Catalytic gas-solid reactions are among the most important reactions in chemical industry and energy industry. The novel fluidised bed nanoparticle catalytic reactor is expected to have many important advantages over the conventional porous supported catalyst system. These rea ....Fluidised bed nanoparticle reactors for gas-solid catalytic reactions. This is a "frontier technologies" (nanotechnology) project and promises to open up new opportunities for exciting development in molecular engineering. Catalytic gas-solid reactions are among the most important reactions in chemical industry and energy industry. The novel fluidised bed nanoparticle catalytic reactor is expected to have many important advantages over the conventional porous supported catalyst system. These reactors promise to minimise the waste product generation from chemical and energy industries and so offer great benefit for the environment. Young researchers involved in the project will be equipped with knowledge at the forefront of nanotechnology, enabling them to contribute to Australia's new, high technology future.Read moreRead less