Determination of the Properties of Hyper-Elastic Materials by Deep Indentation. We seek to develop the scientific basis for the interpretation of the results of "deep" indentation testing of non-linear elastic (hyper-elastic) materials. Simple tests (such as indentation) produce complex strain fields. Interpretation of the resulting data in terms of stiffness, for example, requires a complex model of the deformation process that can be utilised to link the observed behaviour to the basic prope ....Determination of the Properties of Hyper-Elastic Materials by Deep Indentation. We seek to develop the scientific basis for the interpretation of the results of "deep" indentation testing of non-linear elastic (hyper-elastic) materials. Simple tests (such as indentation) produce complex strain fields. Interpretation of the resulting data in terms of stiffness, for example, requires a complex model of the deformation process that can be utilised to link the observed behaviour to the basic properties of interest. This project is dedicated to an understanding of the complex deformation associated with large strain indentation of hyper-elastic materials and structures, development of finite element based models for this deformation and creation of techniques for interpretation of the results of such indentation tests.Read moreRead less
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
Engineering a silk fibroin based ear drum with optimum acoustic properties. This project will use new silk fibroin materials to develop ear drums with improved acoustic properties. This will lead to significant improvement in the quality of life of nearly 2.5 million people in Australia who are affected by hearing loss and further strengthen Australia's leading position in this area.
Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by th ....Wearable thermoelectric textiles for portable microelectronics. Wearable thermoelectrics enable the power generation from the temperature difference between human body and ambient temperature by using thermoelectric effect. This project aims to design eco-friendly wearable thermoelectric textiles to realize high-efficiency solid-state power generation and meet individual needs with human comfort and health. The target is to achieve a power density in the as-designed thermoelectric textiles by the optimization of materials and device design. The outcome will open up a new platform for the green and sustainable charge for portable microelectronics, which will lead to an innovative technology for energy management, which will place Australia at the forefront of wearable electronics and textile industry.Read moreRead less
Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new el ....Powering Next Generation Wearable Electronics: Moisture Electric Generator . This project aims to develop next generation energy harvesting device which can directly generate electricity from the moisture in the air for self-powered, wearable electronics. The goal will be achieved by developing a new class of carbon based nanomaterials and large scale printing technology, through optimizing the materials defects, printing process and electrode configuration. The expected outcomes will be new electronic materials for a wide range of end uses in wearable electronics, significant advances in self-powered, environmentally friendly devices, and commercialisation of the technology to Australian industries.Read moreRead less
Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction o ....Smart utilisation of cobaltite based electrodes on solid oxide fuel cells. This project aims to develop solid oxide fuel cell technologies with significantly simplified fabrication steps and at low cost. It aims to generate fundamental knowledge on the polarisation induced electrode/electrolyte interfaces under fuel cell operation conditions. The advanced fuel cell technologies will in turn substantially increase the energy conversion efficiency and provide significant benefit in the reduction of greenhouse emission.Read moreRead less
Wearable thermoelectrics for personal heat management. Thermoregulation has substantial implications for energy consumption and human comfort and health. This project aims to develop wearable thermoelectric materials and devices with high cooling performance for personal heat management. A novel assembly approach, coupled with device design and materials engineering strategies, will be developed to engineer flexible thermoelectric materials with unique structures and chemistry. The key breakthro ....Wearable thermoelectrics for personal heat management. Thermoregulation has substantial implications for energy consumption and human comfort and health. This project aims to develop wearable thermoelectric materials and devices with high cooling performance for personal heat management. A novel assembly approach, coupled with device design and materials engineering strategies, will be developed to engineer flexible thermoelectric materials with unique structures and chemistry. The key breakthrough is to design wearable thermoelectric devices with high flexibility and user comfort. The expected outcomes of this project will lead to an innovative cooling technology for personal heat management, which will place Australia at the forefront of wearable electronics and garment industry.Read moreRead less
metal hydride reactors for high temperature thermochemical heat storage. The aim of this project is to develop a laboratory-based prototype for energy storage in concentrating solar power (CSP) systems using metal hydrides as a chemical energy storage medium. The successful development of cost-effective energy storage technologies is expected to dramatically increase the deployability of CSP systems and this, in turn, will greatly enhance our capacity to reduce reliance on fossil fuels. The outc ....metal hydride reactors for high temperature thermochemical heat storage. The aim of this project is to develop a laboratory-based prototype for energy storage in concentrating solar power (CSP) systems using metal hydrides as a chemical energy storage medium. The successful development of cost-effective energy storage technologies is expected to dramatically increase the deployability of CSP systems and this, in turn, will greatly enhance our capacity to reduce reliance on fossil fuels. The outcomes of the project are planned to be used towards the development of a commercially viable solar thermal energy storage system. The project also plans to conduct fundamental research into the development of new high-temperature metal hydrides suitable for energy storage in CSP systems.Read moreRead less
Concentrating solar thermal energy storage using metal hydrides. This project will investigate energy storage for concentrating solar thermal energy systems. These systems can be used to efficiently generate electricity in remote locations, day and night, using solar energy. The solar energy is converted to heat energy and then chemical energy stored in a metal-hydrogen compound.