Mechanical advantage: biomimetic artificial muscles for micro-machines. This project will develop better ways to operate miniature machines by copying the way that muscle operates in Nature. The outcome will be important for portable devices like digital cameras that need small, efficient motors. The artificial muscles developed in this project may also be used in medical prosthetics and more agile robots.
Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more eff ....Advanced electrochemical capacitors. This project aims to design electrochemical capacitors that can provide self-sustaining power for equipment using renewable energy sources, such as sunlight. Electrical power systems are needed to supply both the peak power and the energy demand that users, particularly those without grid electricity, and their equipment need. This project will match the capacitator electrochemistry to the power attributes of the load and charging source, making them more efficiently charged and able to supply both peak power and energy demand for improved off-grid power supplies and integration of renewable energy into electricity grids.Read moreRead less
Advanced macromolecular engineering: novel approaches to self-directed assembly and vesicle formation. The aim of this project is to develop new approaches in nanotechnology for the preparation of well-defined polymeric particles. The research will result in the development of new methodology which has the potential to impact areas of commercial interest including those in the health-care sector.
Liquid Metal for quench detection sensors and low resistance joints. This project aims to develop next-generation liquid metal-based superconducting joints and quench detection sensors to enable superconducting magnets to operate in “persistent mode”. This would make a significant contribution to improving the safety and performance of superconducting coil systems at a reduced cost. Furthermore, intelligent features will be formulated to prevent hazardous and inefficient operating conditions. Th ....Liquid Metal for quench detection sensors and low resistance joints. This project aims to develop next-generation liquid metal-based superconducting joints and quench detection sensors to enable superconducting magnets to operate in “persistent mode”. This would make a significant contribution to improving the safety and performance of superconducting coil systems at a reduced cost. Furthermore, intelligent features will be formulated to prevent hazardous and inefficient operating conditions. The expected outcome is that an advanced superconducting coil system with improved stability and safety is delivered with newly developed liquid metal-based materials and relevant fabrication techniques.Read moreRead less
Engineered control of polarisation rotation in ferroelectric bilayers. This project aims to develop interface engineered nanoscale ferroelectric thin films with functional properties suitable for integration. Bulk ferroelectrics form the core of traditional stand-alone electromechanical devices such as sensors, actuators and ultrasonic devices. Future applications need to be integrated into thin film form on semiconductor wafers, but the attachment to the wafer induces a mechanical constraint, w ....Engineered control of polarisation rotation in ferroelectric bilayers. This project aims to develop interface engineered nanoscale ferroelectric thin films with functional properties suitable for integration. Bulk ferroelectrics form the core of traditional stand-alone electromechanical devices such as sensors, actuators and ultrasonic devices. Future applications need to be integrated into thin film form on semiconductor wafers, but the attachment to the wafer induces a mechanical constraint, which dramatically suppresses the electromechanical response. This project aims to solve this problem by "polarisation rotation", achieved by layered stacking of thin film ferroelectrics. Engineered control of ferroelectric polarization rotation could be the pathway to modern electromechanical devices.Read moreRead less
Design and exploration of novel p-block materials for visible light photocatalysis. This project aims to design and explore novel visible light p-block photocatalysts through in depth surface studies of materials at an atomic level. A new strategy of band structure engineering and in-situ investigation of atomic-level photocatalytic dynamics will be the key elements in this research which is expected to yield several novel visible light photocatalysts. The outcome of the project will be the unde ....Design and exploration of novel p-block materials for visible light photocatalysis. This project aims to design and explore novel visible light p-block photocatalysts through in depth surface studies of materials at an atomic level. A new strategy of band structure engineering and in-situ investigation of atomic-level photocatalytic dynamics will be the key elements in this research which is expected to yield several novel visible light photocatalysts. The outcome of the project will be the understanding of processes and mechanisms underlying the photocatalysis and building the foundation of usable, stable, and durable visible-light photocatalytic applications.Read moreRead less
Modification of optical properties of photocatalytic titania. The aim of the project is to capitalise on and optimise the recently discovered successful modification of the optical properties of titanium oxide (TiO2), such that efficient solar splitting of water is possible. TiO2 photocatalysts of adequate efficiency will be implemented as photoanodes in photoelectrochemical cells capable of large-scale production of hydrogen.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE180100141
Funder
Australian Research Council
Funding Amount
$326,367.00
Summary
Thermo-gravimetric infra-red imaging system for functional materials study. This proposal seeks to establish a multi-functional system for investigating surface, interface, and thermal properties of functional materials. The instrumentation features thermo-gravimetric, infra-red imaging hyphenated with gas-chromatography-mass spectrometry. The expected benefits are an enhanced research capability in solid-electrolyte-interphase and electrolyte decomposition on electrodes being used in alkaline-i ....Thermo-gravimetric infra-red imaging system for functional materials study. This proposal seeks to establish a multi-functional system for investigating surface, interface, and thermal properties of functional materials. The instrumentation features thermo-gravimetric, infra-red imaging hyphenated with gas-chromatography-mass spectrometry. The expected benefits are an enhanced research capability in solid-electrolyte-interphase and electrolyte decomposition on electrodes being used in alkaline-ion batteries, which could potentially pose risks during manufacturing and application. The system will not only facilitate high-quality research and impact the training of young researchers, but also provide a platform from which to enhance Australian materials research capabilities.Read moreRead less
New generation high efficiency thermoelectric materials and modules for waste heat recovery in steelworks. The development of thermoelectric materials and devices, and their subsequent uptake by the steel industry, will bring tremendous socio-economic benefits in terms of decreased operational costs, a significantly reduced carbon footprint and will set an excellent example for other industries on how to comply with strict environmental regulations.