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
Novel fuel-cell structures based on electroactive polymers. This project will tackle some of the challenges currently hindering progression of our society into a post-petroleum era via materials developments that will lead to in-expensive, more efficient fuel cell technologies. Specifically, a new class of organic catalysts and novel ion conducting membranes will be integrated into functional fuel-cells.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100042
Funder
Australian Research Council
Funding Amount
$190,000.00
Summary
UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance ....UV to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry, and laser materials characterisation. Ultraviolet to mid-infrared fluorescence spectrometer for use in mineral analysis, radiation dosimetry and laser materials characterisation: This project will provide equipment with a vast capability to collect ultraviolet to mid-infrared fluorescence with high temporal measurement accuracy, and highly flexible excitation (spectral and temporal). This will enhance active research into new glasses and laser crystals, probing of defect states resulting from ionising radiation absorption in environmental and medical dosimetry materials, investigation of novel fluorescence techniques for mineral identification, through to improving chemical detection capability (for example, detection of explosives). The instrument comprises modules that enable excitation in the ultraviolet, visible, and infrared from a tunable laser system, and high-efficiency collection and processing of fluorescence spectra.Read moreRead less
Development of Novel Spin Caloritronic Materials and Devices for Heat Management in Nanoelectronic Systems. Spin caloritronics is a new field that combines concepts from spintronics and thermoelectricity. This project is inspired by spin Seebeck effect observed in magnetic insulators and motivated by the basic requirements of nanoscale heat management devices. Such devices are the key components promising to surmount fundamental limits of microelectronic technologies with heat dissipation and p ....Development of Novel Spin Caloritronic Materials and Devices for Heat Management in Nanoelectronic Systems. Spin caloritronics is a new field that combines concepts from spintronics and thermoelectricity. This project is inspired by spin Seebeck effect observed in magnetic insulators and motivated by the basic requirements of nanoscale heat management devices. Such devices are the key components promising to surmount fundamental limits of microelectronic technologies with heat dissipation and power consumption as the size of charge-based logic devices shrinks into nanometre scale. This program is aimed at experimental and theoretical development of novel spin caloritronic materials with spin Seebeck effect at ambient temperature, which is orders of magnitude higher than state-of-the-art materials, for heat management in nanoelectronic systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100188
Funder
Australian Research Council
Funding Amount
$1,000,000.00
Summary
Epitaxial growth facility for advanced materials. An advanced materials fabrication facility accessible to all Australian researchers will be established. This will allow crystal growth at the atomic level for novel materials with applications including fundamental physics, nanocomposites, energy storage and conversion systems, and solar cells.
Controllable synthesis of multifunctional boron-based 2D materials. This project aims to make it possible to control the synthesis of boron-based two-dimensional (2D) materials with the desired following features in single or multiple aspects: thickness, composition, lateral sizes, porosity, surface area, and functionality. It intends to do so by designing and synthesising novel precursors, and by optimising the fabrication process of boron-based 2D nanosheets for different applications. The pro ....Controllable synthesis of multifunctional boron-based 2D materials. This project aims to make it possible to control the synthesis of boron-based two-dimensional (2D) materials with the desired following features in single or multiple aspects: thickness, composition, lateral sizes, porosity, surface area, and functionality. It intends to do so by designing and synthesising novel precursors, and by optimising the fabrication process of boron-based 2D nanosheets for different applications. The project will advance our fundamental knowledge in synthetic chemistry, materials chemistry, materials engineering and physics. It is expected to take us closer to unlocking the potential of boron-based 2D materials for real-world applications in, for example, energy storage and high-performance flexible electronics.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.
Nanoscale electrochemical imaging of catalyst inks for water oxidation. This project aims to reduce the cost of current water splitting technology by making new catalysts from earth abundant materials that will ensure a sustainable technological solution for the storage of renewable energy. This technology is an excellent solution to storing energy from intermittent renewable energy sources such as solar as it generates hydrogen which is a clean fuel. Using new techniques that can image the cata ....Nanoscale electrochemical imaging of catalyst inks for water oxidation. This project aims to reduce the cost of current water splitting technology by making new catalysts from earth abundant materials that will ensure a sustainable technological solution for the storage of renewable energy. This technology is an excellent solution to storing energy from intermittent renewable energy sources such as solar as it generates hydrogen which is a clean fuel. Using new techniques that can image the catalyst at the nanoscale while it is operating is expected to provide the knowledge for developing the next generation of water splitting electrolysers that can be utilised by households and businesses for storing solar or wind energy.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE110100028
Funder
Australian Research Council
Funding Amount
$720,000.00
Summary
Ultra-high resolution and advanced analytical scanning electron microscope facility. This scanning electron microscope facility will form an essential part of characterising a broad range of material types, from nanometre sized particles through to cells and their interactions.
Cost-efficient 2D heterostructures for solar overall water splitting. This project aims to develop novel processes to enable water splitting to generate hydrogen and oxygen under sunlight using cost-efficient 2D van der Waals heterostructures. Enhanced optical absorption and reduced charge transfer distance across the interface are expected to improve the photocatalytic activity. Experimental design and theoretical simulations will be combined to modulate the materials and achieve optimum photoc ....Cost-efficient 2D heterostructures for solar overall water splitting. This project aims to develop novel processes to enable water splitting to generate hydrogen and oxygen under sunlight using cost-efficient 2D van der Waals heterostructures. Enhanced optical absorption and reduced charge transfer distance across the interface are expected to improve the photocatalytic activity. Experimental design and theoretical simulations will be combined to modulate the materials and achieve optimum photocatalytic performances. Expected outcomes of this project include expanded chemistry knowledge and techniques in materials design and synthesis, photophysics and photocatalysis mechanism and solar energy conversion. This will provide significant benefits to clean energy and environmental protections.Read moreRead less