Thallium hydride complexes - synthesis, stabilisation and synthetic utility. Australia has abundant geological deposits of group 13 metals. The hydride chemistries of group 13 elements are critical to modern applications of these elements. There are no hydrides of thallium, the heaviest member of group 13. This project aims to prepare and stabilise thallium hydrides to enable technological applications of thallium.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100136
Funder
Australian Research Council
Funding Amount
$1,100,000.00
Summary
High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-prope ....High Performance Solid State NMR Spectroscopy for Materials Research. The project will support research in a diverse set of fields such as biomedical engineering catalysis, energy storage and waste recovery, with cutting edge next-generation solid state (400 MHz) nuclear magnetic resonance capabilities and research expertise. The system enabling high sensitivity, high throughput analysis over extended temperature range will enable addressing of fundamental questions regarding the structure-property relationships of advanced functional materials. Accessible to a wide user base in fundamental and applied research, in medicine, energy, catalysis and recycling of waste, the project will extend the current facilities to develop Sydney as regional centre for advanced solid state nuclear magnetic resonance analysis.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100090
Funder
Australian Research Council
Funding Amount
$200,000.00
Summary
Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important ....Surface and Colloid Characterisation Facility. Surface and colloid characterisation facility: Surface science lies at the heart of biointerface and colloid science. This facility will enable particle size, shape, distribution, surface area and charge to be measured as well as the amount of material adsorbed to interfaces, the configuration of that material and the response of the surface to stimuli such as changing pH or salinity. All these parameters influence the properties of these important systems. As such this facility will underpin the research of a number of groups across three institutions over the next decade and promote collaboration between scientists with a range of complementary expertise in fields where surface science is important from biology to ionic liquids.Read moreRead less
Next-generation polymer films for control of material interactions. This project will develop smart polymer films which incorporate a mechanism which rapidly switches the coating from being attracted to or repelled by adjacent material. These films will be made using a new water-based technology and assessed for potential application such as: (1) active agents for mineral processing, or (2) high performance lubricants.
Smart materials from semi-soft particles. This project will combine precision polymer chemistry to material science to develop structured nanoparticles for applications in photonics and shape memory materials.
Programming anisotropy into responsive soft materials. The project aims to generate viscoelastic soft materials with programmable anisotropy using aqueous suspensions of colloidal rods that have tunable surface coatings. The project expects to generate new knowledge in the rheology and structural characteristics of this unique class of materials. A key innovation is the use of charge-directed polymer self-assembly to control colloidal interactions, suspension rheology and phase behaviour. The in ....Programming anisotropy into responsive soft materials. The project aims to generate viscoelastic soft materials with programmable anisotropy using aqueous suspensions of colloidal rods that have tunable surface coatings. The project expects to generate new knowledge in the rheology and structural characteristics of this unique class of materials. A key innovation is the use of charge-directed polymer self-assembly to control colloidal interactions, suspension rheology and phase behaviour. The intended outcome is spatial control over the orientation of nanostructures, potentially mimicking the structural hierarchy found in nature. This should provide significant benefits to the creation of viscoelastic materials with complex rheology as well as structural, mechanical and optical heterogeneity.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101259
Funder
Australian Research Council
Funding Amount
$360,000.00
Summary
A predictive, ab initio design of enhanced plasmonic photocatalysts. Plasmonic catalysis is a promising platform for sunlight-driven chemical reactions that employs optically absorptive plasmonic-metal/semiconductor nanostructures. However, it suffers from poor external quantum efficiencies. The aim of this project is to rationally design an efficient plasmonic photocatalyst utilizing state-of-the-art ab initio computations. The project is expected to provide insights on various atomic-level rea ....A predictive, ab initio design of enhanced plasmonic photocatalysts. Plasmonic catalysis is a promising platform for sunlight-driven chemical reactions that employs optically absorptive plasmonic-metal/semiconductor nanostructures. However, it suffers from poor external quantum efficiencies. The aim of this project is to rationally design an efficient plasmonic photocatalyst utilizing state-of-the-art ab initio computations. The project is expected to provide insights on various atomic-level reaction steps involved and consequently develop a set of catalyst design principles to guide experiments. The project will largely benefit Australia’s and international renewable energy sector and chemical industries by generating knowledge in catalysis relevant for hydrogen production and greenhouse gas reduction. Read moreRead less
Nanoscale silicon field-effect transistor diagnostic technology. This project aims to overcome barriers to the implementation of silicon field-effect transistor biosensors. It will investigate the biosensors’ physical and structural properties. This knowledge, combined with technological and conceptual advances, could foster the development of an advanced and translational point-of-care diagnostic technology to rapidly and sensitively detect malignant tissues. Such technology would have commerci ....Nanoscale silicon field-effect transistor diagnostic technology. This project aims to overcome barriers to the implementation of silicon field-effect transistor biosensors. It will investigate the biosensors’ physical and structural properties. This knowledge, combined with technological and conceptual advances, could foster the development of an advanced and translational point-of-care diagnostic technology to rapidly and sensitively detect malignant tissues. Such technology would have commercial potential and important societal benefits.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100986
Funder
Australian Research Council
Funding Amount
$401,000.00
Summary
High-performance, portable ion-mobility surface-acoustic wave spectrometry. This project aims to develop a high-performance, cost-effective, palm-portable differential ion mobility spectrometer for universal chemical analysis that operates at atmospheric pressure and consumes minimal power. A significant problem in current analytical chemistry is the lack of rapid and cost-effective methods that can be used in the field for analysis of many different chemical species of environmental and biologi ....High-performance, portable ion-mobility surface-acoustic wave spectrometry. This project aims to develop a high-performance, cost-effective, palm-portable differential ion mobility spectrometer for universal chemical analysis that operates at atmospheric pressure and consumes minimal power. A significant problem in current analytical chemistry is the lack of rapid and cost-effective methods that can be used in the field for analysis of many different chemical species of environmental and biological importance. The project expects to enable the rapid and simultaneous separation and detection of many different ions from complex mixtures with high selectivity and sensitivity. The spectrometer can be implemented in the field for various applications such as atmospheric monitoring, disease diagnosis and chemical weapons detection.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE160100234
Funder
Australian Research Council
Funding Amount
$155,000.00
Summary
Facility for Nanometer Scale Microscopy, Characterization, and Fabrication. Facility for nanometre-scale microscopy, characterisation, and fabrication:
This project aims to create a collaborative research facility for the microscopy and characterisation of nanometre structured devices and materials, enabling researchers to visualise and quantify the topography, chemical composition and structure of samples with a resolution approaching the atomic scale. A WiTek Alpha300SR microscope is capable ....Facility for Nanometer Scale Microscopy, Characterization, and Fabrication. Facility for nanometre-scale microscopy, characterisation, and fabrication:
This project aims to create a collaborative research facility for the microscopy and characterisation of nanometre structured devices and materials, enabling researchers to visualise and quantify the topography, chemical composition and structure of samples with a resolution approaching the atomic scale. A WiTek Alpha300SR microscope is capable of simultaneous atomic force microscopy, near-field scanning optical microscopy, photocurrent mapping, and Raman spectroscopy. These capabilities would allow the mapping of topography and chemical composition, response to optical stimulus, and the structure of materials in 3-D with nanometre-scale resolution on surfaces. This instrument would support research in areas such as organic photovoltaics, nanofabrication, polymer electronics, ionic fluids, functional interfaces, and thermionic devices.Read moreRead less