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.
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100036
Funder
Australian Research Council
Funding Amount
$771,000.00
Summary
Nuclear magnetic resonance spectroscopy facilities - Advancing cutting-edge chemical, biological, energy and materials research in Western Australia. Nuclear magnetic resonance spectroscopy facilities: advancing cutting-edge chemical, biological, energy and materials research: This project will establish new nuclear magnetic resonance spectroscopy facilities supporting high-throughput metabolite detection, diffusion measurement, and small-volume sample identification. The project will support re ....Nuclear magnetic resonance spectroscopy facilities - Advancing cutting-edge chemical, biological, energy and materials research in Western Australia. Nuclear magnetic resonance spectroscopy facilities: advancing cutting-edge chemical, biological, energy and materials research: This project will establish new nuclear magnetic resonance spectroscopy facilities supporting high-throughput metabolite detection, diffusion measurement, and small-volume sample identification. The project will support research across diverse priorities including: energy and minerals; ecology, evolution and the environment; and medicine and health. The project will open new opportunities for areas such as metabolomics and oil and gas processing, and greatly expand capacity to meet strongly increasing demand.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE200100162
Funder
Australian Research Council
Funding Amount
$444,000.00
Summary
Quantitative Movies of Nanoscale Dynamics by Video Atomic Force Microscopy. This project aims to address an urgent need for Australian researchers to undertake previously impossible real time studies of nanoscale dynamics concerning colloids and surfaces with unprecedented structural and temporal resolution using Video Rate Atomic Force Microscopy. This will lead to a step changes in understating, and rapid progress, in colloids and surfaces projects spanning chemistry, biology, biochemistry, m ....Quantitative Movies of Nanoscale Dynamics by Video Atomic Force Microscopy. This project aims to address an urgent need for Australian researchers to undertake previously impossible real time studies of nanoscale dynamics concerning colloids and surfaces with unprecedented structural and temporal resolution using Video Rate Atomic Force Microscopy. This will lead to a step changes in understating, and rapid progress, in colloids and surfaces projects spanning chemistry, biology, biochemistry, medicine, engineering, sensors and materials science. The new information the delivered will enable colloids and surfaces to be refined with precision for function, build on domestic expertise in allied methods, and place Australian researchers at the forefront of the study of molecular scale process.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE150100187
Funder
Australian Research Council
Funding Amount
$290,000.00
Summary
SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano in ....SA Facility for High Resolution Imaging and Material Characterization. Facility for high resolution imaging and material characterisation: The aim of this project is to establish a facility that will allow researchers to visualise and analyse structure at nanoscale resolutions. The development of the next generation of opto-electronics, electrochemical and biomedical devices requires tools that can quickly visualise and characterise complex materials at multiscale. The new collaborative nano infrared thermal analysis facility is essential to meet the demands of a large number of innovative projects conducted by multidisciplinary consortia of researchers. Located in state-of-the art laboratories and managed as open access resources, the facility will enable and advance research in the areas of energy harvesting, environmental monitoring, biomedical devices, food and pharmaceuticals.Read moreRead less
Surface forces and confinement of anisotropic particles. Advanced materials assembled from engineered particles found in next generation solar cells, nano-electronics, photonic materials, and nano-sensors have experienced an explosion in research interest over the past decade. This is in large part due to improving techniques for the synthesis of anisotropy in particle shape to form rods, plates, iso-hedra and nano-prisms and material properties such as janus particles used for self-assembly. Ho ....Surface forces and confinement of anisotropic particles. Advanced materials assembled from engineered particles found in next generation solar cells, nano-electronics, photonic materials, and nano-sensors have experienced an explosion in research interest over the past decade. This is in large part due to improving techniques for the synthesis of anisotropy in particle shape to form rods, plates, iso-hedra and nano-prisms and material properties such as janus particles used for self-assembly. However, there is a lack of methods to measure the interactions that control the assembly process. This project aims to develop a novel method to quantify the particle-particle and particle-surface interactions for anisotropic particles to enable predictive approaches to particle assembly for advanced materials.Read moreRead less
Algorithms for multi-scale problems in science and engineering. This project aims to develop theoretical formulations and algorithms for modelling fundamental problems in molecular electrostatics, dispersion force theory, acoustics and electromagnetic scattering in applications where current approaches may be useless. Many engineering applications, from microelectronics to bioengineering devices, need to operate across dimensions from a few millimetres down to a million times smaller. This large ....Algorithms for multi-scale problems in science and engineering. This project aims to develop theoretical formulations and algorithms for modelling fundamental problems in molecular electrostatics, dispersion force theory, acoustics and electromagnetic scattering in applications where current approaches may be useless. Many engineering applications, from microelectronics to bioengineering devices, need to operate across dimensions from a few millimetres down to a million times smaller. This large range of length scales means traditional modelling tools and computational techniques will rapidly become intractable. This project will meet this need to strengthen the Australian technological skill base and contribute to innovations in areas ranging from bioengineering to nanotechnology.Read moreRead less
Modelling of soft multi-scale systems. This project develops realistic physical models and efficient computational methods as the platform technology for giving highly accurate predictions of the complex behaviour of soft deformable systems. The outcomes will add to our understanding of the mechano-biology of living cells and artificial soft body tissues, the cellular uptake of nutrients and drugs, the energy-efficient processing of high value pharmaceutical emulsions and the design of functiona ....Modelling of soft multi-scale systems. This project develops realistic physical models and efficient computational methods as the platform technology for giving highly accurate predictions of the complex behaviour of soft deformable systems. The outcomes will add to our understanding of the mechano-biology of living cells and artificial soft body tissues, the cellular uptake of nutrients and drugs, the energy-efficient processing of high value pharmaceutical emulsions and the design of functional polymers and proteins using molecular models. The new knowledge will advance the frontier of material design and characterisation of soft complex materials.Read moreRead less
Unravelling the rules on particle assembly into superstructures. Nanoparticle superstructures are assemblies of particles that exhibit high surface-to-volume ratio, periodicity and large packing density useful for drug delivery, photonics, sensing and energy storage. To realise the potential of these materials requires a predicative understanding of how interparticle forces control superstructure formation. This project will create a one-of-its-kind multiscale simulation framework to tailor the ....Unravelling the rules on particle assembly into superstructures. Nanoparticle superstructures are assemblies of particles that exhibit high surface-to-volume ratio, periodicity and large packing density useful for drug delivery, photonics, sensing and energy storage. To realise the potential of these materials requires a predicative understanding of how interparticle forces control superstructure formation. This project will create a one-of-its-kind multiscale simulation framework to tailor the assembly of anisotropic engineered nanoparticles into superstructures in liquids. Nanoparticle assembly simulation will be validated with a novel particle tracking microscopy in solution-based studies. This will enable the design and large-scale production of nanomaterials with controlled properties and functions.Read moreRead less