Linkage Infrastructure, Equipment And Facilities - Grant ID: LE100100177
Funder
Australian Research Council
Funding Amount
$300,000.00
Summary
Advanced electron paramagnetic resonance (EPR) facilities for chemical, biological and materials sciences. New instrumentation to advance national research in hydrogen fuel generation from renewable sources, new generation photo-voltaic technologies, novel polymer and other chemical materials and advanced computing systems will be provided by this project. A new high sensitivity electron paramagnetic resonance facility, located at the Australian National University, will serve researchers in the ....Advanced electron paramagnetic resonance (EPR) facilities for chemical, biological and materials sciences. New instrumentation to advance national research in hydrogen fuel generation from renewable sources, new generation photo-voltaic technologies, novel polymer and other chemical materials and advanced computing systems will be provided by this project. A new high sensitivity electron paramagnetic resonance facility, located at the Australian National University, will serve researchers in the ACT region devoted to the broad range of activities summarised above. A particular focus involves novel, biologically inspired energy systems and high efficiency solar cell technology.Read moreRead less
Increasing solid electrolyte conductivity through defect design. This project aims to engineer electrolyte materials, based on organic ionic plastic crystals, and use isomeric doping to improve the ionic conductivity. The development of safer batteries relies on eliminating the volatile and flammable solvents commonly used as the electrolyte. Improving the safety and performance of batteries is important as electricity costs increase. Solid state ionic electrolytes can address leakage and volati ....Increasing solid electrolyte conductivity through defect design. This project aims to engineer electrolyte materials, based on organic ionic plastic crystals, and use isomeric doping to improve the ionic conductivity. The development of safer batteries relies on eliminating the volatile and flammable solvents commonly used as the electrolyte. Improving the safety and performance of batteries is important as electricity costs increase. Solid state ionic electrolytes can address leakage and volatility problems, but the conductivity must be improved if these materials are to support high battery power. The project’s electrolyte materials can be used in lithium metal batteries, which have higher theoretical energy densities than traditional lithium ion batteries. This project will develop new solid state electrolytes, with improved conductivity, and use these materials in emerging lithium battery technologies.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180101454
Funder
Australian Research Council
Funding Amount
$359,446.00
Summary
High performance lead-free piezoelectrics based on polar nanoregions. This project aims to enhance the electro-mechanical couplings of lead free piezoelectrics via introducing polar nanoregions for medical transducers applications. This is expected to impact on the design and development of high-performance lead free piezoelectrics, and have environmental benefits through replacing lead based counterparts.
Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifun ....Exploring piezoelectricity of two-dimensional nanocrystals and nanodevices. This project aims to study piezoelectricity in two-dimensional (2D) nanocrystals and nano-devices. This project expects to result in the formulation of new 2D piezoelectric, ferroelectric and multiferroic theory, syntheses of 2D crystals and exploration of their functionalities, which are directly implemented in innovative electronic and photonic components. This will contribute to the advancement of both new 2D multifunctional materials and new nanodevice structures which may open up unprecedented opportunities for both scientific and technological endeavoursRead moreRead less
An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefi ....An account of wetting phenomena on nano-engineered surfaces. This project aims to provide researchers and industry with a toolbox to predict wetting behaviour on surfaces with nanoscale topography. A combined experimental and numerical study will lead to the discovery of the mechanisms by which topographical and chemical properties of the surface trigger the formation of nanostructure-induced air pockets and how these phenomena determine surface wettability. This will provide significant benefits, as the predictive surface-wettability model will enhance controllability and productivity of diverse manufacturing processes and lead to new applications, high-value products and economic benefits in mining, energy, electronics, biomedicine and other fields.Read moreRead less
Micropatterned polymer film coatings for the capture of water directly from the atmosphere. This project will produce micropatterned surface coatings that collect large amounts of water from the atmosphere. Through this technology, isolated and drought-prone regions of Australia will be able to partially satisfy their water supply needs, in a manner that is economically and environmentally sustainable.
Benchmarking of advanced scattering probes for materials characterisation. The project seeks to establish the accuracy and validity of different methods of nanoscale structure determination. Nanoscale structure is crucial to the properties of many modern materials with diverse applications: e.g. sensors and actuators in cell phones; smart shock absorbers and fuel injectors in cars; memory devices; drug delivery devices.
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
Discovery Early Career Researcher Award - Grant ID: DE220101113
Funder
Australian Research Council
Funding Amount
$428,000.00
Summary
Optimal reaction pathways towards advanced energy technology. This project aims to develop a novel lithium-ion battery (LIB) system that delivers high energy-density, a long cycle life, low-cost, and high safety based on conversion-type lithium oxide cathodes. Expected outcomes of this project will address the preliminary challenges for the practical use of lithium-oxide, which requires innovative designs of reaction pathways to lithium oxide cathode and lithium metal anode architectures as well ....Optimal reaction pathways towards advanced energy technology. This project aims to develop a novel lithium-ion battery (LIB) system that delivers high energy-density, a long cycle life, low-cost, and high safety based on conversion-type lithium oxide cathodes. Expected outcomes of this project will address the preliminary challenges for the practical use of lithium-oxide, which requires innovative designs of reaction pathways to lithium oxide cathode and lithium metal anode architectures as well as a fundamental in-depth understanding of the electrochemical and growing mechanisms. This project will establish a manufacturing road-map for a novel lithium-ion battery system in Australia with practical reliability by integrating active lithium oxide cathode, optimized electrolyte, and lithium metal anode.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE170100235
Funder
Australian Research Council
Funding Amount
$388,000.00
Summary
Spectroscopy and imaging platform for photoactive materials. This project aims to establish a comprehensive analytic tool-box to characterise solution-processable materials for thin-film solar cells based on materials such as perovskites. These materials have light harvesting properties with absorption edges beyond 800 nm. This project will focus on time-resolved transient absorption and microwave conductivity phenomena and on lock-in thermographic imaging capabilities. This will accelerate mate ....Spectroscopy and imaging platform for photoactive materials. This project aims to establish a comprehensive analytic tool-box to characterise solution-processable materials for thin-film solar cells based on materials such as perovskites. These materials have light harvesting properties with absorption edges beyond 800 nm. This project will focus on time-resolved transient absorption and microwave conductivity phenomena and on lock-in thermographic imaging capabilities. This will accelerate materials and technological development in this research field. This project is expected to help the local and global energy sector transition to sustainable energy, provide a competitive edge for commercialisations of solar technologies in Australia, and benefit the economy, environment and national security.Read moreRead less