Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a rema ....Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a remarkable energy density, high stability and low cost. This should provide significant benefits, such as improving the capacity and robustness of low-cost hydrogen storage and transportation, reducing energy costs and making hydrogen energy a more accessible and sustainable clean energy source for Australia.Read moreRead less
Mesoporous Metal Scaffolds: Reactive Containment Vessels. The storage of hydrogen is one of the most important issues that remains to be solved before the mass implementation of hydrogen as an energy carrier becomes commercially viable. This project aims to determine the kinetic and thermodynamic benefits of mesoporous metal scaffolds as reactive containment vessels for hydrogen storage materials. Fundamental experimental research into the synthesis, characterisation, and modification of nano-co ....Mesoporous Metal Scaffolds: Reactive Containment Vessels. The storage of hydrogen is one of the most important issues that remains to be solved before the mass implementation of hydrogen as an energy carrier becomes commercially viable. This project aims to determine the kinetic and thermodynamic benefits of mesoporous metal scaffolds as reactive containment vessels for hydrogen storage materials. Fundamental experimental research into the synthesis, characterisation, and modification of nano-confined hydrogen storage materials will be carried out. The results of this research are expected be used to tune hydrogen desorption temperatures and pressures of various light weight hydrogen storage materials to generate new materials attractive to the automobile industry.Read moreRead less
Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safet ....Improving battery safety with boron nitride nanotube separators. This project aims to improve the safety of lithium ion batteries by developing high –temperature, stable separators. The use of batteries in a hot Australian summer is a major safety issue for our society. This project will develop a new and safe battery technology with the help of boron nitride nanotubes to effectively reduce the risk of thermal runaway of battery cells. The expected outcomes will have a global impact on the safety of the current battery technology and the innovative application of boron nitride nanotubes in battery technology. It will position industry on the cutting edge of battery technology required for energy storage development in Australia.Read moreRead less
ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green che ....ARC Centre of Excellence for Carbon Science and Innovation. ARC Centre of Excellence for Carbon Science and Innovation. This Centre aims to develop carbon-based catalysts for clean energy, CO2 capture, and green chemistry to reduce emissions. The Centre expects to use pioneering data-guided atomic-precision synthesis and multiscale analysis to transform fundamental science of carbon materials. Expected outcomes of this Centre will benefit new technologies for energy, environmental, and green chemical industries by utilising abundant sunlight, seawater, and waste feedstocks. This should provide significant benefits, through industry collaborations, our new world-leading capacity will train a next generation of game changers to empower emerging carbon industries to solve grand socio-economic challenges, ultimately meeting zero-carbon emissions targets.Read moreRead less
Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy stora ....Spinning Nanosheets for Versatile Applications. This project seeks to develop a highly versatile and innovative fibre spinning research platform for fabricating multifunctional hybrid fibres with unprecedented mechanical, electrical and electrochemical properties. The novel fibres to be produced can be assembled into macroscale architectures or be weaved into functional textiles that can feed into relevant technologies and Australian industries such as advanced textiles for wearable energy storage and conversion, microelectrodes and sensors, and smart medical/biomedical platforms. More importantly, this project will have far reaching implications across a range of research disciplines, and ultimately sectors critical to Australia’s health, social, and economic future.Read moreRead less
Diatomic Electrocatalysts for Efficient Carbon Dioxide Conversion. This project will create novel electrocatalysts to produce valuable C2 compounds (ethylene, ethanol and ethylene glycol) from carbon dioxide reduction reaction. The precise catalyst structure control remains challenging but is crucial for pushing catalyst performance towards practical applications. By innovating organic macrocycle molecules as precursors, this project will generate a new paradigm of diatomic electrocatalysts with ....Diatomic Electrocatalysts for Efficient Carbon Dioxide Conversion. This project will create novel electrocatalysts to produce valuable C2 compounds (ethylene, ethanol and ethylene glycol) from carbon dioxide reduction reaction. The precise catalyst structure control remains challenging but is crucial for pushing catalyst performance towards practical applications. By innovating organic macrocycle molecules as precursors, this project will generate a new paradigm of diatomic electrocatalysts with structure control precision at atomic-scale. Such catalysts are expected to deliver high catalytic performance to accelerate the transformation to a carbon-neutral future. Synchronously, they will also serve as an ideal platform for in-depth mechanism study and establishing guidelines for rational catalyst design Read moreRead less
Nanoporous nanorods with improved electrochemical properties. This project applies the latest nanotechnology to produce new nanomaterials for energy storage applications. The aim is to significantly improve supercapacitor performance for use in the storage of clean energy and harvesting of wasted energy which will contribute to a clean energy economy.
A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerat ....A new design strategy for supercapacitors. This project aims to build a new equivalent electric circuit model using structurally tuneable graphene-based porous electrodes to establish a quantitative structure-property-performance relationship for super-capacitors. The new model will then be used to design novel electrode and device architectures to realise new energy storage devices with high usable storage capacity at high operation rates. This new computer-aided strategy will greatly accelerate the design of next-generation high-performance super-capacitors, and bring significant benefit to Australia's emerging knowledge-based manufacturing industry.Read moreRead less
Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project wi ....Systems engineering approach to nanostructuring porous electrodes for compact capacitive energy storage. This project will develop a new systems engineering approach to fabricating porous yet densely packed electrodes with high ion-accessible surface area and low ion transport impedance. This will lead to new-generation compact electrochemical capacitive energy storage systems that can combine high energy density, fast charging/discharging rate and long cycle life. The success of this project will facilitate future large-scale adoption of renewable energy and many other new emerging technologies such as portable/wearable electronics, electric vehicles, and energy regeneration systems.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE240100049
Funder
Australian Research Council
Funding Amount
$1,200,000.00
Summary
In-situ nanomechanical testing for materials under extreme environments. This project aims to establish a state-of-the-art in-situ nanomechanical testing capability for materials under extreme environments. A cutting-edge nanoindentation stage with customisable modules, as well as an optimally configured scanning electron microscope, will enable this capability for the first time in Australia. The expected outcomes will provide valuable insights into how microstructures affect mechanical propert ....In-situ nanomechanical testing for materials under extreme environments. This project aims to establish a state-of-the-art in-situ nanomechanical testing capability for materials under extreme environments. A cutting-edge nanoindentation stage with customisable modules, as well as an optimally configured scanning electron microscope, will enable this capability for the first time in Australia. The expected outcomes will provide valuable insights into how microstructures affect mechanical properties at temperatures ranging from -150 to 1000 °C, strain rates from 10E-5/s to 10E5/s, and liquid environments. The resulting knowledge will guide the development of structural materials that withstand harsh environmental conditions, thereby advancing Australia's advanced manufacturing and sustainable energy sectors.Read moreRead less