Multi-resolution situation recognition for urban-aware smart assistant. This project aims to develop a situation recognition framework to recognise and anticipate unforeseen emerging situations, such as schedule changes, incidents, and disruptions in an urban environment. The project will address a significant knowledge gap by capturing and modelling unpredictability in human mobility and work routines. The outcome will be a situation recognition framework that can be applied at the individual, ....Multi-resolution situation recognition for urban-aware smart assistant. This project aims to develop a situation recognition framework to recognise and anticipate unforeseen emerging situations, such as schedule changes, incidents, and disruptions in an urban environment. The project will address a significant knowledge gap by capturing and modelling unpredictability in human mobility and work routines. The outcome will be a situation recognition framework that can be applied at the individual, social group, and urban level, and at multiple locations and time scales. This should provide users with timely notifications and recommendations to resume their activities and routines. The expected benefits will be far-ranging and adaptable to many domains, from personal smart assistants to trip planning and emergency services.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE180100346
Funder
Australian Research Council
Funding Amount
$328,075.00
Summary
Probing extreme astrophysics via rapid response to cosmic explosions. This project aims to reveal the radio emission properties of particular classes of gravitational wave events through the utilisation and further development of rapid-response observing systems on Australian radio telescopes. The project will use Australian radio telescopes to rapidly and automatically obtain observations of short-duration gamma-ray bursts, which are thought to be a subclass of gravitational wave events. It is ....Probing extreme astrophysics via rapid response to cosmic explosions. This project aims to reveal the radio emission properties of particular classes of gravitational wave events through the utilisation and further development of rapid-response observing systems on Australian radio telescopes. The project will use Australian radio telescopes to rapidly and automatically obtain observations of short-duration gamma-ray bursts, which are thought to be a subclass of gravitational wave events. It is anticipated such observations will provide vital insight into the early-time radio signatures of gravitational wave events and that rapid-response experiments will contribute invaluable knowledge towards optimising transient science conducted with the Square Kilometre Array.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
Future sodium based electrochemical energy storage technologies. New rechargeable batteries will be developed through the use of breakthrough electrolytes based on liquid salts. These batteries are vital for the widespread use of renewables in Australia's electricity grid. They will also enable new generations of environmental sensor technology.
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
Next-generation fluid-in-solid capacitor materials. This project will create next-generation materials to maximize the energy and power densities of electrochemical capacitors (ECs). The performance gap between batteries and ECs remains paradox. Devices with high energy and power densities will largely boost the performance of electric vehicles, mobile devices and smart grids. By innovating the design of capacitor materials using layered fluid-in-solid architecture, the project will produce new- ....Next-generation fluid-in-solid capacitor materials. This project will create next-generation materials to maximize the energy and power densities of electrochemical capacitors (ECs). The performance gap between batteries and ECs remains paradox. Devices with high energy and power densities will largely boost the performance of electric vehicles, mobile devices and smart grids. By innovating the design of capacitor materials using layered fluid-in-solid architecture, the project will produce new-concept ECs with energy density approaching to batteries. Such ECs will synchronously possess dramatically high power density, intrinsically unlike hybrid battery-capacitor. This project will maximize the efficiency of future electronics, vehicles and grids with the new generation ECs.Read moreRead less
Advanced Na battery technology; key to transforming society's energy use. This project aims to advance energy storage technology based on low cost and sustainable sodium chemistry through understanding new electrode and electrolyte materials combinations, particularly to enhance the way charge is moved across the electrolyte–electrode interface. Sodium batteries represent a low-cost alternative to existing lithium devices and their development will affect a broad range of technologies. This is e ....Advanced Na battery technology; key to transforming society's energy use. This project aims to advance energy storage technology based on low cost and sustainable sodium chemistry through understanding new electrode and electrolyte materials combinations, particularly to enhance the way charge is moved across the electrolyte–electrode interface. Sodium batteries represent a low-cost alternative to existing lithium devices and their development will affect a broad range of technologies. This is especially relevant to electric vehicles and renewable energy where large, expensive batteries are needed.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE190100465
Funder
Australian Research Council
Funding Amount
$408,000.00
Summary
Advanced sodium batteries using 2D material interphases with ionic liquids. This project aims to stabilise alkali metal electrodes that are necessary for the development of advanced batteries by using interphase engineering mechanisms to protect electrodes from unfavourable reactions. This project will enable the use of high-energy and safer anodes, essential in promoting better use of renewable energy in the future. This is expected to contribute to fundamental knowledge and have real commercia ....Advanced sodium batteries using 2D material interphases with ionic liquids. This project aims to stabilise alkali metal electrodes that are necessary for the development of advanced batteries by using interphase engineering mechanisms to protect electrodes from unfavourable reactions. This project will enable the use of high-energy and safer anodes, essential in promoting better use of renewable energy in the future. This is expected to contribute to fundamental knowledge and have real commercial prospects for sodium batteries via improved artificial protective interface design. This project has many potential benefits, such as the development of new materials and processes needed to produce safe, high-capacity batteries with applications in both smart-grid, and behind-the-meter stationary storage.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE210101896
Funder
Australian Research Council
Funding Amount
$436,875.00
Summary
Interface engineering of 2D materials for advanced battery application. The fast-growing energy storage market demands new devices with both high energy and power density. This project aims to understand and then engineering electrode-electrolyte interfaces using novel two-dimensional (2D) materials to achieve accelerated ion transport and enhanced surface redox reactions. Advanced in-situ and ex-situ characterization tools, including X-ray scattering, neutron scattering, and terahertz time-doma ....Interface engineering of 2D materials for advanced battery application. The fast-growing energy storage market demands new devices with both high energy and power density. This project aims to understand and then engineering electrode-electrolyte interfaces using novel two-dimensional (2D) materials to achieve accelerated ion transport and enhanced surface redox reactions. Advanced in-situ and ex-situ characterization tools, including X-ray scattering, neutron scattering, and terahertz time-domain spectroscopy, will be employed to study energy storage mechanisms. Novel solid-state batteries will be demonstrated based on well-designed electrodes using 2D materials. This project will boost the standing of Australia in the global competition of developing more efficient energy storage devices. Read moreRead less
Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include tw ....Novel Fuel Materials for Radiation-Free Proton-Boron Fusion Power Source. Laser proton-boron fusion reactions are a radiation-free nuclear energy source but are limited by a low reaction rate due to a lack of efficient fuel materials. This project aims to develop new fuel materials by synthesising isotope boron 11 enriched hydrogen borides and hydrogen adsorbed boron nitride nanosheets using our research experience in hydrogen storage and nanomateials synthesis. The expected outcomes include two new hydrogen storage nanomaterials, the associated new synthesis technologies, and a clean and safe nuclear power source, which helps to reduce carbon dioxide emissions.Read moreRead less