A compact microphone array system for outdoor low frequency noise measurements. To investigate the impact of wind farm noise on surrounding communities, the sound level caused by wind turbines must be accurately measured, which sometimes is hard due to wind induced noise and other interference noise. This project aims to propose a novel compact microphone array solution, where the wind induced noise is attenuated by a specially designed windproof shell first, and then the residual wind induced n ....A compact microphone array system for outdoor low frequency noise measurements. To investigate the impact of wind farm noise on surrounding communities, the sound level caused by wind turbines must be accurately measured, which sometimes is hard due to wind induced noise and other interference noise. This project aims to propose a novel compact microphone array solution, where the wind induced noise is attenuated by a specially designed windproof shell first, and then the residual wind induced noise and other interference noise are further filtered out by a specific adaptive noise cancellation algorithm based on the spherical and differential microphone array structure. With the proposed system, the measurement configuration size is expected to be reduced from the current few metres to less than 10 centimetres, and with better accuracy.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
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
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
Future 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.
Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology ....Sustainable high energy sodium batteries with enhanced safety & cycle life. This project aims to deliver a high specific energy, ambient temperature sodium metal battery that is more sustainable, safer and better performing than existing technologies. Innovative chemistry will be used to replace the current flammable and toxic organic solvent-based systems, while novel tools and capabilities will be forged to retain Australian leadership in this sector. These advances will provide a technology and materials platform to generate and support emerging energy storage industries in Australia. It will strengthen international collaborations with leading research teams and provide opportunities and training for the next generation of energy storage research leaders in both academia and industry.Read moreRead less
High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new con ....High-performance smart solar powered on-chip capacitive energy storage. High performance and environmentally friendly on-chip power system is the key bottleneck issue limiting the further performance improvement and miniaturisation of ever-increasing portable optoelectronic devices. Building on previous work, including recent breakthroughs of on-chip photonic devices in patterned graphene oxide thin film and the record-breaking nanophotonics solar cells, the project aims to investigate a new concept of super-resolution direct laser printing and simultaneous dopant activation of graphene oxide thin films. It is expected that the conceptually new development of the functional graphene oxide film patterning will allow for smart solar-powered on-chip power systems that outperform the state-of-the-art pollution generating batteries.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100427
Funder
Australian Research Council
Funding Amount
$446,000.00
Summary
Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-f ....Engineered multifunctional membranes for aqueous organic redox flow battery. This project aims to develop multifunctional membranes with high ion conductivity and selectivity and high energy density to address the key challenges in the development of aqueous organic redox flow battery for renewable energy storage. The project will develop novel methodologies for precisely tuning and functionalising microporous materials to achieve cost-effective and scalable fabrication of membranes with multi-functions, thus improving the energy efficiency and retaining the cycling capacity of redox flow batteries. The advancement of multifunctional membranes will enhance the efficiency of storage of intermittent and fluctuating renewable resources, thereby contributing to the reduction of carbon footprint in Australia. Read moreRead less