Extreme astrophysics in the age of gravitational waves. This project aims to probe the most catastrophic explosions in the universe. It will use gravitational wave astronomy to detect an exotic effect that causes space to permanently deform following cataclysmic events, determine the origin of binary black holes by measuring statistical properties of many mergers, and use observations of colliding neutron stars to understand the physics of the biggest explosions in the Universe. This project wil ....Extreme astrophysics in the age of gravitational waves. This project aims to probe the most catastrophic explosions in the universe. It will use gravitational wave astronomy to detect an exotic effect that causes space to permanently deform following cataclysmic events, determine the origin of binary black holes by measuring statistical properties of many mergers, and use observations of colliding neutron stars to understand the physics of the biggest explosions in the Universe. This project will lay the framework for the next decade of the new field of gravitational-wave astronomy.Read moreRead less
The red belly blockchain: a scalable blockchain for internet of things. This project aims to offer a blockchain that scales with the number of participants. There have been major investments in blockchain technologies during the last year as blockchains promise to disrupt industries like supply chains. Unfortunately, blockchains cannot solve this problem in their current form, because they cannot scale. They require resources that grow with the number of participants and yet fail at providing in ....The red belly blockchain: a scalable blockchain for internet of things. This project aims to offer a blockchain that scales with the number of participants. There have been major investments in blockchain technologies during the last year as blockchains promise to disrupt industries like supply chains. Unfortunately, blockchains cannot solve this problem in their current form, because they cannot scale. They require resources that grow with the number of participants and yet fail at providing increasing performance. The project will leverage many devices of limited resources to offer higher performance and will impact the distributed computing field by establishing a new connection between energy efficient systems and highly scalable distributed algorithms.Read moreRead less
High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expec ....High-voltage electrode materials for lithium-ion batteries. This project aims to establish a complete battery research system and develop high-voltage electrode materials for lithium-ion batteries through mechanistic understanding obtained in operando studies. Lithium-ion batteries are the most promising choice for portable electronic devices, including electric vehicles, due to their high power and energy performance compared with other battery technologies. The success of this project is expected to advance fundamental understanding of lithium-ion batteries, and provide techniques to develop a promising high-energy and high-power battery system.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
Addressing Challenges for the Future Grids – Harmonics Standardization. The main aim of this project is to deliver appropriate frequency standardisation to protect electricity grids and support the use of renewable energy sources. Globally, there is no harmonic standardisation within the frequency range of 2–150 kHz, which can significantly affect the reliability of electricity networks and smart grids. Electricity networks are increasingly using renewable energy sources and an efficient loads a ....Addressing Challenges for the Future Grids – Harmonics Standardization. The main aim of this project is to deliver appropriate frequency standardisation to protect electricity grids and support the use of renewable energy sources. Globally, there is no harmonic standardisation within the frequency range of 2–150 kHz, which can significantly affect the reliability of electricity networks and smart grids. Electricity networks are increasingly using renewable energy sources and an efficient loads approach based on power electronics technology. However, this can affect grid reliability and robustness. The project aims to develop advanced tools to better understand the power quality issues of Australian residential, commercial and industrial distribution networks. It also aims to develop novel techniques to improve power quality and reliability of the grids, and to develop harmonics emission and immunity levels to modify the Australian standards accordingly.Read moreRead less
Blue energy harvesting and storage technology for wearable electronics. This project aims to develop new self-charging power devices that can harvest and store body energy generated during body motions, and power smart and implantable medical electronics. The project will develop new Piezo-supercapacitors by designing new electrode materials and cell designs. The charge storage and transport kinetics will be uncovered using advanced in-situ characterisation techniques and modern simulation metho ....Blue energy harvesting and storage technology for wearable electronics. This project aims to develop new self-charging power devices that can harvest and store body energy generated during body motions, and power smart and implantable medical electronics. The project will develop new Piezo-supercapacitors by designing new electrode materials and cell designs. The charge storage and transport kinetics will be uncovered using advanced in-situ characterisation techniques and modern simulation methods. The project expects to generate new knowledge in blue energy harvesting and storage systems, training for young scientists, and generate intellectual property with potential commercialised products to be used in implantable devices, placing Australia at the forefront of new technology.Read moreRead less
2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomin ....2D vertical heterostructures for multi-functional energy applications. This project aims to develop multi-functional 2D vertical heterostructures for sustainable energy applications. A key challenge in fabricating 2D vertical heterostructures is the re-stacking of layered materials. This project will utilize edge-rich vertical graphene to unleash the full potential of 2D vertical heterostructures by combining the advantages of individual building blocks while mitigating the associated shortcomings. Expected outcomes will include improved electrochemical performance of materials and an integrated energy system utilizing these multi-functional materials to produce green hydrogen at low cost and high efficiency. The project should contribute largely to Australia’s transition to robust and affordable clean energy.Read moreRead less
Characterising and Manipulating Triplet Interactions. Organic optoelectronic devices are based on organic semiconductors and are found throughout modern life. They underpin technologies such as phone and television displays, low-energy lighting, and solar cells.
The project Aims to use spectroscopy to comprehensively understand the underlying physics of organic optoelectronic device materials. This is Significant enabling science that will accelerate development of light-emitting diodes, solar ....Characterising and Manipulating Triplet Interactions. Organic optoelectronic devices are based on organic semiconductors and are found throughout modern life. They underpin technologies such as phone and television displays, low-energy lighting, and solar cells.
The project Aims to use spectroscopy to comprehensively understand the underlying physics of organic optoelectronic device materials. This is Significant enabling science that will accelerate development of light-emitting diodes, solar cells, and new quantum information technologies. Expected outcomes include new knowledge about organic semiconductors, enhanced Australian research capacity, and international collaboration. Benefits include device innovations and the training of researchers in synthesis, fabrication, and spectroscopy.Read moreRead less
Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding ....Exploration of Advanced Nanostructures for Sodium-ion Battery Application. The aim of this project is to develop advanced nanostructured electrode materials for high energy, long service life sodium-ion batteries. Sodium-ion batteries are the most promising choice for large-scale electrical energy storage, in particular for renewable energy sources and smart electric grids, owing to their low cost and natural abundance of sodium. The success of this project will advance fundamental understanding of sodium-ion batteries, and provide techniques for the development of a promising low-cost system for renewable energy storage, which is urgently needed in smart electricity grids. 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