Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artifi ....Multifunctional 2D materials for sustainable energy applications. This project seeks to explore the great potential of novel graphene-like two dimensional (2-D) materials for energy applications. 2-D materials, which possess atomic or molecular thickness and infinite planar lengths, are regarded as a building block for many applications due to their unique nanostructures, electronic and mechanical properties. This project is focused on the design and exploration of layered two-dimensional artificial graphene and graphene analogues with ‘on-demand’ properties to exploit advanced energy applications. There is now a pressing need to integrate graphene sheets into multidimensional and multifunctional systems with spatially well-defined configurations, and integrated systems with a controllable structure and predictable performance. Project outcomes may lead to next-generation devices in energy storage and other applications.Read moreRead less
Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation batte ....Development of the next generation battery storage system for smart grid. Development of the next generation battery storage system for smart grid. This project aims to significantly improve the energy density, safety and robust storage performance of lithium batteries with reduced cost, by developing a next-generation battery with lithium-rich layered oxide cathodes and titanium oxide-based and silicon-based anodes. Intelligent features will make the whole energy network a next-generation battery storage system, with mechanisms to protect the battery from hazardous and inefficient operating conditions. This lithium ion battery storage system is expected to create opportunities for businesses that harvest renewable energy and make existing industries more environmentally benign.Read moreRead less
New high performance zinc bromine batteries with novel electrode/electrolyte systems. Renewable sources of energy are of particular interest in the era of diminishing fossil fuels. Efficient energy storage is a missing link for renewable energy. Zinc-bromine batteries have great potential as energy storage. This project will aim to fundamentally re-design the existing first generation systems to improve power density by 300-400 per cent.
Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a pl ....Efficient ionic liquid-based reduction of nitrogen to ammonia. This project aims to develop a hybrid ionic liquid-nanostructured electrode platform to electrochemically convert nitrogen gas to ammonia. Ammonia production, mostly for fertilisers, consumes more than 1% of the global energy supply and contributes 1.6 % of global carbon dioxide emissions. A process that could convert nitrogen to ammonia using renewable energy would be an important alternative approach. This project will develop a platform for electrochemical conversion of nitrogen gas to ammonia and optimise it for use with surplus renewable energy supplies. The project is expected to contribute to mitigation of greenhouse emissions and create a technology for distributed production of ammonia and ammonium fertilisers.Read moreRead less
New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This ....New dielectric materials: Improving storage density of high temperature multilayer ceramic capacitors to sustainably meet future energy demands. Electrical energy generation from renewable sources, such as solar, wind and geothermal, provide enormous potential for meeting future energy demands. However, the ability to store and control this energy for miniaturisation and modularisation in applications requiring a wide temperature usage range is a limiting factor that needs to be addressed. This project aims to develop new bismuth-based lead-free dielectric materials for improving the storage density of high temperature multilayer ceramic capacitors for sustainable applications in the energy and vehicle industries, where high temperature stability and high volumetric efficiency are crucial.Read moreRead less
New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve ....New high energy density cathode materials for lithium ion batteries. This project aims to develop new high-energy-density and low-cost lithium-rich cathode materials for advanced lithium-ion batteries that can store solar energy for Australian households and power the next generation electric vehicles. The project will design innovative strategies to suppress the voltage decay and capacity decline of the lithium rich materials over long-term cycling. The project expects to significantly improve battery performance at a lower price and make a substantial impact to the energy supply technologies and industries in Australia and benefit the environment in the long run.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE220100656
Funder
Australian Research Council
Funding Amount
$406,742.00
Summary
Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will ....Aqueous-based potassium ion batteries for scalable energy storage. The aim of this project is to develop aqueous-based potassium ion batteries for new energy storage applications that currently have barely been studied. This project will design novel cathode/anode materials and electrolytes to significantly advance knowledge in this new technology. The expected outcomes include high-performance aqueous-based potassium ion batteries, while new fundamental knowledge of the reaction mechanisms will enhance our research capabilities to position Australia as a leader in potassium ion storage.Read moreRead less
Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a ....Recyclable and Rechargeable All-Solid-State Sodium Ion Batteries. This project aims to design a new generation recyclable and rechargeable all-solid-state sodium ion battery. We will use low cost and abundant sodium as a substitute for expensive and limited lithium to reduce material and environmental costs, and will develop ceramic/polymer composites as safe and environmentally friendly solid-state electrolytes to replace flammable and toxic organic liquid electrolytes. Furthermore, we design a recyclable battery configuration to allow rapid, low cost and green recycling of end-of-life batteries. The new battery will be a safe, low cost and sustainable energy storage technology for the multi-billion dollar electric vehicle and smart grid markets while simultaneously addressing battery recycling issues.Read moreRead less
Novel Ionic Composites with superior transport and mechanical properties for Clean Energy Systems. Electroactive materials are key components of technologies desperately needed to allow the efficient production of energy from sustainable sources. Of equal importance, large amounts of this energy needs to be stored in safe, stable devices that also allow high rates of energy storage and release. This project addresses these requirements using both fundamental and applied aspects of electromateria ....Novel Ionic Composites with superior transport and mechanical properties for Clean Energy Systems. Electroactive materials are key components of technologies desperately needed to allow the efficient production of energy from sustainable sources. Of equal importance, large amounts of this energy needs to be stored in safe, stable devices that also allow high rates of energy storage and release. This project addresses these requirements using both fundamental and applied aspects of electromaterials science and electrochemistry. This project will design and characterise novel solid state electrolyte membranes composed of plastic crystals and polymer nanofibres. These materials will have enhanced physical and chemical properties, yielding advanced thin film membranes for application in a range of energy production and storage technologies.Read moreRead less
Functional carbon composites to power a sustainable future. This project aims to address the limitation of current energy storage technologies though the development of functional carbon-based materials for the next generation of energy storage systems with high capacity, high energy/power density, excellent retention and low cost. The progress of energy storage technology plays a critical role in the development of portable devices in daily life. This project will synthesise a series of carbon- ....Functional carbon composites to power a sustainable future. This project aims to address the limitation of current energy storage technologies though the development of functional carbon-based materials for the next generation of energy storage systems with high capacity, high energy/power density, excellent retention and low cost. The progress of energy storage technology plays a critical role in the development of portable devices in daily life. This project will synthesise a series of carbon-based composites via an electrospinning method, and their properties will be assessed and characterised as electrode materials for high performance energy storage devices.Read moreRead less