Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functi ....Advanced all-Iron flow batteries for stationary energy storage. Iron flow batteries are one of the most promising choices for clean, reliable and cost effective long-duration energy storage. The main obstacle for large scale commercial deployment is the low round-trip energy efficiency caused by the competitive side reaction that occurs at the negative electrode during battery charging. The project aims to address this issue by engineering the negative electrode-electrolyte interface with functional materials to improve battery performance and thus further reduce the cost of energy storage. Expected outcomes include new materials and methods for advanced battery technology and manufacturing. The success of the project will significantly support the national priority of net-zero carbon emissions by 2050.Read moreRead less
Silicon-based Anode Materials for Next Generation Lithium-ion Batteries. This project aims to develop low-cost high-performance silicon-based anode materials for next generation high-energy lithium-ion batteries. A cutting-edge in situ reduction and encapsulation technique will be developed to synthesise sub-nanometer silicon nanoparticles homogeneously embedded in graphite matrix. The newly developed silicon-based anode material is expected to deliver high specific capacity and long cycle life. ....Silicon-based Anode Materials for Next Generation Lithium-ion Batteries. This project aims to develop low-cost high-performance silicon-based anode materials for next generation high-energy lithium-ion batteries. A cutting-edge in situ reduction and encapsulation technique will be developed to synthesise sub-nanometer silicon nanoparticles homogeneously embedded in graphite matrix. The newly developed silicon-based anode material is expected to deliver high specific capacity and long cycle life. The novel silicon-based anode materials will boost the energy density of next generation lithium-ion batteries, which will be used to power electric vehicles and renewable energy storage. This project will benefit the industry partner to launch commercial production of silicon-based anode materials for global market. Read moreRead less
Engineering vanadium oxide-based cathode for aqueous ammonium ion batteries. This project aims to develop the next-generation rechargeable aqueous ammonium ion batteries and the scaled-up prototypes. It will be innovatively powered by nonmetallic charge carriers to show superior safety, low cost, high rate and cycle performance, and large capacity, ensuring realistic implementation for industrial purposes. Expected outcomes include a series of chemically and morphologically tuned vanadium oxide- ....Engineering vanadium oxide-based cathode for aqueous ammonium ion batteries. This project aims to develop the next-generation rechargeable aqueous ammonium ion batteries and the scaled-up prototypes. It will be innovatively powered by nonmetallic charge carriers to show superior safety, low cost, high rate and cycle performance, and large capacity, ensuring realistic implementation for industrial purposes. Expected outcomes include a series of chemically and morphologically tuned vanadium oxide-based cathode materials, a novel and reliable working principle based on reversible ammonium ion storage, and battery pack prototypes targeting industry demanded energy density and lifespan. Via industrial pilot trials, commercial benefits will be fast tracked for clean energy storage, net zero future and industry upgrades.Read moreRead less
High performance electrolyte for the vanadium redox flow battery. Vanadium batteries present a highly-scalable, sustainable solution for storage of renewable electricity, but the technology needs to be improved for robust and efficient operation in the warm Australian climate. This project aims to design and extensively test new high-performance electrolyte compositions with advanced thermal stabilising additives for safe long-term battery operation at 60 °C. New knowledge in materials science a ....High performance electrolyte for the vanadium redox flow battery. Vanadium batteries present a highly-scalable, sustainable solution for storage of renewable electricity, but the technology needs to be improved for robust and efficient operation in the warm Australian climate. This project aims to design and extensively test new high-performance electrolyte compositions with advanced thermal stabilising additives for safe long-term battery operation at 60 °C. New knowledge in materials science and electrochemistry will be generated. The core outcome of the project is a sustainable large-scale energy storage technology ready for immediate application in Australia. This will support the transition of the Australian energy sector to renewables and provide businesses with distributed energy storage solutions.Read moreRead less
Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty ....Regeneration of High Value-Added Materials from Spent Lithium-Ion Batteries. This project aims to develop scalable processing techniques for the regeneration of cathode materials and the production of high-purity alumina and graphene from spent lithium-ion batteries. The techniques reduce the cost and time of the processing of degraded cathode materials and increase the value of the spent battery materials (e.g., metallic aluminum and graphite) by converting them into high value-added specialty chemicals. The outcomes and further technology adoptions will extend the capacity of the Partner Organisation for producing specialty battery materials. The outcomes could help Australia’s battery industry switch to a more diversified pathway, which benefits the economic development of Australia in a long term.Read moreRead less