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
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
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
Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a rema ....Scalable high-density hydrogen storage by nano-bubbles in layered materials. Stable and low-cost hydrogen storage and transportation are cornerstones of a global hydrogen economy. This project aims to advance a novel hydrogen storage technology based on highly pressurised nano-bubbles in layered materials. The project expects to expand our fundamental knowledge of the interactions between hydrogen and layered materials. Expected outcomes include a hydrogen storage technology that exhibits a remarkable energy density, high stability and low cost. This should provide significant benefits, such as improving the capacity and robustness of low-cost hydrogen storage and transportation, reducing energy costs and making hydrogen energy a more accessible and sustainable clean energy source for Australia.Read moreRead less
Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of sol ....Solid-state lithium batteries using phase-stabilised electrolytes. This project aims to develop advanced lithium batteries using multifunctional phase-stabilised solid-state electrolytes. Solid-state lithium batteries are the ultimate end goal of the battery industry, owing to their unique features including no fire hazard, high energy and power densities, and long service lifespan. By combining nanofabrication and novel electrolyte materials, the project expects to boost the performances of solid-state lithium batteries, establishing them as an advanced energy technology to meet future energy storage and conversion needs. The newly developed battery technology will be widely used for portable electronics, electric vehicles and smart electricity grids that integrate renewable energy sources.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
Low-temperature ceramic electrolysis cells for renewable energy technology. This project aims to develop advanced protonic ceramic electrolysis cells for greatly improving the efficiency of hydrogen production and carbon dioxide conversion using renewable energy. This will be achieved by nanoscale integration of proton-conducting two-dimensional materials with solid acids and ceramic proton conductors to lower the manufacturing costs and operating temperature of protonic ceramic electrolysis cel ....Low-temperature ceramic electrolysis cells for renewable energy technology. This project aims to develop advanced protonic ceramic electrolysis cells for greatly improving the efficiency of hydrogen production and carbon dioxide conversion using renewable energy. This will be achieved by nanoscale integration of proton-conducting two-dimensional materials with solid acids and ceramic proton conductors to lower the manufacturing costs and operating temperature of protonic ceramic electrolysis cells. Expected outcomes of the project include new intellectual property on materials formulation and process parameters for commercial development of this new type of ceramic electrolysis cell, thereby contributing to the growth of Australian manufacturing and renewable energy industries and reduction of carbon emissions.Read moreRead less
Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion ....Solid Oxide Electrolysis Cells with Novel Perovskite-based Cathode. The electrochemical reduction of CO2 and steam to value-added fuels in a high-temperature solid oxide electrolysis cell (SOEC) is practically promising, but technologically challenging. This project aims to develop next generation SOECs using a perovskite-based cathode and scale-up engineering for rapid, bulk production of H2, CO and syngas fuels. Expected outcomes include material engineering, new knowledge on energy conversion technology, and advanced manufacturing technologies. The success of the project will provide a practical solution to reduce fossil CO2 emissions and potential technology for hydrogen production. These will significantly aid Australia in important climate goals and ambitions.Read moreRead less
Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale pr ....Rechargeable lithium carbon dioxide battery - catalyst design to prototype . This project aims to develop a new concept of rechargeable lithium carbon dioxide batteries and scaled-up prototypes. Such a battery will be first of its kind to show high power comparable to gasoline and superior rechargeability over existing gas-involved batteries, ensuring realistic use for industrial purposes. Expected outcomes include 2-dimensional catalysts made from earth-abundant elements lowering large-scale production cost, a novel but reliable working principle based on reversible carbon dioxide/oxalate conversion, and prototypes featuring high specific capacity, large energy density and excellent durability. Via industrial pilot trials, commercial benefits will be fast tracked for energy security and carbon dioxide utilisation.Read moreRead less
Nanotechnology enabled electrochemical energy storage materials from indigenous natural graphite. This project aims to develop a technology package for reclamation of fine-fractions of indigenous natural graphite to create high-value, nano-engineered 'graphene-based' energy storage materials. A multidisciplinary team of experts in materials science, chemical engineering, physics and electrochemistry will address this issue of national priority.