Special Research Initiatives - Grant ID: SR0354535
Funder
Australian Research Council
Funding Amount
$10,000.00
Summary
Advanced Electromaterials from Nanomaterials and Biomaterials. The proposed initiative brings together relevant sectors of the nanomaterials, biomaterials and electrochemistry research communities. It is envisaged that the collective complementary expertise will give rise to research opportunities and insights into the emerging work of electro-bio-nano. Scientific and technological challenges that exist in this multidiscipline research space include areas as diverse as the development of more ....Advanced Electromaterials from Nanomaterials and Biomaterials. The proposed initiative brings together relevant sectors of the nanomaterials, biomaterials and electrochemistry research communities. It is envisaged that the collective complementary expertise will give rise to research opportunities and insights into the emerging work of electro-bio-nano. Scientific and technological challenges that exist in this multidiscipline research space include areas as diverse as the development of more efficient nerve cell communication implants, understanding and control of biocorrosion/biofouling and the use of biomimicry to produce more efficient catalysts and artificial muscles.Read moreRead less
ARC Centre for Nanostructured Electromaterials. Electromaterials transport electrons or ions and facilitate charge transfer, underpinning most energy capture/storage processes and cell communication. We propose a national Centre to develop nanostructured electromaterials with exceptional properties. The Centre aims to synthesise novel nanomaterials and assemble them into innovative nanoscale devices. We will exploit these materials to enhance performance in energy conversion/storage systems (eg. ....ARC Centre for Nanostructured Electromaterials. Electromaterials transport electrons or ions and facilitate charge transfer, underpinning most energy capture/storage processes and cell communication. We propose a national Centre to develop nanostructured electromaterials with exceptional properties. The Centre aims to synthesise novel nanomaterials and assemble them into innovative nanoscale devices. We will exploit these materials to enhance performance in energy conversion/storage systems (eg. photovoltaics, batteries, including wearable systems), and novel energy transfer in bioapplications (eg. Bionic Ear). These advances, together with the resource of trained personnel, will assist Australian industry to exploit this exciting area.Read moreRead less
Design and Synthesis of Ionic Liquids for Use in Photoelectrochemical Cells Based on Inherently Conducting Polymers. We propose to evaluate the electrochemistry of photoactive polythiophenes recently synthesised by us in a range of ionic liquids. This knowledge will be used to design and synthesise customised ionic liquids with the properties required to enhance the photoelectrochemical efficiency of devices based on substituted polythiophenes. We expect our findings to lead to the development ....Design and Synthesis of Ionic Liquids for Use in Photoelectrochemical Cells Based on Inherently Conducting Polymers. We propose to evaluate the electrochemistry of photoactive polythiophenes recently synthesised by us in a range of ionic liquids. This knowledge will be used to design and synthesise customised ionic liquids with the properties required to enhance the photoelectrochemical efficiency of devices based on substituted polythiophenes. We expect our findings to lead to the development of low-cost, flexible, organic photoelectrochemical cells.Read moreRead less
Development of Nanocrystalline Transition Metal Oxide and Polymer-Transition Metal Oxide Composite Materials for Rechargeable Lithium Battery Applications. Recent work by the applicants has shown that nanocrystalline titanates and aluminates hold considerable promise as lithium battery electrodes. Nanocrystalline anatase materials showed considerably greater lithium intercalation ratios compared with their microcrystalline counterparts, and doping with vanadium showed further improvements in ....Development of Nanocrystalline Transition Metal Oxide and Polymer-Transition Metal Oxide Composite Materials for Rechargeable Lithium Battery Applications. Recent work by the applicants has shown that nanocrystalline titanates and aluminates hold considerable promise as lithium battery electrodes. Nanocrystalline anatase materials showed considerably greater lithium intercalation ratios compared with their microcrystalline counterparts, and doping with vanadium showed further improvements in capacity. Sol-gel synthesised V-doped anatase materials produced an initial discharge capacity of 428 Ah/kg compared with only 280 mAh/kg for the undoped anatase electrode in the same Li test cell.In this project different dopants and preparation conditions will be investigated to produce nanocrystalline rutile and aluminate materials as potential candidates for high capacity lithium battery applications.Read moreRead less
Capacitance Fade Mechanisms in Carbon-Based Supercapacitors. Energy storage is of significant importance to the global community. This project addresses certain performance issues concerning prolonged energy storage in supercapacitors, which are an emerging technology in the electronics industry. CAP-XX is Australia's only manufacturer of supercapacitors, and the improvements to their products that will result from this work, will lead to significant returns to them and the Australian economy.
ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas ....ARC Centre of Excellence - Australian Centre for Electromaterials Science. The Centre will tackle some of the biggest challenges facing society: those of renewable energy, sustainable industries and enhancing human health. Improvements in all these areas are possible by developing electromaterials with improved efficiency in the generation and transfer of electrical charge. By developing new nano-materials and new theories to explain their behaviour, the Centre will make advances in the areas of human health through the regeneration of damaged nerves (eg. in spinal injury) and development of artificial muscles; in renewable energy (plastic solar cells, lightweight batteries and electronic textiles) and in sustainable industries (recovery of precious metals and new corrosion protection technologies).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.
Discovery Early Career Researcher Award - Grant ID: DE160100596
Funder
Australian Research Council
Funding Amount
$372,000.00
Summary
Lithium-Ion Conducting Sulfide Cathodes for All-Solid-State Li–S Batteries. The aim of the project is to develop lithium-ion conducting sulphide cathode materials for high-performance all-solid-state lithium-sulphur (Li–S) batteries. Substituting solid-state electrolyte for liquid electrolyte is the most efficient approach to eliminate the polysulfide shuttle effect, which is the biggest obstacle for the practical application of Li–S batteries based on liquid electrolytes. The project aims to de ....Lithium-Ion Conducting Sulfide Cathodes for All-Solid-State Li–S Batteries. The aim of the project is to develop lithium-ion conducting sulphide cathode materials for high-performance all-solid-state lithium-sulphur (Li–S) batteries. Substituting solid-state electrolyte for liquid electrolyte is the most efficient approach to eliminate the polysulfide shuttle effect, which is the biggest obstacle for the practical application of Li–S batteries based on liquid electrolytes. The project aims to develop novel Li2S-rich cathode materials with high lithium-ion conductivity, which will form the basis of all-solid-state Li–S batteries with high energy density. The new battery is expected to have wide applications in portable electronic devices, electric vehicles and grid-scale renewable energy storage.Read moreRead less
Designing Nano-Pore Architectures for High Power Battery Materials. In recent years there has been a steady increase in the popularity of portable electronic devices. Of the numerous battery systems available, alkaline MnO2/Zn cells are most commonly used to power these devices. However, as the device power requirements increase, so too does the demand on these cells to perform. Delta EMD, Australia, currently exports ~10% of the world's supply of MnO2 for these cells. Their collaboration with p ....Designing Nano-Pore Architectures for High Power Battery Materials. In recent years there has been a steady increase in the popularity of portable electronic devices. Of the numerous battery systems available, alkaline MnO2/Zn cells are most commonly used to power these devices. However, as the device power requirements increase, so too does the demand on these cells to perform. Delta EMD, Australia, currently exports ~10% of the world's supply of MnO2 for these cells. Their collaboration with personnel from the University of Newcastle, who have significant expertise in the field of MnO2 research, will focus on designing a superior MnO2 with optimized nano-pore architecture for high power battery applications.Read moreRead less
Bioinspired tuneable catalysts for renewable ammonia production. The project will design a new solar-powered system for electrosynthesis of ammonia to replace the current energy intensive, non-sustainable process that generates 1.5% of global CO2 emissions. An innovative new system will be developed by combining cutting edge electrochemical, spectroscopic and theoretical methods. Expected key outcomes include novel concepts in the design of advanced materials, and an efficient process for the gr ....Bioinspired tuneable catalysts for renewable ammonia production. The project will design a new solar-powered system for electrosynthesis of ammonia to replace the current energy intensive, non-sustainable process that generates 1.5% of global CO2 emissions. An innovative new system will be developed by combining cutting edge electrochemical, spectroscopic and theoretical methods. Expected key outcomes include novel concepts in the design of advanced materials, and an efficient process for the green ammonia synthesis. Given the strategic importance of ammonia as a future energy carrier for the export of Australian renewables and as a major source of fertilisers, this project should provide significant national economic and ecological benefits and is expected to have a broad reaching global impact.Read moreRead less