Development of inorganic-conducting polymer composites and ionic liquid-based electrolytes for rechargeable lithium batteries. The project will lead to development of safe lithium batteries for electric vehicles and hybrid electric vehicles to contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. Small, flexible batteries for new implantable medical devices will also be developed to treat millions of people suffering from different ....Development of inorganic-conducting polymer composites and ionic liquid-based electrolytes for rechargeable lithium batteries. The project will lead to development of safe lithium batteries for electric vehicles and hybrid electric vehicles to contribute to the national priority goal of reducing and capturing emissions in transport to improve our environment. Small, flexible batteries for new implantable medical devices will also be developed to treat millions of people suffering from different diseases. The development of new scientific knowledge related to this project will place Australia at the forefront of an emerging domain of research. The project will take the incentive in establishing a leading national position in development of new energy storage technology.
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Graphene - the new frontier electromaterial for rechargeable lithium batteries and supercapacitors. Global warming and climate change have triggered an intensive demand for clean energy sources to replace fossil fuels. Graphene, as an emerging novel material, can serve as a medium for highly efficient energy storage and conversion in electrochemical devices. This project will lead to the development of novel renewable energy storage and conversion technology for transportation and distributed en ....Graphene - the new frontier electromaterial for rechargeable lithium batteries and supercapacitors. Global warming and climate change have triggered an intensive demand for clean energy sources to replace fossil fuels. Graphene, as an emerging novel material, can serve as a medium for highly efficient energy storage and conversion in electrochemical devices. This project will lead to the development of novel renewable energy storage and conversion technology for transportation and distributed energy supplies. The outcomes of this research will increase our national energy security, facilitate achievement of the Federal government's target of 20% renewable energy in 2020, and bring significant economic and environmental benefits for Australia.Read moreRead less
Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent wor ....Ionic Liquids and Solids - New Designs, Insights and Applications. Ionic Materials in the form of liquid salts and plastic crystals are of interest in a wide range of applications including environmentally benign synthesis of chemicals and high stability electrolytes for batteries, capacitors and other devices. These materials represent some of the most stable chemicals known, making them attractive for any application where complete stability and recycling are issues. Building on our recent work, this project will design, prepare and characterize novel materials of this type for a number of target applications. Collaborators in Europe and USA will be involved in the analysis and testing of the materials.Read moreRead less
Mapping new cathode materials for aqueous rechargeable batteries: The mechanism of intercalation of lithium in aqueous solutions. This technology could power electric vehicles of the future. With the aid of using advanced oxide and phosphate materials for an aqueous battery, the project will establish a widespread use of green energy for national benefit. This will help us to reduce the current emission observed in transport and energy conversion. The project will facilitate an understanding the ....Mapping new cathode materials for aqueous rechargeable batteries: The mechanism of intercalation of lithium in aqueous solutions. This technology could power electric vehicles of the future. With the aid of using advanced oxide and phosphate materials for an aqueous battery, the project will establish a widespread use of green energy for national benefit. This will help us to reduce the current emission observed in transport and energy conversion. The project will facilitate an understanding the electrochemical energy storage technology. The challenging and significant results from this project will contribute to the energy industries to build non-pollutant high energy storage equipments and productivity of Australia's research and development.Read moreRead less
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
New directions to miniaturized power sources: Integrated all-solid-state rechargeable batteries. This project will lead to the development of safe integrated all-solid-state miniaturized lithium ion batteries for small autonomous devices, such as implantable medical devices, hearing aids, small autonomous devices with sensing and actuation, and for communications and rapid chemical/biological analysis. This will make a significant contribution to the nation in the areas of science, technology, h ....New directions to miniaturized power sources: Integrated all-solid-state rechargeable batteries. This project will lead to the development of safe integrated all-solid-state miniaturized lithium ion batteries for small autonomous devices, such as implantable medical devices, hearing aids, small autonomous devices with sensing and actuation, and for communications and rapid chemical/biological analysis. This will make a significant contribution to the nation in the areas of science, technology, health, and the economy. The development of new scientific knowledge related to this project will place Australia at the forefront of an emerging domain of research. The project will also provide excellent training for postgraduate students and young researchers to develop their skills in chemistry, materials science, and battery technology.Read moreRead less
Novel Graphitic Mesoporous Carbon Materials for Next Generation Carbon Catalyst Supports and Carbon Electrodes. This project will bring about direct application benefits in terms of disclosing novel graphitic mesoporous carbons with high accessible surface area and graphitic framework as catalyst supports and electrode materials. This would lead to advanced processes important to the Australian energy and environmental industries, such as electrical double layer capacitors, greenhouse reduction ....Novel Graphitic Mesoporous Carbon Materials for Next Generation Carbon Catalyst Supports and Carbon Electrodes. This project will bring about direct application benefits in terms of disclosing novel graphitic mesoporous carbons with high accessible surface area and graphitic framework as catalyst supports and electrode materials. This would lead to advanced processes important to the Australian energy and environmental industries, such as electrical double layer capacitors, greenhouse reduction by hydrogen fuel, and hydrodesulfurization of diesel fuels. The techniques and synthesis strategies developed in this project are also applicable to creating other graphitic mesoporsous carbons important to advanced sensors, fuel cells and optoelectronic applications. Read moreRead less
Interphase Engineering of Reactive Metal Surfaces Using Ionic Liquids. Corrosion is a multi-billion dollar problem for all developed countries which limits the use of a number of advanced, light weight alloys in applications ranging from aircraft components to artificial hip-joints. The outcomes of this project will be surface treatments which will enable a range of these applications including magnesium alloys in a wider range of engineering uses, magnesium for advanced metal batteries and coat ....Interphase Engineering of Reactive Metal Surfaces Using Ionic Liquids. Corrosion is a multi-billion dollar problem for all developed countries which limits the use of a number of advanced, light weight alloys in applications ranging from aircraft components to artificial hip-joints. The outcomes of this project will be surface treatments which will enable a range of these applications including magnesium alloys in a wider range of engineering uses, magnesium for advanced metal batteries and coatings for medical implant applications. Many of these applications will make a significant contribution to reducing our greenhouse gas emissions.Read moreRead less
Protic Ionic Liquids: Design, Creation, Characterisation and Application. The project activities fall within National Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries. To remain internationally competitive in the future many Australian manufacturing enterprises will need to make significant advancements in the design and processing of products at multiple length scales, including at molecular and atomic levels. The plan is to translate this projec ....Protic Ionic Liquids: Design, Creation, Characterisation and Application. The project activities fall within National Research Priority 3: Frontier Technologies for Building and Transforming Australian Industries. To remain internationally competitive in the future many Australian manufacturing enterprises will need to make significant advancements in the design and processing of products at multiple length scales, including at molecular and atomic levels. The plan is to translate this project's anticipated cutting edge research results into new high technology products that can be manufactured in Australia. Australian post-graduate students and post-doctoral fellows will be trained in the design, creation, characterisation and application of advanced materials.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