Nickel(III) Oxyhydroxide (NiOOH) as a Positive Electrode Material in Primary Cells. In recent years, the demands put on batteries has increased due to the development of sophisticated portable electronic devices. With the currently available primary battery systems finding it difficult to cope with these demands, there is considerable incentive to develop an improved system with an appropriate capability. This project focuses on nickel(III) oxyhydroxide (NiOOH) as a cathode material. NiOOH is us ....Nickel(III) Oxyhydroxide (NiOOH) as a Positive Electrode Material in Primary Cells. In recent years, the demands put on batteries has increased due to the development of sophisticated portable electronic devices. With the currently available primary battery systems finding it difficult to cope with these demands, there is considerable incentive to develop an improved system with an appropriate capability. This project focuses on nickel(III) oxyhydroxide (NiOOH) as a cathode material. NiOOH is used widely in rechargeable battery systems, where it performs adequately even under severe discharge conditions. However, in primary battery systems, NiOOH suffers from self discharge. This project aims to use the performance capabilities of NiOOH in a primary system, by investigating ways to improve its stability. The benefits for Delta EMD will be protection of their existing business, as well as opening the door to the commercial manufacture of an advanced export material.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.
Hydrogen storage materials for energy conversion applications. For a clean environment, the ideal synthetic fuel is hydrogen because it is lightweight, highly abundant and its oxidation product (water) is environmentally benign. However, the effective storage of hydrogen remains a scientific challenge. This project aims to develop innovative materials with high hydrogen storage capacity and long cycle life, including new composite hydrides, catalysed metal hydrides and various nanotubes. The exp ....Hydrogen storage materials for energy conversion applications. For a clean environment, the ideal synthetic fuel is hydrogen because it is lightweight, highly abundant and its oxidation product (water) is environmentally benign. However, the effective storage of hydrogen remains a scientific challenge. This project aims to develop innovative materials with high hydrogen storage capacity and long cycle life, including new composite hydrides, catalysed metal hydrides and various nanotubes. The expected outcome is the achievement of high reversible hydrogen storage capacity to meet all the demands required for energy conversion applications, in particular, for hydrogen storage/fuel-cell vehicular applications.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
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
Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental ....Molecular Framework Materials: Nanoporosity and Anomalous Thermal Expansion. The design and construction of advanced nanomaterials represents both a key area of fundamental research and a critical step in the push towards smarter and more efficient high-level technologies. Here we explore the strategic assembly of molecular materials that have entirely new and highly useful properties, namely, nanoporosity and anomalous thermal expansion. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in molecular separations and sensing, clean energy storage, electronics and photonics.Read moreRead less
Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. Th ....Advanced Molecular Nanomaterials. The design and construction of advanced nanomaterials is a key step in the push towards smarter and more efficient high-level technologies. Here we mount a major research program into the strategic assembly of molecular nanomaterials that have entirely new and highly useful properties. This innovative work will lead to important fundamental advances in nanoscience and will forge deep understandings of how materials properties relate to nanoscale structure. These advances will spur a wide range of important new technologies, with application of the materials in electronics, photonics, molecular sensing, drug synthesis and purification, clean energy and the controlled release of agrochemicals and pharmaceuticals.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE0989180
Funder
Australian Research Council
Funding Amount
$150,000.00
Summary
Facility for studying the sorption properties of gases by nanostructured materials. The climate debate has put the issues that this research will address at the forefront of community concern. All of the initiatives discussed herein are relevant to alternative energy sources and greenhouse gas reduction. The facility will ensure that the research undertaken will be internationally cutting edge and will hasten the adoption of technologies that will flow from the research, thereby reducing the e ....Facility for studying the sorption properties of gases by nanostructured materials. The climate debate has put the issues that this research will address at the forefront of community concern. All of the initiatives discussed herein are relevant to alternative energy sources and greenhouse gas reduction. The facility will ensure that the research undertaken will be internationally cutting edge and will hasten the adoption of technologies that will flow from the research, thereby reducing the effects of the impending energy crisis and related global pollution issues. The current capability for accurately measuring gas sorption in materials for storage and sequestration is limited in W.A. and the proposed facility will address this situation.Read moreRead less
Lithium/Sulfur rechargeable battery for power applications. The Lithium/Sulphur battery system is very promising for large-scale power applications as it has the highest energy density and lowest cost among various types of rechargeable batteries. However, the degradation of the capacity and short cycle life of Li/S battery have been problematic for commercial development. The aim of this project is to study the mechanisms of capacity fading and to develop effective means such as use of carbon n ....Lithium/Sulfur rechargeable battery for power applications. The Lithium/Sulphur battery system is very promising for large-scale power applications as it has the highest energy density and lowest cost among various types of rechargeable batteries. However, the degradation of the capacity and short cycle life of Li/S battery have been problematic for commercial development. The aim of this project is to study the mechanisms of capacity fading and to develop effective means such as use of carbon nanotubes and nanosize composite absorbents to improve the cycle life of Li/S batteries. The expected outcomes are the development of sulphur-containing cathode materials and polymer electrolytes, enabling electric vehicles to be a technically competitive and environmentally superior transportation option.Read moreRead less
Investigation of Nano-materials for use in Lithium Rechargable Batteries. Lithium ion batteries are emerging as a new generation of rechargeable batteries for power sources of portable electronics. The aim of this project is to explore potential applications of novel nano-materials such as intermetallic alloys, transition-metal oxides, and carbon nanotubes as anode materials in lithium-ion rechargeable batteries. Significance and expected outcomes will be the development of alternative anode ma ....Investigation of Nano-materials for use in Lithium Rechargable Batteries. Lithium ion batteries are emerging as a new generation of rechargeable batteries for power sources of portable electronics. The aim of this project is to explore potential applications of novel nano-materials such as intermetallic alloys, transition-metal oxides, and carbon nanotubes as anode materials in lithium-ion rechargeable batteries. Significance and expected outcomes will be the development of alternative anode materials with improved performance in energy capacity and cycle life over existing anode materials. This could open opportunities for Australian mineral companies to take advantage of the developments to produce value-added new products.Read moreRead less