Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and susta ....Interface/Boundary Engineering Towards Better Solid-State Lithium Batteries. This project aims to develop high-performance solid-state lithium batteries by engineering the design of grain boundaries within the oxide electrolyte and interfaces between the electrolyte and both anode and cathode. This project expects to propose a novel cation exsolution strategy for comprehensively engineering the interfaces and boundaries. This project should provide significant benefits on energy safety and sustainable development of Australia. The successful completion of this project can lead to the development of battery technologies that may lift Australia to a better position in the international market and may also help boost the prosperity of Australia’s world-leading lithium mining industry.Read moreRead less
Industry Laureate Fellowships - Grant ID: IL230100039
Funder
Australian Research Council
Funding Amount
$3,516,522.00
Summary
Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a sm ....Aqueous sodium batteries for household and smart-grid electricity storage. This project aims to design and commercialise safe, cost-effective, long-lasting, fast-charging, high energy density aqueous sodium-based batteries to store renewable energy for use in households and smart grids. With a focus on developing and scaling technology and in collaboration with industry partners, the project’s expected outcomes include an enhanced ability to store excess energy and modulate its release into a smart grid during peak demand. Of benefits to Australia, this project will deliver access to reliable, safe and cheap batteries for smart-grid electricity storage in households and a competitive industry manufacturing capability. The downstream benefit is a reduction in energy costs and a contribution to net-zero emissions.
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New carbon nanotube electrocatalysts for water splitting and fuel cells. The demand for clean, secure and sustainable energy sources has stimulated great interest in electrochemical energy storage and conversion technologies such as water splitting and fuel cells. The efficiency of water splitting and fuel cells is however strongly dependent on the activity of the electrocatalysts. The objective of the project is to develop new electrocatalysts based on the recently discovered phenomena that car ....New carbon nanotube electrocatalysts for water splitting and fuel cells. The demand for clean, secure and sustainable energy sources has stimulated great interest in electrochemical energy storage and conversion technologies such as water splitting and fuel cells. The efficiency of water splitting and fuel cells is however strongly dependent on the activity of the electrocatalysts. The objective of the project is to develop new electrocatalysts based on the recently discovered phenomena that carbon nanotubes with specific size and number of walls are very active and significantly promote the reaction of water splitting and fuel cells. The proposed project is expected to open a new research field in the development of new electrocatalysts and photoelectrocatalysts for advanced energy conversion and storage technologies.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
Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all ox ....Oxide-based high temperature proton exchange membrane fuel cells. Proton exchange membrane fuel cells (PEMFCs) are one of the most efficient energy conversion technologies for producing electricity from fuels such as hydrogen and methanol. Current PEMFCs use precious metal catalysts, and the performance of liquid methanol fuel is disappointingly low due to the inability of polymer or hybrid membranes to operate at temperatures above 160-180 degrees centigrade. This work aims to develop an all oxide-based PEMFC technology using a recently developed sintered and heteropolyacid functionalised mesoporous silica membrane. The utilisation of all-oxide-PEMFCs using non-precious metal catalysts is expected to significantly enhance the power density, reduce costs, and enhance the commercial viability of PEMFC technologies.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE140100051
Funder
Australian Research Council
Funding Amount
$320,000.00
Summary
An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X- ....An advanced X-ray facility for surface and in-situ materials characterization. An advanced X-ray facility for surface and in-situ materials characterisation: Materials properties are crucial to the performance of devices and structures, and detailed characterisation at a molecular level is important for optimizing new materials. X-rays are a powerful means of achieving the required level of detail in structural characterisation. The aim of this project is to make available an extremely bright X-ray source with a suite of advanced analytical tools, including surface structural analysis by reflectometry and grazing incidence diffraction and materials structure determination using powder diffraction and microdiffraction at high and low temperatures. The functions of this facility are broad and its applications include materials science, organic electronics, biomaterials and engineering.Read moreRead less
Industrial Transformation Training Centres - Grant ID: IC230100042
Funder
Australian Research Council
Funding Amount
$5,000,000.00
Summary
ARC Training Centre for Battery Recycling. This Training Centre aims to transform Australia’s battery and resource industry by building advanced manufacturing capability for recycling mixed battery materials, promoting 2nd-life re-use, redesigning high performance batteries towards a battery circular economy, and advancing the supporting regulatory landscape. The research will address the challenges associated with battery recycling, deliver industrial demonstrations and promotion policies, and ....ARC Training Centre for Battery Recycling. This Training Centre aims to transform Australia’s battery and resource industry by building advanced manufacturing capability for recycling mixed battery materials, promoting 2nd-life re-use, redesigning high performance batteries towards a battery circular economy, and advancing the supporting regulatory landscape. The research will address the challenges associated with battery recycling, deliver industrial demonstrations and promotion policies, and create a dynamic skilled workforce. Outcomes are expected to shape a distinctive battery recycling model that shifts Australia to zero battery waste to landfill; establish a profitable and self-sustaining onshore industry chain; and help ensure the future of Australia’s energy security.Read moreRead less
Highly ordered and tuneable mesostructured perfluorosulfonic acid polymers as novel proton exchange membranes for fuel cells. The purpose of the project is to develop an innovative perfluorofonic acid based proton exchange membranes (PEM) with ordered and tuneable mesopores and it is expected that PEM fuel cell power systems based on such new PEMs will have significant impact on the advancement of fuel cell technologies and the reduction in greenhouse gas emission.
New mesoporous materials for use in high temperature proton exchange fuel cell membranes. A novel high temperature proton exchange membrane based on heteropolyacid (HPA) functionalised mesoporous silica will be developed. This research into the fundamental materials science of novel proton exchange membranes is expected to impact significantly on the advancement and commercialisation of portable fuel cell devices.
Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the ....Single-atom catalysts for electrochemical carbon dioxide conversion. This project aims to develop a new synthetic technique for the fabrication of template-free and metal single-atoms embedded in doped carbon nano tubes. It will generate fundamental knowledge about multiple proton and electron transfer steps in carbon dioxide (CO2RR) using in-situ synchrotron characterisation techniques. Expected outcomes of the research include the development of new single-atom catalysts for production of the key feed-stock of CO for sustainable use in hydrocarbon fuels, providing significant benefits in the reduction of greenhouse emissions.Read moreRead less