Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100223
Funder
Australian Research Council
Funding Amount
$340,000.00
Summary
Advanced X-ray diffraction facility for high energy and extreme conditions. X-ray powder diffraction is a powerful technique for determining the structure of matter at the atomic scale. This project will establish a new Australian capability for X-ray powder diffraction under extreme conditions that emulate real harsh service environments for advanced functional materials.
Concentrating solar thermal energy storage using metal hydrides. This project will investigate energy storage for concentrating solar thermal energy systems. These systems can be used to efficiently generate electricity in remote locations, day and night, using solar energy. The solar energy is converted to heat energy and then chemical energy stored in a metal-hydrogen compound.
Exploration of highly regenerable boron-nitrogen based hydrides for hydrogen storage. The project will design and synthesise novel boron-nitrogen hydrides. It will employ material design strategies, such as new synthesis techniques, dopant destabilisation, and dehydrogenation catalysts to design and experimentally validate novel multicomponent hydride systems with high storage capacities (above 9 wt% under near-ambient conditions) and high reversibility. The outcomes of this project will make a ....Exploration of highly regenerable boron-nitrogen based hydrides for hydrogen storage. The project will design and synthesise novel boron-nitrogen hydrides. It will employ material design strategies, such as new synthesis techniques, dopant destabilisation, and dehydrogenation catalysts to design and experimentally validate novel multicomponent hydride systems with high storage capacities (above 9 wt% under near-ambient conditions) and high reversibility. The outcomes of this project will make a significant enhancement in the performance of solid state hydrogen storage materials and will deliver a viable storage technology for a range of fuel cell applications.Read moreRead less
Discovery Early Career Researcher Award - Grant ID: DE120101496
Funder
Australian Research Council
Funding Amount
$375,000.00
Summary
Diammoniate of diborane for hydrogen storage. The project will study diammoniate of diborane and its related compounds and systems for hydrogen storage. The research outcome will be extremely beneficial for the fundamental research and potential application of new compounds for hydrogen storage.
Liquid-phase hydrogen carriers for energy storage and delivery. This project aims to overcome hydrogen storage and delivery issues by developing liquid-phase hydrogen storage materials with high hydrogen capacity, exceptional stability and that do not change phase during hydrogen evolution. This project will build on the recent synthesis of strategically important hydrogen storage compounds. The innovative liquid-phase hydrogen storage and delivery technology will enable effective usage of estab ....Liquid-phase hydrogen carriers for energy storage and delivery. This project aims to overcome hydrogen storage and delivery issues by developing liquid-phase hydrogen storage materials with high hydrogen capacity, exceptional stability and that do not change phase during hydrogen evolution. This project will build on the recent synthesis of strategically important hydrogen storage compounds. The innovative liquid-phase hydrogen storage and delivery technology will enable effective usage of established liquid fuel distribution techniques and infrastructure throughout the country. The project would benefit renewable energy, chemical, and manufacturing industries, where new employment opportunities would be created.Read moreRead less
Novel hydrogen-rich liquids for storing and transporting hydrogen at scale. Hydrogen is proposed as the best candidate to store large amounts of energy produced by intermittent sources such as wind and solar. This project aims to address challenges in storing and transporting large amounts of hydrogen in a safe and effective way by developing novel liquid-phase compounds that contain light elements including boron, carbon, nitrogen, and hydrogen. Expected outcomes of this project include new liq ....Novel hydrogen-rich liquids for storing and transporting hydrogen at scale. Hydrogen is proposed as the best candidate to store large amounts of energy produced by intermittent sources such as wind and solar. This project aims to address challenges in storing and transporting large amounts of hydrogen in a safe and effective way by developing novel liquid-phase compounds that contain light elements including boron, carbon, nitrogen, and hydrogen. Expected outcomes of this project include new liquid compounds that can effectively and safely store hydrogen at scale using the exisiting liquid hydrocarbon fuel infrastructure. This should provide significant benefits in the establishment of renewable hydrogen for domestic consumption and more for exporting sustainable and clean fuel using hydrogen as the energy carrier.Read moreRead less
Linkage Infrastructure, Equipment And Facilities - Grant ID: LE120100098
Funder
Australian Research Council
Funding Amount
$230,000.00
Summary
A comprehensive gas/vapour sorption facility for the fast advancement of decarbonised energy technologies. Solutions to clean energy production, storage and use are critical to Australia’s prosperity, yet there is a significant lack of targeted research facilities for the development of the highly needed materials and technologies for powering a sustainable Australia. This facility will bring research efforts closer to practical solutions.
Embrittlement-tolerant alloys for safe hydrogen transmission and storage. Hydrogen embrittlement in steels is a major impediment to a safe hydrogen economy. This project will determine how hydrogen affects the deformation behaviour of steel, providing the fundamental information that is required to develop alloys that can be safely used in infrastructure for a future Australian hydrogen industry. We will utilise new technologies that allow us, for the first time, to determine the position of hyd ....Embrittlement-tolerant alloys for safe hydrogen transmission and storage. Hydrogen embrittlement in steels is a major impediment to a safe hydrogen economy. This project will determine how hydrogen affects the deformation behaviour of steel, providing the fundamental information that is required to develop alloys that can be safely used in infrastructure for a future Australian hydrogen industry. We will utilise new technologies that allow us, for the first time, to determine the position of hydrogen atoms around micro-scale features and to compare it to local mechanical behaviour, determined by micro-mechanical tests. The systematic investigation of the effect of hydrogen on different micro-components within steel will allow the development of microstructure-guided alloy design principles.Read moreRead less
Mitigating hydrogen embrittlement in high-strength steels. Hydrogen wreaks havoc in many alloys, leading to embrittlement that can cause catastrophic failure. This is a very serious issue for any industry in which structures are exposed to hydrogen and is a limiting factor for the production, transport, storage and use of hydrogen in a potential hydrogen economy. However, understanding the behaviour of hydrogen in alloys is restricted by the difficulty of observing it. In this project we will ob ....Mitigating hydrogen embrittlement in high-strength steels. Hydrogen wreaks havoc in many alloys, leading to embrittlement that can cause catastrophic failure. This is a very serious issue for any industry in which structures are exposed to hydrogen and is a limiting factor for the production, transport, storage and use of hydrogen in a potential hydrogen economy. However, understanding the behaviour of hydrogen in alloys is restricted by the difficulty of observing it. In this project we will obtain accurate 3D maps showing the position of hydrogen atoms in steel by combining deuteration with cryogenic atom probe microscopy. In this way we will will elucidate how a proposed solution, hydrogen trapping, reduces hydrogen embrittlement, contributing to design criteria for hydrogen-resistant steels.Read moreRead less
Bulk Mg based hydrogen storage alloys with faster activation. Bulk Mg based hydrogen storage alloys with faster activation. This project aims to improve the performance and efficiency of manufacture of magnesium-based hydrogen storage alloys, making them more cost competitive and widely useable. A hydrogen economy will reduce greenhouse gas emissions and improve air quality in urban areas. The expected outcomes are an understanding of the mechanisms governing the activation process, a necessary ....Bulk Mg based hydrogen storage alloys with faster activation. Bulk Mg based hydrogen storage alloys with faster activation. This project aims to improve the performance and efficiency of manufacture of magnesium-based hydrogen storage alloys, making them more cost competitive and widely useable. A hydrogen economy will reduce greenhouse gas emissions and improve air quality in urban areas. The expected outcomes are an understanding of the mechanisms governing the activation process, a necessary step in manufacture, and techniques to exploit these mechanisms to minimise the activation time. This is expected to develop competitive, bulk magnesium-based hydrogen storage alloys for effective and safe hydrogen storage systems.Read moreRead less