Discovery Early Career Researcher Award - Grant ID: DE240100863
Funder
Australian Research Council
Funding Amount
$460,847.00
Summary
High-Efficiency, Modular and Low-Cost Hydrogen Liquefaction and Storage . Australia’s first modular hydrogen liquefaction and storage. This project aims to develop a novel multi-faceted cooling system and software to increase efficiency, lower cost, and improve the safety of hydrogen liquefaction and storage. The project will establish a new multi-disciplinary research capability in Australia and expand our fundamental knowledge to model, design, and build modular liquefaction and zero-boil-off ....High-Efficiency, Modular and Low-Cost Hydrogen Liquefaction and Storage . Australia’s first modular hydrogen liquefaction and storage. This project aims to develop a novel multi-faceted cooling system and software to increase efficiency, lower cost, and improve the safety of hydrogen liquefaction and storage. The project will establish a new multi-disciplinary research capability in Australia and expand our fundamental knowledge to model, design, and build modular liquefaction and zero-boil-off storage systems, allowing widespread distribution and usage of hydrogen. It will create a paradigm shift from traditional scale-up to modern number-up approaches. This level of innovation is crucial for Australia to lead the world in hydrogen and also enable accessible and sustainable clean energy sources for Australians.Read moreRead less
A New Spin on Liquid Hydrogen: Controlled Cold Energy. While hydrogen is set to play a leading role in global decarbonisation, significant challenges remain regarding methods for its reliable storage and transportation. Hydrogen liquefaction has emerged as a promising approach in this regard due to its high energy density and hydrogen purity, but is currently prohibitively expensive. In this project we will exploit the peculiar spin physics of hydrogen to alleviate liquefactions costs through t ....A New Spin on Liquid Hydrogen: Controlled Cold Energy. While hydrogen is set to play a leading role in global decarbonisation, significant challenges remain regarding methods for its reliable storage and transportation. Hydrogen liquefaction has emerged as a promising approach in this regard due to its high energy density and hydrogen purity, but is currently prohibitively expensive. In this project we will exploit the peculiar spin physics of hydrogen to alleviate liquefactions costs through the provision of controllable refrigeration (so-called 'cold energy') following regasification. In particular we will measure, optimise and exploit the highly endothermic catalysed conversion of para- to ortho- hydrogen, which can provide up to 525 kJ/kg of cooling at convenient temperatures. Read moreRead less