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Solid Air Hydrogen Liquefaction Suggested as Efficient Supplement to Hydrogen Liquefaction Supply Chain, according to recent IIASA Research

One of the challenges of constructing a global hydrogen economy is hydrogen transportation by sea. A new approach developed by researchers from the International Institute for Applied Systems Analysis (IIASA) in Austria and international colleagues proposes using solid air (nitrogen or oxygen) as a medium for recycling cooling energy across the hydrogen liquefaction supply chain.

An open-access paper on the work is published in the International Journal of Hydrogen Energy.

The world is undergoing an energy transition to reduce CO2 emissions and mitigate climate change. The COVID-19 pandemic and the Russia-Ukraine war have further increased the interest of Europe and Western countries to invest in the hydrogen economy as an alternative to fossil fuels. Hydrogen can significantly reduce geopolitical risks if the diversity of future hydrogen energy suppliers is increased.

However, hydrogen is a particularly challenging product to transport safely. One option is to liquefy hydrogen, which requires cooling to 20 Kelvin (-253 °C). This is an expensive process and requires around 30% of the energy stored within the hydrogen.

At standard temperature and pressure, air is a gas, but under certain conditions, it can become a liquid or solid. Solid Air Hydrogen Liquefaction (SAHL) consists of storing the cooling energy from the regasification of hydrogen, by solidifying air, and transporting the solid air back to where the hydrogen was liquefied. The solid air is then used to reduce the energy consumption for liquefying hydrogen.

The process is divided into four main steps: hydrogen regasification, solid air transportation, hydrogen liquefaction, and liquid hydrogen transportation.

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The Solid Air Hydrogen Liquefaction process © Hunt et al. (2023)


Another advantage of solidifying air for energy recovery in the hydrogen liquefaction supply chain is the extra production of oxygen. The oxygen could be used to increase the efficiency of power generation with oxy-combustion and to facilitate the capture, use, and storage of carbon (CCUS).

Using solid air as a medium for recycling cooling energy across the hydrogen liquefaction supply chain can reduce the cost and energy consumption for transporting hydrogen between continents. This would increase the viability of a global hydrogen economy in the future and increase the number of hydrogen suppliers for energy-demanding regions, such as China, Europe, and Japan. The possibility of selling hydrogen could result in a further expansion of solar and wind power in developing countries, contributing to their economies.

—lead author Julian Hunt, a researcher in the Integrated Assessment and Climate Change Research Group of the IIASA Energy, Climate, and Environment Program

In their paper, the authors also address the ongoing debate in industry and academia to find the best alternative to transport hydrogen by sea.

Compared to ammonia or methanol, liquefied hydrogen is the best option for several reasons. Transporting hydrogen with ammonia and other molecules would require around 30% of the energy transported to extract the hydrogen. The hydrogen is liquefied where electricity is cheap. Also, SAHL can lower energy consumption for hydrogen liquefaction by 25 to 50%.

—Julian Hunt

Resources

  • Hunt, J., Montanari, P., Hummes D., Taghavi M., Zakeri, B., Romero, O., Zhou, W., Castro, J., Schneider, P., Wada, Y. (2023). “Solid air hydrogen liquefaction, the missing link of the hydrogen economy.” International Journal of Hydrogen Energy doi: 10.1016/j.ijhydene.2023.03.405

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2 COMMENTS

  1. I think that the solid air hydrogen liquefaction process is a really interesting way to recycle energy and I think it has a lot of potential to reduce the cost and energy consumption of transporting hydrogen. I think it would be great if this process could be used to increase the number of hydrogen suppliers for energy-demanding regions.

  2. I think that this is a really interesting idea and could definitely work to help with the transportation of hydrogen. I like that it would also create oxygen as a byproduct, which could be used in many different ways. I’m curious to see if this idea is explored further and if it is eventually implemented on a larger scale.

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