New catalyst could provide liquid hydrogen fuel of the future

Concept of LOHCs under continuous-flow conditions. Credit: Catalysis Science & Technology (2023). DOI: 10.1039/D3CY00881A

Researchers at Lund University in Sweden are investigating a car fuel comprised of a liquid that is converted to hydrogen by a solid catalyst. The used liquid is then emptied from the tank and charged with hydrogen, after which it can be used again in a circular system that is free from greenhouse gas emissions.

Lund researchers have demonstrated that the method works, and while it is still basic research, it has the potential to become an efficient energy-storage system in the future.

“Our catalyst is one of the most efficient around, at least if you look at publicly available research,” says Ola Wendt, professor at the Department of Chemistry at Lund University, and one of the authors.

The findings are published in the journal Catalysis Science & Technology.

Finding alternative ways of producing, storing and transforming energy in order to reduce carbon dioxide emissions from fossil fuels is necessary to reduce the impact on the climate. One way involves much-talked-about hydrogen gas, which many see as a future solution for energy storage. Nature stores energy in chemical bonds, and hydrogen contains the highest energy density in relation to its weight.

“However, gas can be difficult to handle, so we are looking at liquid fuel charged with hydrogen that can be delivered at a pump, in a way broadly similar to what happens at petrol stations today,” says Wendt.

The concept is known as LOHC (liquid organic hydrogen carriers) and is not new as such. The challenge is in finding as efficient a catalyst as possible, that can extract the hydrogen from the liquid.

The system is intended to work using a liquid that is “charged” with hydrogen. The liquid is pumped through a solid catalyst which extracts the hydrogen. This can be used in a fuel cell—which converts chemical fuel to electricity—while the “spent” liquid carries on to another tank. The only emission is water.

The spent liquid can then be emptied at a filling station before refueling with new, charged liquid. This would probably mean large scale production of the substance, comparable to today’s oil refineries.

“We converted more than 99 percent of the hydrogen gas that was present in the liquid,” says Wendt.

Researchers have also been calculating whether it might be possible to use the fuel for larger vehicles such as buses, trucks and aircraft.

“With the large tanks that they have, it might be possible to cover almost the same distance as you can with a tank of diesel. You would also convert around 50 percent more energy compared to compressed hydrogen,” Wendt explains.

The liquids used are isopropanol (which is a common ingredient in screenwash) and 4-methylpiperidine.

Does this sound a little too good to be true? Yes—for now at least, a number of challenges remain. One is that the lifespan of the catalyst is rather limited. Another is that iridium, which the catalyst is based on, is a precious metal.

Wendt cautions, “But we estimate that you need about two grams of iridium per car. This could be compared to today’s exhaust-cleaning catalytic converters, which contain about three grams of platinum, palladium and rhodium, which are also precious metals.”

This is a technical solution based on basic research. If a decision were made to go for a finished product, Wendt believes that the concept could be ready in ten years’ time—provided that it is economically viable and that there is interest from society.

Another problem is how hydrogen is produced—today, most production is not climate-friendly. The hydrogen then must be stored and transported in an effective way, which is not that straightforward today. There are also the risks of refueling with compressed hydrogen. The Lund researchers hope to solve this with their method.

“Ninety-eight percent of all hydrogen today is fossil-based, produced from natural gas. The biproduct is carbon dioxide. From an environmental point of view, the notion of producing hydrogen for steel, batteries and fuel is pointless if it is done using natural gas,” says Wendt, but he explains that there is a lot of research going on into how “green hydrogen” might be produced by splitting water into hydrogen and oxygen with the help of renewable energy.

At the same time, he believes that political decisions are required for renewable and climate-friendly alternatives to gain a proper foothold.

“It needs to be cheaper, and it takes political decisions. Renewables have no chance of competing with something that you just dig out of the ground, where transport is almost the only cost, as is the case with fossil fuels,” he concludes.

More information:
Kaushik Chakrabarti et al, Acceptorless dehydrogenation of 4-methylpiperidine by supported pincer-ligated iridium catalysts in continuous flow, Catalysis Science & Technology (2023). DOI: 10.1039/D3CY00881A

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New catalyst could provide liquid hydrogen fuel of the future (2023, October 12)
retrieved 13 October 2023

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