Aviation fuel directly from carbon dioxide, water and sunlight

In the quest for fossil-free fuels for aircraft, a new study shows that isoprene could be part of a future solution. Isoprene can be produced by blue-green algae from sunlight, water and ordinary carbon dioxide. The productivity of the cyanobacteria increases if they are exposed to violet light or higher temperatures, and isoprene is ideally suited for photochemical processing into aviation fuels.

These are the findings of two separate studies from the Department of Chemistry – Ångström Laboratory at Uppsala University, which are now being published in Photochemical and Photobiological Sciences, and Bioresource Technology.

“Our study shows that isoprene is actually an ideal hydrocarbon, and that the photochemical reaction can be optimised under conditions that are also suitable for photobiological isoprene production,” says Henrik Ottosson, Associate Professor of Physical Organic Chemistry and principal author of one of the studies.

Sustainable aviation fuels (SAFs) have an important part to play in developing fossil-free aviation fuels and by extension reducing carbon dioxide emissions from aviation. Although electric aviation could provide another solution, particularly for short flights, batteries still do not deliver enough energy for longer flights. One emerging way to create sustainable aviation fuels could be solar-driven production of hydrocarbons by photosynthetic microorganisms.

Two research groups at Uppsala University, led by Henrik Ottosson and Pia Lindberg respectively, have studied a combined photobiological-photochemical method for producing synthetic sustainable aviation fuel. In their research, they have used genetically modified photosynthetic microorganisms, cyanobacteria, that have been genetically engineered to include a new enzyme from the Eucalyptus tree. This enzyme enables the cyanobacteria to manufacture the hydrocarbon isoprene, using solar energy and carbon dioxide from the air.

In a previous study, published in November 2022, the same researchers reported that isoprene from cyanobacteria can be dimerised photochemically into larger hydrocarbons that, following hydrogenation, are very similar to existing aviation fuels. The method has great potential usability, as it employs sunlight as the energy source for both processes. One question, however, is whether isoprene itself is the best starting material for the photochemical reaction.

To find out whether isoprene or some other hydrocarbon is the most suitable for producing sustainable aviation fuel, Henrik Ottosson’s research group has studied an extended set of small hydrocarbons, several of which can be produced by biotechnological means. The results of the study show that the molecular structure of a hydrocarbon affects the efficiency with which it undergoes the photochemical reaction.

Although isoprene can demonstrably be produced by cyanobacteria, the overall yield is still very low. Pia Lindberg’s research group, in collaboration with Global Change Research Institute in Brno, Czech Republic, and others, has therefore carried out a study to investigate cultivation conditions that may influence productivity.

“We can show that both violet light and higher temperatures can increase the productivity of the cyanobacteria. Another finding is that isoprene increases the heat tolerance of cyanobacteria, enabling them to survive at higher temperatures than they normally would, which could be an advantage for large-scale production using sunlight,” says Lindberg, Associate Professor of Microbial Chemistry and author of the other study.

The results from the photobiological and photochemical processes improve the prospects of replacing fossil fuels in aviation. The technology will need further development to make it possible to realise the final goal of establishing an industrial process by 2040.

References:

Vajravel, S., Gomes, L. C., Rana, A., & Ottosson, H. (2023). Towards combined photobiological-photochemical formation of kerosene-type biofuels: Which small 1, 3-diene photodimerizes most efficiently? Photochemical and Photobiological Sciences, https://link.springer.com/article/10.1007/s43630-023-00418-0

Rodrigues, J.S., Kovács, L., Lukeš, M., Hoeper, R., Steuer, R., Červený, J., Lindberg, P. and Zavřel, T. (2023). Characterizing isoprene production in cyanobacteria – insights into the effects of light, temperature, and isoprene on Synechocystis sp. PCC 6803. Bioresource Technology 129068, https://doi.org/10.1016/j.biortech.2023.129068.

Rana, A., Gomes, L. C., Rodrigues, J. S., Yacout, D. M., Arrou-Vignod, H., Sjölander, J., Vedin, N.P., El Bakouri, O., Stensjö, K., Lindblad, P., Andersson, L., Sundberg, C., Berglund, M., Lindberg, P., Ottosson, H. (2022). A combined photobiological–photochemical route to C10 cycloalkane jet fuels from carbon dioxide via isoprene. Green Chemistry, 24 (24) 9602-9619. https://pubs.rsc.org/en/content/articlelanding/2022/gc/d2gc03272d

For further information:

Pia Lindberg, Associate Professor, Department of Chemistry – Ångström Laboratory, Uppsala University, email: pia.lindberg@kemi.uu.se, telephone: 018-471 6587

Henrik Ottosson, Associate Professor, Department of Chemistry – Ångström Laboratory, Uppsala University, email: henrik.ottosson@kemi.uu.se, telephone: 070-477 63 33

Sindhujaa Vajravel, Postdoctoral Researcher, Department of Chemistry – Ångström Laboratory, Uppsala University, email: sindhujaa.vajravel@kemi.uu.se