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Fats being released into the atmosphere from cookers such as deep fat fryers may be enhancing the formation of clouds, which have a major cooling effect on the planet.

In a Nature Communications paper published today, scientists demonstrated for the first time that fatty acid molecules emitted during cooking can spontaneously form complex 3-D structures in atmospheric aerosol droplets. The team believes that the formation of these highly ordered structures is likely to extend the atmospheric lifetimes of these molecules and affects how clouds form.

The work is a collaboration between the atmospheric scientist Dr Christian Pfrang and the biophysical chemist Dr Adam Squires. Dr Pfrang, Associate Professor of Physical & Atmospheric Chemistry at the University of Reading, said:

"It is known that fatty acid molecules coating the surface of aerosol particles in the atmosphere may affect the aerosol's ability to seed cloud formation. However, this is the first time scientists have considered what these molecules do inside of the aerosol droplet, and we have shown that they may be assembling into a range of complex, ordered patterns and structures. This means they may last longer in the atmosphere."

"The full impact of the surprisingly complex molecular arrangements of these fatty acid molecules in the environment is hard to quantify at this stage since these structures have not previously been considered by the atmospheric science community: there is no reliable estimate available yet how much organic material shows such complex self-assembly in the atmosphere and further research is urgently needed."

"However, it is likely that these structures have a significant effect on water uptake of droplets in the atmosphere, increase lifetimes of reactive molecules and generally slow down transport inside these droplets with yet unexplored consequences."

Dr Squires, Associate Professor of Biophysics and Materials at the University of Bath, said:

"We know that the complex structures we saw are formed by similar fatty acid molecules like soap in water. There, they dramatically affect whether the mixture is cloudy or transparent, solid or liquid, and how much it absorbs moisture from the atmosphere in a lab. The idea that this may also be happening in the air above our heads is exciting, and raises challenges in understanding what these cooking fats are really doing to the world around us."

The international team also included researchers from Universities of Bristol and Lund, Diamond Light Source and MAX-lab; they studied a model system to represent atmospheric aerosol consisting of individually levitated droplets of mixtures of brine and oleic acid, a fatty acid associated with cooking emissions which contributes approximately 10% to the urban load of fine particulate matter in London.

They observed that the fat molecules assembled into highly ordered "lyotropic" phases – crystal-like lattices of spheres or cylinders which are known to strongly affect water uptake from the surrounding environment, a key process in cloud nucleation, and viscosity, which affects chemical reaction rates. Further experiments showed that the fatty acids were more resistant to chemical attack by ozone, and therefore can survive longer and travel further in the atmosphere, if they adopt these complex structures. The extended lifetimes of these molecules may facilitate droplet growth and thus cloud formation.

Although the behaviour of organic molecules in atmospheric aerosols is subject of high profile current research activity, such lyotropic phases have not until now been considered by the atmospheric community. Given the potential importance of these phases has clearly been demonstrated in the new paper, the team hopes that these results will encourage researchers to explore the actual impact of complex self-assembly in the atmosphere.

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More information: C. Pfrang et al. Complex three-dimensional self-assembly in proxies for atmospheric aerosols, Nature Communications (2017). Journal information: Nature Communications C. Pfrang et al. Complex three-dimensional self-assembly in proxies for atmospheric aerosols,(2017). DOI: 10.1038/s41467-017-01918-1