Physicists observe individual atomic collisions during diffusion for the first time

Almost two hundred years ago, the Scottish doctor and researcher Robert Brown observed that particles of pollen quiver as they move through a liquid. Tiny particles, such as molecules or atoms, exhibit similar behaviour as they disperse within gases and liquids.

Resulting from a huge number of random collisions, the particles show a zigzag pattern of movements causing various substances to mix. Scientists refer to these zigzag movements as “Brownian motion” and to the dispersion and mixing of various substances as diffusion.

“Diffusion is a key phenomenon in many areas of science and forms the basis for numerous transport processes, for example in living cells or energy storage devices,” says Professor Artur Widera, who conducts research into the quantum physics of individual atoms and ultracold quantum gases at TU Kaiserslautern.

“That’s why it’s important to have an understanding of diffusion processes in almost every area of the life sciences, the natural sciences, and technological development.”

An easy, simplified understanding of diffusion can be obtained by disregarding the individual collisions between particles. “In this context, we also talk of a continuous medium with, for example, a larger particle diffusing into it. This simplification becomes all the more accurate as the mass of the particles in the medium becomes smaller and the frequency of collisions becomes higher,” says Dr. Michael Hohmann, who is researcher in Professor Widera’s group and first author of this study. One everyday example is fog, which can also be viewed as a medium of this kind although it actually consists of tiny individual water droplets.

For their experiments, the physicists working under Widera tweaked the conditions that characterise a continuous medium: “Instead of large particles, such as pollen, we studied the diffusion of individual atoms that have almost the same mass as atoms of the gas. Furthermore, we used a very cold, dilute gas in order to drastically reduce the frequency of collisions,” explains Hohmann.

By doing so, the Kaiserslautern-based researchers observed, for the first time, how caesium atoms diffuse at a temperature close to absolute zero in a gas made up of rubidium atoms. “These are temperatures that no refrigerator can reproduce, so we used laser beams to cool the atoms and hold them in place in a vacuum apparatus. This slowed the diffusion down to such an extent that the effect of individual collisions could be observed,” explains Professor Widera with regard to the experimental setup.

For the theoretical description of the experiment, the researchers in Kaiserslautern received assistance from their colleague Professor Eric Lutz, a professor of theoretical physics at the Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), who helped them to develop the mathematical modelling.

“With the new model, we can now describe the atoms’ motions more accurately,” says the Erlangen-based researcher. Together, they showed that it is sufficient to alter the coefficient of friction in the theoretical calculation from the continuous model. By doing so, it is also possible to describe cases that do not involve a continuous medium, as in the above experiment. Examples of such cases include when aerosols – mixtures of suspended particles – disperse in thin layers of air in the upper atmosphere, in interstellar space or in vacuum systems.

The publishers of the journal Physical Review Letters highlight the study as an especially interesting and noteworthy article and have published it as an Editor’s Suggestion: “Individual tracer atoms in an ultracold dilute gas.”
DOI: https://doi.org/10.1103/PhysRevLett.118.263401

The paper is accompanied by a Focus story in the online journal 'Physics': https://physics.aps.org/articles/v10/76

If you have any questions, please contact:
Professor Artur Widera
Tel.: 0631 205-4130
Email: widera(at)physik.uni-kl.de