Tiny particles such as ice crystals or ashes tend to oscillate when deposited in the atmosphere. By combining theory and experiments, a Franco-German-Swedish scientific collaboration involving the Physics Laboratory (CNRS/ENS de Lyon) has built a model that can help refine forecasts of the wind transport of atmospheric pollutants and weather forecasts.

Abstract

The orientation of nonspherical particles in the atmosphere, such as volcanic ash and ice crystals, influences their residence times and the radiative properties of the atmosphere. Here, we demonstrate experimentally that the orientation of heavy submillimeter spheroids settling in still air exhibits decaying oscillations, whereas it relaxes monotonically in liquids. Theoretical analysis shows that these oscillations are due to particle inertia, caused by the large particle-fluid mass-density ratio. This effect must be accounted for to model solid particles in the atmosphere.

Reference
Inertia Induces Strong Orientation Fluctuations of Nonspherical Atmospheric Particles. LT. Bhowmick, J. Seesing, K. Gustavsson, J. Guettler, Y. Wang, A. Pumir, B. Mehlig, andG. Bagheri. Physical Review Letters, January 19, 2024.
DOI : 10.1103/PhysRevLett.132.034101
Open archive ArXiv: arXiv:2303.04299