Inertial angular dynamics of non-spherical atmospheric particles

Cloud-ice crystals, volcanic ash, and microplastic are ubiquitous in the atmosphere. These non-spherical particles are small, but their mass density is much greater than that of air. Little is known about their inertial dynamics, mainly because experiments with such heavy, sub-millimetre particles in air are difficult. We tracked the inertial dynamics of heavy sub-millimetre spheroids through still air and observed that their orientations fluctuate considerably, in stark contrast to the rapid alignment seen in high-density fluids such as water. A model, that quantitatively describes the resulting transient oscillations of the particle orientation, shows that the oscillations are due to particle inertia, and allows us to study the effect of particle shape and volume, beyond the parameters of the experiment. We discuss implications for the angular dynamics of such particles in turbulent air. We conclude that the particle inertia can significantly delay the alignment and increase angular fluctuations. This has significant implications for the statistics of particle orientation, affecting settling velocities and atmospheric residence times, collision/aggregation mechanism and how the particles scatter and absorb solar radiation.