Settling and Clustering of Snow Particles in Atmospheric Turbulence

TL;DR

This study demonstrates that atmospheric turbulence significantly influences snow particle settling and clustering, revealing mechanisms like preferential sweeping and particle clustering that improve understanding of snow precipitation dynamics.

Contribution

It provides the first observational evidence of clustering in natural snow flows and links turbulence-driven mechanisms to snow settling behavior, enhancing predictive models.

Findings

Turbulence affects snow fall speed and distribution.

Clustering of snow particles exhibits power-law size distribution.

Preferential sweeping explains enhanced settling and clustering.

Abstract

The effect of turbulence on snow precipitation is not incorporated into present weather forecasting models. Here we show evidence that turbulence is in fact a key influence on both fall speed and spatial distribution of settling snow. We consider three snowfall events under vastly different levels of atmospheric turbulence. We characterize the size and morphology of the snow particles, and we simultaneously image their velocity, acceleration, and relative concentration over vertical planes about 30 m2 in area. We find that turbulence-driven settling enhancement explains otherwise contradictory trends between the particle size and velocity. The estimates of the Stokes number and the correlation between vertical velocity and local concentration indicate that the enhanced settling is rooted in the preferential sweeping mechanism. When the snow vertical velocity is large compared to the characteristic turbulence velocity, the crossing trajectories effect results in strong accelerations. When the conditions of preferential sweeping are met, the concentration field is highly non-uniform and clustering appears over a wide range of scales. These clusters, identified for the first time in a naturally occurring flow, display the signature features seen in canonical settings: power-law size distribution, fractal-like shape, vertical elongation, and large fall speed that increases with the cluster size. These findings demonstrate that the fundamental phenomenology of particle-laden turbulence can be leveraged towards a better predictive understanding of snow precipitation and ground snow accumulation. They also demonstrate how environmental flows can be used to investigate dispersed multiphase flows at Reynolds numbers not accessible in laboratory experiments or numerical simulations.