Gravity-induced collisions of uncharged cloud droplets in an electric field

Abstract: We investigate the collisions of uncharged, conducting droplets settling under gravity in the presence of an external electric field. Previous studies have derived a near-field asymptotic expression for the electric-field-induced attraction, suggesting that this force can overcome lubrication resistance and drive surface-to-surface contact between two spherical conductors within a finite time. However, for droplets moving in air, traditional lubrication theory breaks down when the inter-droplet gap approaches the mean free path of air molecules. To account for this, we incorporate non-continuum hydrodynamic effects to estimate the gravity-driven collision efficiency under electric-field-induced forces. This study examines how an external electric field influences the trajectories of settling droplet pairs of unequal sizes. By analyzing their motion, we compute collision efficiencies and explore their dependence on droplet size ratio, electric field strength, the angle between the field and gravity, and key dimensionless parameters governing electric-field-induced and van der Waals forces. Our findings reveal that electric-field-induced forces significantly enhance collision efficiency, highlighting their critical role in droplet coalescence dynamics.