Direct numerical simulation of coalescing droplets in turbulence

There is a rich body of numerical, experimental and theoretical work looking at the role of turbulence in particle collisions, with a particular emphasis on how it might accelerate the evolution of clouds in the atmosphere. This study is a continuation of that lineage. We perform direct numerical simulations of isotropic turbulence with embedded droplets that, upon collision, coalesce to produce a daughter droplet that conserves the mass and momentum of the parent droplets. ~As a consequence of coalescence, the droplet size distribution evolves over time from its monodisperse initial condition. ~The work is an extension of Reade and Collins (J. Fluid Mech. 415:45-64, 2000), which considered the same problem at a much lower Reynolds number. ~We observe important effects of intermittency at Reynolds numbers that are several-fold higher. ~The collisions do not yet take into account the effect of the lubricating gas layer, which will be the topic of future work.