Self-similar Features in Sub-secondary Breakup of a Droplet and Ligament Mediated Fragmentation under Extreme Conditions (2502.05976v2)

Abstract: Droplet formation is relevant in many applications spanning natural and artificial settings. Comprehending droplet aerobreakup or air-assisted secondary atomization is challenging, especially in high-speed flow scenarios. This entails multi-scale interface deformations with intricate wave dynamics that conform to a non-linear cascade. In the present study, we look into shockwave-induced breakups and associated intermediate processes happening at smaller spatiotemporal scales across the disintegrating droplet interface at different Weber numbers ($We \sim 10^3$). We observe the undulations to follow breakup patterns that resemble a scaled-down version of a secondary atomization event. These sub-secondary breakup processes end with corrugated ligaments that generate the final daughter droplets. The size distribution of these droplets is estimated using a Depth from Defocus (DFD) technique. These illustrate the transient nature of aerobreakup, where the normalized statistics in subsequent time periods and different $We$ are observed to follow a universal distribution. This conforms to a gamma distribution where the associated fit parameters agree well with the coefficients determined from ligament shape factors, corresponding to the limit associated with most extreme corrugations. Scaling laws based on $We$ are deduced for the averaged statistics using a high energy chaotic breakup mechanism. These observations reinforce the idea of a self-similar mechanism for catastrophic aerobreakup of a droplet.