A molecular dynamics study on coalescence-induced jumping of moving and static droplets

In this paper, molecular dynamics simulations are employed to investigate the coalescence-induced jumping behavior of moving and stationary droplets at the nanoscale on superhydrophobic surfaces. The results show that the initial velocity of the droplets significantly influences the coalescence time and jumping characteristics. As the initial velocity increases, the coalescence time decreases, and the horizontal velocity increases, suggesting that controlling the initial velocity can adjust droplet motion behavior. In terms of energy conversion, the total energy conversion rate remains relatively constant at lower initial velocities but increases significantly as the velocity rises. This is primarily due to the reduced coalescence time and viscous dissipation caused by the increased initial kinetic energy, allowing more energy to be converted into the kinetic energy of jumping. The energy conversion rate in the horizontal direction increases with initial velocity, while in the vertical direction, it tends to decrease. This study deepens the understanding of coalescence-induced jumping phenomena at the nanoscale and provides a theoretical basis for engineering applications, showing that droplet behavior can be effectively modulated by controlling the initial velocity.