Spontaneous charging affects the motion of sliding drops

Water drops moving on surfaces are not only an everyday phenomenon seen on windows but also form an essential part of many industrial processes. Previous understanding is that drop motion is dictated by viscous dissipation and activated dynamics at the contact line. Here we demonstrate that these two effects cannot fully explain the complex paths of sliding or impacting drops. To accurately determine the forces experienced by moving drops, we imaged their trajectory when sliding down a tilted surface, and applied the relevant equations of motion. We found that drop motion on low-permittivity substrates is substantially influenced by electrostatic forces. Our findings confirm that electrostatics must be taken into consideration for the description of the motion of water, aqueous electrolytes and ethylene glycol on hydrophobic surfaces. Our results are relevant for improving the control of drop motion in many applications, including printing, microfluidics, water management and tribo-electric nanogenerators.

Automated summary

Research reveals that water drops moving on surfaces are influenced by viscous dissipation, activated dynamics, and electrostatic forces. Electrostatic forces play a significant role in the motion of water, aqueous electrolytes, and ethylene glycol on hydrophobic surfaces. These findings are important for improving the control of drop motion in various applications.