Contact time of nanodroplets obliquely impacting nanopillar-arrayed superhydrophobic surfaces: A molecular dynamics study

On nanopillar-arrayed superhydrophobic surfaces, the contact time of oblique nanodroplet impacts is for the first time investigated via molecular dynamics simulations. Here, oblique nanodroplet impacts are triggered by nanodroplets impacting superhydrophobic surfaces under various impact angles, a. The simulation results show that owing to the non-axisymmetry of spreading factors on nanopillar-arrayed superhydrophobic surfaces, the contact time of oblique nanodroplet impacts is always less on nanopillar-arrayed rather than smooth super hydrophobic surfaces under same impact angles. As the impact angle is increased from 5 degrees to 65 degrees, that is, under different impact conditions, the non-axisymmetry is more remarkable as a > 35 degrees instead of a < 35<degrees> at the low, medium, and high normal Weber numbers, Wen. Hence, the contact time is sharp as a > 35 degrees and then slowly reduced as a < 35<degrees> at the low, medium, and high Wen, at which the drastically increased sliding length as a > 35 degrees further promotes the rapid reduction in contact time. As the impact angle is constant at 35 degrees, the non-axisymmetry is more remarkable as h/w < 1 instead of h/w > 1 as the aspect ratio of nanopillars, h/w, is increased, that is, under different surface conditions. Hence, the contact time is sharp as h/w < 1 and then slowly reduced as h/w > 1 at the low, medium, and high Wen, at which the drastically reduced sliding length as h/w > 1 further hinders the rapid reduction in contact time.