On the Oblique Impact Dynamics of Drops on Superhydrophobic Surfaces. Part II: Restitution Coefficient and Contact Time

We tested oblique drop impacts on a superhydrophobic surface at normal Weber numbers (We n) in the range of 3–45, and at varying angles of incidence (AOIs), ranging from 0° (normal impact) to 60° (highly oblique). Our objective is to define the influence of the AOI on the restitution coefficient and...

Full description

Saved in:
Bibliographic Details
Published in:Langmuir 2018-08, Vol.34 (34), p.9889-9896
Main Authors: Aboud, Damon G. K, Kietzig, Anne-Marie
Format: Article
Language:English
Citations: Items that this one cites
Items that cite this one
Online Access:Get full text
Tags: Add Tag
No Tags, Be the first to tag this record!
Description
Summary:We tested oblique drop impacts on a superhydrophobic surface at normal Weber numbers (We n) in the range of 3–45, and at varying angles of incidence (AOIs), ranging from 0° (normal impact) to 60° (highly oblique). Our objective is to define the influence of the AOI on the restitution coefficient and on the contact time of rebounding droplets. To interpret the overall restitution coefficient of oblique drop rebounds (ε), we decoupled it into two separate components: a normal (εn) and a tangential restitution coefficient (εt). We discovered that, regardless of the impact angle, εn can be accurately predicted as a function of the normal Weber number (εn = 0.94We n –1/4). We support this finding with a mathematical derivation from theory, indicating a general scaling relationship of εn ∼ We n –1/4 for the normal restitution coefficient. Likewise, the tangential restitution coefficient (εt) can also be predicted as a function of We n (εt = 1.20We n –0.12) but is much larger than εn. As a result, the overall restitution coefficient (ε) increases for more oblique impacts because most of the tangential velocity is preserved. Furthermore, using the observed correlations for εn and εt, we derived a model to predict the overall restitution coefficient of rebounding drops at any We n and AOI. The model’s predictions are highly accurate, lying close to our experimental observations in all cases. Regarding the contact time (t c), we found that for normal impacts, t c increased slightly as We n was raised. We associate this behavior with partial penetration of the liquid into the surface’s pores, which results in greater solid–liquid adhesion, prolonging detachment. For highly oblique impacts (AOI = 60°), we observed the reverse trend: the drop’s contact time decreases for higher-We n impacts. We attribute this correlation to stretched rebounding behavior, which accelerates the rebounding of highly oblique impacts.
ISSN:0743-7463
1520-5827
DOI:10.1021/acs.langmuir.8b01233