Aboud et al., 2021 - Google Patents
Influence of microstructure topography on the oblique impact dynamics of drops on superhydrophobic surfacesAboud et al., 2021
View PDF- Document ID
- 7076032675973870300
- Author
- Aboud D
- Kietzig A
- Publication year
- Publication venue
- Langmuir
External Links
Snippet
This report investigates the influence of microstructure topography on the restitution coefficient, maximum spreading diameter, and contact time of oblique drop impacts on superhydrophobic surfaces. The five surfaces tested allow for comparison of open-versus …
- 230000003075 superhydrophobic 0 title abstract description 174
Similar Documents
| Publication | Publication Date | Title |
|---|---|---|
| Aboud et al. | Influence of microstructure topography on the oblique impact dynamics of drops on superhydrophobic surfaces | |
| Guo et al. | Droplet impact on anisotropic superhydrophobic surfaces | |
| Song et al. | Robust superhydrophobic conical pillars from syringe needle shape to straight conical pillar shape for droplet pancake bouncing | |
| Aboud et al. | Splashing threshold of oblique droplet impacts on surfaces of various wettability | |
| Sarshar et al. | Anti-icing or deicing: Icephobicities of superhydrophobic surfaces with hierarchical structures | |
| Song et al. | Large-area fabrication of droplet pancake bouncing surface and control of bouncing state | |
| Wang et al. | Droplet asymmetric bouncing on inclined superhydrophobic surfaces | |
| Wen et al. | Wetting transition of condensed droplets on nanostructured superhydrophobic surfaces: coordination of surface properties and condensing conditions | |
| Aria et al. | Physicochemical characteristics and droplet impact dynamics of superhydrophobic carbon nanotube arrays | |
| Chu et al. | Directional transportation of impacting droplets on wettability-controlled surfaces | |
| Extrand et al. | Repellency of the lotus leaf: contact angles, drop retention, and sliding angles | |
| Aboud et al. | On the oblique impact dynamics of drops on superhydrophobic surfaces. Part II: Restitution coefficient and contact time | |
| Xie et al. | Contact time of a bouncing nanodroplet | |
| Wang et al. | Underwater drag reduction and buoyancy enhancement on biomimetic antiabrasive superhydrophobic coatings | |
| Jung et al. | Dynamic effects induced transition of droplets on biomimetic superhydrophobic surfaces | |
| Kim et al. | Drop impact characteristics and structure effects of hydrophobic surfaces with micro-and/or nanoscaled structures | |
| Marengo et al. | Drop collisions with simple and complex surfaces | |
| Hu et al. | Contact time of droplet impact on inclined ridged superhydrophobic surfaces | |
| Malla et al. | Droplet bouncing and breakup during impact on a microgrooved surface | |
| Li et al. | Dynamic behavior of the water droplet impact on a textured hydrophobic/superhydrophobic surface: The effect of the remaining liquid film arising on the pillars' tops on the contact time | |
| Shen et al. | Bioinspired fabrication of hierarchical-structured superhydrophobic surfaces to understand droplet bouncing dynamics for enhancing water repellency | |
| Gao et al. | Nanodroplets impact on rough surfaces: A simulation and theoretical study | |
| Shi et al. | Drop impact on two-tier monostable superrepellent surfaces | |
| Li et al. | Insights into the impact of surface hydrophobicity on droplet coalescence and jumping dynamics | |
| Sahoo et al. | Thermally triggered transition of superhydrophobic characteristics of micro-and nanotextured multiscale rough surfaces |