Journal
APPLIED SURFACE SCIENCE
Volume 605, Issue -, Pages -Publisher
ELSEVIER
DOI: 10.1016/j.apsusc.2022.154661
Keywords
Wettability; Superhydrophobic; Laser-induced plasma micro-machining; Impact behavior; Ti6Al4V
Categories
Funding
- National Natural Science Founda- tion of China (NSFC) [51705171, 51975228]
- Nat- ural Science Foundation of Guangdong Province [2020A1515010638]
- Local Innovative and Research Team Project of Guangdong Pearl River Talents Program [2017BT01G167]
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In this study, a laser-induced plasma micromachining technique was used to fabricate a super-hydrophobic surface with a micro-nano hierarchical structure on a titanium alloy. Experimental and simulation results showed that as the contact angle increases, the spreading diameter decreases and the rebound height increases.
Titanium alloy Ti6Al4V super-hydrophobic surface plays a key role in enhancing the water repellency and anti-condensation of the fuselage. In this study, laser-induced plasma micromachining (LIPMM) is used for processing an array of cone-shaped protrusions on the surface with a micro-nano hierarchical structure. The relationship between surface wettability, micro-nano structure, and surface chemical composition was studied, meanwhile, the droplet impact behavior was experimented and simulated. The study found that with the aging treatment surface C element distribution and content increased significantly, and the wettability changed from super-hydrophilic to hydrophobic. As the scan line spacing (50, 40, 30 mu m) decreases, the contact angle increased and the hysteresis contact angle decreased. At 50 times and 30 mu m line spacing, the contact angle 151.209 degrees > 150 degrees, and the hysteresis contact angle 2.619 degrees < 10 degrees. The collision experiments reveal that with the increase of the collision velocity (0.44 m/s to 0.98 m/s), the spreading diameter and the rebound height increases. The comparative results of experiments and simulations of collisions present that as the contact angle increases, the spreading diameter decreases, and the rebound height increases. Therefore, the LIPMM is feasible for the fabrication of a superhydrophobic surface and has a wide range of application prospects such as waterproofing, anti-fouling, and anti-icing.
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