Controllable Construction and Corrosion Resistance Mechanism of Durable Superhydrophobic Micro-Nano Structure on Aluminum Alloy Surface

Aluminum alloy corrosion resistance could be improved by micro-nanostructures on superhydrophobic surfaces, but inadequate mechanical stability remains a bottleneck concern in the sector. Herein, femtosecond laser processing and spray modification techniques are employed to fabricate armor-style micro-nanostructures on aluminum alloy surfaces. The construction of durable superhydrophobic surfaces was controllably constructed using this strategy. Applying a spray of hydrophobic nano silica onto the surface of aluminum alloys is an effective method for creating a low surface energy coating, while the femtosecond laser-processed armor-style micro-nano structure offers additional adhesion sites for the hydrophobic nano-silica. The findings indicated that the treated surface's contact angle (CA) reached 152.5 & DEG; while the slide angle (SA) was only 2.3 & DEG;, exhibiting favorable superhydrophobic performance. Being worn 100 times with 400# sandpaper, the superhydrophobic surface retained a contact angle above 150 & DEG;. Electrochemical tests demonstrated significant reductions in the self-corrosion current of superhydrophobic surfaces. Meanwhile, the impedance increased significantly, showing good thermal, mechanical, and chemical stability, enabling better sustainable use of aluminum alloys. These results will serve as a theoretical foundation for the surface protection of aluminum alloys.

Automated summary

Armor-style micro-nanostructures were fabricated on aluminum alloy surfaces using femtosecond laser processing and spray modification techniques, leading to durable and controllable superhydrophobic surfaces. The combination of a hydrophobic nano-silica coating and the laser-processed micro-nano structure resulted in a high contact angle and low slide angle, demonstrating excellent superhydrophobic performance. The treated surface also exhibited improved corrosion resistance and better thermal, mechanical, and chemical stability, presenting a promising solution for surface protection of aluminum alloys.