Femtosecond laser patterned superhydrophobic surface with anisotropic sliding for droplet manipulation.

• A simple and robust method for fabricating patterned superhydrophobic surfaces by femtosecond laser micromachining is presented. • The wettability and the adhesion force of the patterned surface are tuned by changing the width of the linear pattern. • Based on the modified Furmidge equation, the relationship between the adhesion and the liquid-solid interface width is explained. • The patterned surface has the ability to manage fluid motion, transportation and mixing. Patterned superhydrophobic surfaces have a wide range of applications in terms of microfluidic devices. In this work, a simple and robust method is proposed to fabricate patterned superhydrophobic surfaces by two combined steps including femtosecond laser microfabrication and immersion treatment. The obtained surface exhibits contact angles of 170.0°, 167.6°, and 169.5°, and sliding angles of 5.8°, 6.0°, and 3.9° for 12 μL, 18 μL, and 30 μL water droplets, respectively. The high-adhesion hydrophobic linear pattern combined with the surrounding low-adhesion superhydrophobic surface exhibits controllable wettability and pronounced liquid-sliding anisotropy. Since the contact angle and the adhesion force can be controlled by adjusting the width of the linear pattern, the droplet motion can be directionally modulated. As the line width increases, the sliding angle in parallel direction can be regulated from 18.9° to 90°, from 15.3° to 47.6°, and from 8.6° to 25.0° for 12 μL, 18 μL, and 30 μL water droplets, respectively. Based on the modified Furmidge equation, the relationship between adhesion and liquid-solid interface width can be reasonably explained. Furthermore, the potential applications of the patterned surfaces for droplet transport and mixing are explored. The wettability of the superhydrophobic surfaces to liquids of different types and pH is also investigated. The work presented here has the potential to advance femtosecond laser scanning as a simple, precise, and controllable method for fabricating patterned superhydrophobic surfaces, and to accelerate their applications in parallel reactors, chemical micro-assays, drug delivery systems and so on. [ABSTRACT FROM AUTHOR]