Acta Optica Sinica, Volume. 41, Issue 1, 0114003(2021)
Recent Advances in Femtosecond Laser-Induced Superhydrophobic Surfaces
Figures & Tables(14)
![Morphology and wettability of the silicon surface processed by femtosecond laser at different environments. (a)-(d) SF6 environment[36]; (e)-(h) atmospheric environment[30]](/Images/icon/loading.gif){kind=icon}
Fig. 6. Transparent superhydrophobic glass fabricated by femtosecond laser[58]. (a) Surface morphology; (b)(c) wettability of water droplets on the prepared surface; (d) transparency
Fig. 7. Self-cleaning phenomenon of femtosecond laser-structured superhydrophobic surface[46]
Fig. 8. Anti-icing property of femtosecond laser-structured superhydrophobic PTFE surface[59]. (a) Drop the same volume of water on samples; (b) water freezes; (c) result after shaking the samples
Fig. 9. Wettability of femtosecond laser-ablated microhole array aluminum foil surface and oil/water separation process[60]. (a) Surface wettability; (b) oil/water separation process
Fig. 10. Surface morphology of the silicon surface ablated by laser with different pulse energies and evaporation process of the droplet on the samples surfaces[61].(a)-(j) Surface morphology; (k) evaporation process
Fig. 11. Transportation process of a water droplet from low-adhesive superhydrophobic surface to high-adhesive superhydrophobic surface[40]
Fig. 12. Micro/nano-structures morphology on the surface of copper sheet and microfluidic devices[62]. (a)(c) Morphology and wettability of micro/nano-structures formed on copper sheet surface by laser with different energy densities; (b)(d) surface morphology and wettability of PDMS after template replicating; (e)-(g) microfluidic devices
Table 1. Crucial parameters for preparing superhydrophobic micro/nano-structures on different materials surfaces by femtosecond laser technology
View tableTable 1. Crucial parameters for preparing superhydrophobic micro/nano-structures on different materials surfaces by femtosecond laser technology
Sample Parameter of laser system Processing parameter Ref. Material Morphology Pulse width /fs Central wavelength /nm Repetition rate /kHz Silicon Well-defined conical-shaped spikes 100 800 1 Laser energy density: 5-9 kJ·m-2 [35] Platinum Parallel microgroove array covered by nanostructures 65 800 1 Laser energy density: 9.8 J·cm-2 [38] Stainless steel Micro- and submicron double-scale structure 130 800 1 Laser energy density: 0.8 J·cm-2, scanning speed: 1 mm·s-1 [39] Zinc Micro-mountain-like papillae 50 800 1 Laser power: 15 mW, scanning speed: 2 mm·s-1 [41] PDMS Microwell array structures 50 800 1 Laser power: 30 mW, scanning speed: 13 mm·s-1 [42] PTFE Microstructures with pores and protrusions 50 800 1 Laser power: 20 mW, scanning speed: 5 mm·s-1 [47] Shape memory polymer Micropillar array 50 800 1 Laser power: 30 mW, scanning speed: 4 mm·s-1 [54] Glass Periodic microgratings 183 786 1 Laser energy: 21 μJ, scanning speed: 5 mm·s-1 [57]
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Xue Bai, Feng Chen. Recent Advances in Femtosecond Laser-Induced Superhydrophobic Surfaces[J]. Acta Optica Sinica, 2021, 41(1): 0114003
Paper Information
Category: Lasers and Laser Optics
Received: Aug. 12, 2020
Accepted: Sep. 18, 2020
Published Online: Feb. 23, 2021
The Author Email: Chen Feng (chengfeng@mail.xjtu.edu.cn)
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