TY - JOUR
T1 - A Sequential Process for Manufacturing Nature-Inspired Anisotropic Superhydrophobic Structures on AISI 316L Stainless Steel
AU - Cai, Yukui
AU - Xu, Zongwei
AU - Wang, Hong
AU - Lau, King Hang Aaron
AU - Ding, Fei
AU - Sun, Jining
AU - Qin, Yi
AU - Luo, Xichun
N1 - Funding Information:
This research was undertaken in the context of MICROMAN project (?Process Fingerprint for Zero-defect Net-shape MICROMANufacturing?, http://www.microman.mek.dtu.dk/). MICROMAN is a European Training Network supported by Horizon 2020, the EU Framework Programme for Research and Innovation (Project ID: 674801). The authors would also gratefully acknowledge the financial support from the EPSRC (EP/K018345/1) and Royal Society-NSFC International exchange scheme (IE141422 and IEC\NSFC\181474) for this research.
Funding Information:
This research was undertaken in the context of MICROMAN project (“Process Fingerprint for Zero-defect Net-shape MICROMANufacturing”, http://www.microman.mek.dtu.dk/ ). MICROMAN is a European Training Network supported by Horizon 2020, the EU Framework Programme for Research and Innovation (Project ID: 674801). The authors would also gratefully acknowledge the financial support from the EPSRC (EP/K018345/1) and Royal Society-NSFC International exchange scheme (IE141422 and IEC\NSFC\181474) for this research.
Publisher Copyright:
© 2019, The Author(s).
PY - 2019/9
Y1 - 2019/9
N2 - Surfaces with anisotropic superhydrophobicity have great potential applications in drug delivery and microfluidic devices due to their unique properties of drag reduction and unidirectional fluid transportation. Observations of natural biological surfaces have proven that directional microstructures are indispensable for realizing anisotropic superhydrophobicity. However, current lithography-based manufacturing approaches have limited capabilities to scale-up for real-world industrial applications. This paper proposes a sequential process of laser ablation and chemical etching, for the first time, to manufacture ratchet-like microstructures on AISI 316L stainless steel by harvesting the advantages of both methods. The laser ablation will form a specified recast layer that will be covered by an oxide layer on the specimen, and these two layers can be easily removed in the chemical etching process to obtain the periodic ratchet-like microstructures. According to the experimental results, the direction of the microstructures is determined by the laser beam feed direction. Both the width and depth of microstructures increase with increasing laser power, which results in the disappearance of ridges. However, the increasing pitch will lead to the ridges appearing again. The specimen with a pitch of 25 μm machined at a laser power of 20 W has a maximum contact angle of 158.2°. Moreover, with a dip angle of 7°, this specimen shows a strong anisotropic superhydrophobicity, the droplet easily rolls off the surface in the laser beam feed direction; however, it is pinned tightly in the opposite direction.
AB - Surfaces with anisotropic superhydrophobicity have great potential applications in drug delivery and microfluidic devices due to their unique properties of drag reduction and unidirectional fluid transportation. Observations of natural biological surfaces have proven that directional microstructures are indispensable for realizing anisotropic superhydrophobicity. However, current lithography-based manufacturing approaches have limited capabilities to scale-up for real-world industrial applications. This paper proposes a sequential process of laser ablation and chemical etching, for the first time, to manufacture ratchet-like microstructures on AISI 316L stainless steel by harvesting the advantages of both methods. The laser ablation will form a specified recast layer that will be covered by an oxide layer on the specimen, and these two layers can be easily removed in the chemical etching process to obtain the periodic ratchet-like microstructures. According to the experimental results, the direction of the microstructures is determined by the laser beam feed direction. Both the width and depth of microstructures increase with increasing laser power, which results in the disappearance of ridges. However, the increasing pitch will lead to the ridges appearing again. The specimen with a pitch of 25 μm machined at a laser power of 20 W has a maximum contact angle of 158.2°. Moreover, with a dip angle of 7°, this specimen shows a strong anisotropic superhydrophobicity, the droplet easily rolls off the surface in the laser beam feed direction; however, it is pinned tightly in the opposite direction.
KW - Chemical etching
KW - Laser ablation
KW - Superhydrophobic surface
UR - http://www.scopus.com/inward/record.url?scp=85091767070&partnerID=8YFLogxK
U2 - 10.1007/s41871-019-00046-2
DO - 10.1007/s41871-019-00046-2
M3 - Article
AN - SCOPUS:85091767070
SN - 2520-811X
VL - 2
SP - 148
EP - 159
JO - Nanomanufacturing and Metrology
JF - Nanomanufacturing and Metrology
IS - 3
ER -