TY - JOUR
T1 - Multistimuli-Responsive Microstructured Superamphiphobic Surfaces with Large-Range, Reversible Switchable Wettability for Oil
AU - Wang, Hujun
AU - Zhang, Zhihui
AU - Wang, Zuankai
AU - Liang, Yunhong
AU - Cui, Zhenquan
AU - Zhao, Jie
AU - Li, Xiujuan
AU - Ren, Luquan
N1 - Funding Information:
This work was supported by the National Natural Science Foundation of China (no. U1601203), Young and Middle-aged Science and Technology Innovation Team Project of Jilin Province (no. 20180519007JH), and Graduate Innovation Fund of Jilin University (no. 101832018C009).
Publisher Copyright:
© 2019 American Chemical Society.
PY - 2019/8/7
Y1 - 2019/8/7
N2 - The switchable wettability is essential for widespread applications in droplet manipulation, rewritable liquid patterning, fluid carrying, and so forth. However, it remains difficult to achieve the multistimuli-responsive, large-range, and reversible wetting switching especially for liquids with low surface tensions through surface topographical management. Here, we apply a simple and effective template-free self-assembly strategy to fabricate microstructured superamphiphobic surfaces that can reversibly switch the wetting performance for oil by transforming the surface morphology in response to multiple stimuli of magnetic fields and mechanical strains. Notably, the noticeably different wetting switching of oil triggered by different stimuli is demonstrated. The contact angles of hexadecane droplets on the as-prepared surfaces can be reversibly switched between 150 ± 1° and 38 ± 2° in response to mechanical strains. Furthermore, the underlying mechanism of wetting switching has been further elucidated using mathematical models. Interestingly, these switchable surfaces dramatically demonstrate the ability to transport oil droplets, without requiring lubricating liquid films. This work not only achieves the large-range and reversible wetting switching for oil but also opens new avenues for fabricating tunable superamphiphobic surfaces with transformable mushroom-like microstructures that can be easily extended to microstructure-dependent friction or adhesion control and used in other fields.
AB - The switchable wettability is essential for widespread applications in droplet manipulation, rewritable liquid patterning, fluid carrying, and so forth. However, it remains difficult to achieve the multistimuli-responsive, large-range, and reversible wetting switching especially for liquids with low surface tensions through surface topographical management. Here, we apply a simple and effective template-free self-assembly strategy to fabricate microstructured superamphiphobic surfaces that can reversibly switch the wetting performance for oil by transforming the surface morphology in response to multiple stimuli of magnetic fields and mechanical strains. Notably, the noticeably different wetting switching of oil triggered by different stimuli is demonstrated. The contact angles of hexadecane droplets on the as-prepared surfaces can be reversibly switched between 150 ± 1° and 38 ± 2° in response to mechanical strains. Furthermore, the underlying mechanism of wetting switching has been further elucidated using mathematical models. Interestingly, these switchable surfaces dramatically demonstrate the ability to transport oil droplets, without requiring lubricating liquid films. This work not only achieves the large-range and reversible wetting switching for oil but also opens new avenues for fabricating tunable superamphiphobic surfaces with transformable mushroom-like microstructures that can be easily extended to microstructure-dependent friction or adhesion control and used in other fields.
KW - multistimuli-responsive surfaces
KW - simple fabrication
KW - superamphiphobicity
KW - transformable re-entrant microstructures
KW - wetting switching
UR - http://www.scopus.com/inward/record.url?scp=85070538259&partnerID=8YFLogxK
U2 - 10.1021/acsami.9b07941
DO - 10.1021/acsami.9b07941
M3 - Journal article
C2 - 31307191
AN - SCOPUS:85070538259
SN - 1944-8244
VL - 11
SP - 28478
EP - 28486
JO - ACS Applied Materials and Interfaces
JF - ACS Applied Materials and Interfaces
IS - 31
ER -