Developing a non-optical platform for impact dynamics analysis on nanostructured superhydrophobic surfaces using a quartz crystal microbalance

•Non-optical technique was employed as a complementary analysis for impact dynamics.•QCM can investigate in-situ changes of a surface state as the resonance frequency.•Nanostructured surface with various surface energies were prepared for this study.•QCM provided detailed microscopic information in...

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Bibliographic Details
Published in:Sensors and actuators. B, Chemical Chemical, 2018-06, Vol.262, p.595-602
Main Authors: Baek, Seunghyeon, Kim, Wuseok, Jeon, Sangmin, Yong, Kijung
Format: Article
Language:English
Subjects:
Control surfaces
Deformation
Droplets
Drying
Dynamics
Fluid dynamics
High speed cameras
Hydrophobic surfaces
Hydrophobicity
Impact analysis
Impact dynamics
Microbalances
Molecular chains
Nanowires
Organic chemistry
Quantitative analysis
Quartz
Quartz crystal microbalance
Superhydrophobic
Surface energy
Water
Water drops
Water-repellency
Weber number
Wettability
Zinc oxide
Zinc oxides
Zinc-oxide nanowires
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Summary:•Non-optical technique was employed as a complementary analysis for impact dynamics.•QCM can investigate in-situ changes of a surface state as the resonance frequency.•Nanostructured surface with various surface energies were prepared for this study.•QCM provided detailed microscopic information in a quantitative way.•QCM compared water-repellency stability of the superhydrophobic surfaces. Quantitative analysis of water droplet behavior under dynamic conditions is one of the critical challenges for applications of wettability-controlled surfaces. Currently, various optical analysis techniques have been employed to analyze impact dynamics. Despite the convenience of direct observation of water droplets, most of these techniques have limited applicability to microscopic and quantitative investigations. In an effort to overcome these limitations, here, we suggest a complementary analysis platform using a quartz crystal microbalance (QCM) to study impact dynamics. A high-speed camera and QCM were applied together to study the behavior of water droplets that impact wettability-controlled surfaces with various We numbers (Weber number). For these experiments, ZnO nanowire surfaces were prepared and chemically modified by alkyl-thiol molecules with various carbon chain lengths (C0–C12) to control the surface energy. For nanowire surfaces with high surface energies (C0–C6) and for the lowest surface energy sample (C18), both methods exhibited highly consistent impact dynamics, showing stable wetting and dewetting properties, respectively. In addition to these apparent behaviors, QCM was further able to provide detailed microscopic information regarding the penetration and deformation of water droplets in a quantitative way based on acoustic sensing. More interestingly, QCM was able to determine the metastable water repellency of a C12-modified surface with a high We number, which could not be detected by the high-speed camera. These results suggest the significant potential of QCM as a new platform to analyze the impact dynamics of water droplets via quantitative, microscopic investigations.
ISSN:0925-4005
1873-3077
DOI:10.1016/j.snb.2018.02.031